Fatigue enhancement of material surrounding openings in workpieces

An elongated first tubular member has a mandrel receiving center passageway and a slotted outer end portion that comprises first axial fingers separated by first axial slots. An elongated second tubular member surrounds the first tubular member and has a slotted outer end portion that comprises second axial fingers separated by second axial slots. An elongated third tubular member surrounds the second tubular member and has a slotted outer end portion comprising third axial fingers separated by third axial slots. An elongated mandrel is positioned inside the center passageway. The first tubular member is extendable and retractable longitudinally of the second and third tubular members. A tubular sleeve is provided that has an inner end and a flange projecting radially outwardly from the sleeve at the inner end. The mandrel is extendable axially through the center passageway of the first tubular member and axially through the tubular sleeve when the radial flange is clamped by and between the first and second fingers.

TECHNICAL FIELD

This invention relates to split sleeve cold expansion of material surrounding openings in the material, for fatigue life enhancement of the material. More particularly, it relates to the provision of a tool adapted for easy insertion of a split sleeve into an opening in a workpiece by extension of the tool, and the pulling of a mandrel through the split sleeve to expand the split sleeve and the material surrounding the split sleeve, and the removal of the split sleeve from the opening following expansion by a retraction of the tool away from the workpiece.

BACKGROUND OF THE INVENTION

Split sleeve cold expansion of fastener holes and other openings in structural members is a process in which a tapered mandrel is used in conjuction with a disposable, internally lubricated split sleeve, to compressively pre-stress a significant zone in the material, surrounding the opening. The compressive pre-stressing offsets the stress concentrations of the hole itself to produce substantial improvement in structural fatigue performance of the material in which the opening is formed. Systems for installing and removing the sleeve from the workpiece, by use of the same tooling that pulls a mandrel through the sleeve for expanding the sleeve and the opening in the workpiece are, for example, disclosed by U.S. Pat. No. 5,127,257, granted Jul. 7, 1992, and by U.S. Pat. No. 5,305,627, granted Apr. 26, 1994. The present invention constitutes an improvement on the systems disclosed by these patents.

The above patents and the additional patents listed in them should be considered for the purpose of putting the present invention into proper perspective relative to the prior art.

BRIEF SUMMARY

The present invention includes improved tooling, and in particular an improved puller tool, and to an unique split sleeve that is adapted to be used with the tooling.

The tooling may include an inner tubular member that is divided by axial slots into axial fingers having substantially radial end surfaces. It may further include an outer tubular member that surrounds the inner tubular member. The outer tubular member may be divided by axial slots into axial fingers that have radial jaws that are axially spaced from the end surfaces on the fingers of the inner tubular member. The radial jaws have substantially radial surfaces that axially confront the end surfaces on the axial fingers of the first tubular member. The jaws further have cylindrical surface segments that extend axially from the substantially radial surfaces. A split sleeve is provided for use with this tooling. The split sleeve comprises a substantially cylindrical body portion having an axial edge at a first end and a substantially radial flange at an opposite second end. The radial flange projects radially outwardly from the cylindrical body portion. The sleeve includes an axial split that extends through both the substantially radial flange and the cylindrical body portion of the sleeve. The radial flange has a substantially radial first surface that is contactable with the substantially radial end surfaces on the axial fingers of the first tubular member. It also has a substantially radial second surface that is contactable with the substantially radial surfaces on the jaws that are on the outer tubular member. The substantially cylindrical body portion of the sleeve has a substantially cylindrical neck portion that extends axially from the flange into a position contiguous the substantially cylindrical segments on the substantially radial jaws of the outer tubular member. This happens when the substantially radial flange on the sleeve is positioned axially between the end surfaces on the axial fingers of the inner tubular member and the confronting, substantially radial surfaces on the jaws of the outer tubular member. In use, the end surfaces on the axial fingers of the first tubular member and the jaws on the axial fingers of the second tubular member are moved relatively together so that they clamp between them the substantially radial flange that is at the second end of the sleeve.

The present invention includes providing a puller tool for pulling a mandrel through a split sleeve that is in an opening in a workpiece. This puller tool is basically characterized by an elongated first tubular member having a mandrel receiving center passageway and a slotted outer end portion comprising first axial fingers separated by first axial slots. An elongated second tubular member surrounds the first tubular member and includes a slotted outer end portion comprising second axial fingers separated by second axial slots. An elongated third tubular member surrounds the second tubular member and includes a slotted outer end portion comprising third axial fingers separated by third axial slots. The puller tool includes an elongated mandrel that is positioned for moving axially in the center passageway of the first tubular member. The mandrel has a small diameter inner end portion, a large diameter outer end portion, and an increasing diameter portion extending from the small diameter inner end portion to the large diameter outer end portion. The third fingers have outer end portions forming an end opening and radially inwardly projecting clamp jaws having substantially radial first clamp surfaces. The first axial fingers include outer end portions having substantially radial second clamp surfaces which confront the first clamp surfaces. The first tubular member is extendable and retractable longitudinally of the second and third tubular members. The first and second tubular members have first and second cam surfaces. The first cam surfaces are radially outwardly directed on the first axial fingers. The second cam surfaces are radially inwardly directed on the second axial fingers. The first and second cam surfaces are adapted to contact each other and expand the second axial fingers radially in response to the first tubular member being retracted into the second tubular member. The expansion of the second axial fingers is adapted to cause an expansion of the third axial fingers and an enlargement of the end-opening formed by the jaws at the ends of axial fingers of the third tubular member. The tooling further includes a tubular sleeve having an inner end and a flange projecting radially outwardly from the sleeve at the first end. The flange is sized to move axially through the end opening in the outer end of the third tubular member when the third axial fingers are expanded. The flange is also sized to be received between and be clamped by the first and second clamp surfaces when the first tubular member is extended axially and the second and third axial fingers are contracted radially. The tubular sleeve has a tubular portion that projects outwardly from the flange and an end opening when the flange is clamped by and between the first and second clamp surfaces. The mandrel is extendable axially through the center passageway of the first tubular member and axially through the tubular sleeve when the radial flange is clamped by and between the first and second clamp surfaces. The mandrel is retractable through the sleeve and into the center passageway when the radial flange is clamped by and between the first and second clamp surfaces.

Preferably, the puller tool also comprises a housing having a first end including an end opening. The first tubular member has an inner end portion which extends through the end opening into the housing. The second and third tubular members have inner ends that are connected to the first end of the housing.

Preferably also, the puller tool includes a push-pull member within the housing to which the inner end of the first tubular member is connected. This push-pull member is preferably tubular and the elongated mandrel has an inner end portion that extends from the first tubular member into the push-pull member. There is a second push-pull member in said housing to which the mandrel is connected.

In preferred form, the mandrel includes an endwise outwardly tapering portion extending endwise outwardly beyond the large diameter outer end portion of the mandrel. The clamp jaws of the third fingers include axial surfaces extending axially from the substantially radial first clamp surfaces. The outer end portions of the first axial fingers include axial surfaces that extend axially from the radial second clamp surfaces. When the flange on the sleeve is clamped by and between the first and second clamp surfaces, the axial surfaces on the first axial fingers are contiguous the axial surfaces on the clamp jaws.

In preferred form, the tubular sleeve has a single axial split and is adapted to expand in diameter in response to the large diameter portion of the mandrel being moved axially through it.

The puller tool is connected to a suitable support that is controllable to move the puller tool towards a sleeve, for receiving the sleeve, and then moving the sleeve and puller tool to an opening in a workpiece. The tool is moveable to insert the sleeve into the opening in the workpiece. The mandrel is retractable to move it through the sleeve that is in the opening in the workpiece. After the mandrel has passed through the sleeve, the tool and sleeve are moveable together away from the workpiece. The puller tool is adapted to then release the sleeve. The mechanism for removing the puller tool may be a robotic mechanism. It may be adapted to suitably position the puller tool relative to an opening that extends vertically, horizontally or diagonally.

These and other advantages, objects, and features will become apparent from the following best mode description, the accompanying drawings, and the claims, which are all incorporated herein as part of the disclosure of the invention.

BEST MODE FOR CARRYING OUT THE INVENTION

Referring toFIGS. 1–3, a puller tool10is shown in a vertical position. However, it is to be understood that, the in-use orientation of the puller tool10is dictated by the orientation of the workpiece. For example, if the workpiece extends horizontally, the puller tool10will be positioned vertically, with its mandrel end directed either downwardly or upwardly. If the workpiece is disposed vertically, the puller tool will be disposed horizontally. If the workpiece extends somewhere between horizontal and vertical, the puller tool10will extend diagonally with its longitudinal axis extending substantially perpendicular to the workpiece. The puller tool10may be suitably supported and guided by a robotic mechanism that is operable to provide the necessary and desired movement and orientation of the puller tool10. See, for example, FIG. 1 of the aforementioned U.S. Pat. No. 5,305,627.

The puller tool10preferably includes an outer housing12having a first end14and a second end16. An elongated inner housing18is positioned within outer housing12. The lower end of inner housing18is connected to a first tubular member20. The inner housing18and the first tubular member20are moveable axially together relative to the outer housing12. A piston is positioned within the inner housing18. It includes a first piston head22and a second piston head24. Piston head22is moveable axially in a cylinder section26. Piston head24is moved axially in a cylinder section28. The lower end (as illustrated) of the piston is connected to an elongated mandrel M.

InFIG. 8, the mandrel M is shown related to the elongated first tubular member20, an elongated second tubular member30and an elongated third tubular member32. Tubular member20surrounds the mandrel M. Tubular member30surrounds the tubular member20. Tubular member32surrounds the tubular member30. Tubular members30,32have end portions34,36that are connected to the end16of the housing12. As a result, tubular members30,32are fixed in position axially relative to the housing12. As already described, the tubular member20is connected to the inner housing18which is moveable back and forth axially. Accordingly, first tubular member20is moveable axially relative to both the second tubular member30and the third tubular member32. The mandrel M is moveable axially relative to all three tubular members20,30,32.

As best shown byFIG. 10, the inner housing18carries a piston head38that is positioned within a tubular cavity40. A first working chamber42is provided above the piston head38and a second working chamber44is provided below the piston head38. The introduction of a pressure fluid into chamber44while chamber42is vented will cause piston head38and the inner housing18to which it is connected to move upwardly relative to the outer housing12. The venting of chamber42while pressure fluid is introduced into chamber44will cause an upward movement of the piston head38and the inner housing18relative to the outer housing12. It is in this manner that the inner housing18and the first tubular member20are moved axially within the tool10.

A working chamber46is provided below piston head22and a working chamber48is provided above piston head24. The simultaneous introduction of a pressure fluid into chamber48and a release of pressure fluid from chamber46will cause the piston, including the piston heads22,24, and the mandrel M to move downwardly. The introduction of a pressure fluid into chamber46while chamber48is vented will cause the piston22,24and the mandrel M to move upwardly.

In the illustrated embodiment, a pair of diametrically opposite openings50,52are provided in the outer housing12. Fluid transmitting fittings54,56, connected to the inner housing18, are positioned within these openings50,52. As can be clearly seen fromFIG. 9, when the inner housing18moves up or down, the fittings54,56are free to move in the openings50,52.

The particular mechanism for moving the mandrel axially and the first tubular member axially can vary substantially. All that is necessary is that the mandrel M be connected to a driver that is moveable back and forth along the axis of the mandrel M and the inner housing18is connected to a driver that is capable of moving the inner housing18back and forth along the same axis on which the mandrel M moves.

Referring again toFIG. 8, the first tubular member20has a mandrel receiving center passageway60and a slotted outer end portion62comprising first axial fingers64separated by first axial slots66. The second tubular member30has a slotted outer end portion68that includes second axial fingers70separated by second axial slots72. The third tubular member32has a slotted outer end portion74comprising third axial fingers76separated by third axial slots78. The fingers64,70,76are all in the nature of leaf springs. Their free ends bend radially inwardly and outwardly as bending forces are applied to and removed from them.

Referring now to FIGS.8and12–15, the first axial fingers64have first cam surfaces80that are radially outwardly directed. The second axial fingers include second cam surfaces82that are radially inwardly directed. In response to a retraction of the first tubular member20into the second tubular member30, the cam surfaces80,82cooperated to exert a radially outwardly directed spreading force on the second fingers70. This outward springing movement of the fingers70causes them to contact and spring outwardly the third fingers76. In response to an extension of the first tubular member20within the second tubular member30, the cam surface80,82cooperate to remove the radially outwardly directed force on the fingers70, allowing the stored spring energy in them to return them to their at-rest positions in which they are relaxed axial extensions of the rest of the tubular member30. This release of the bending forces on fingers70likewise causes a release of the bending forces on fingers76, allowing them to resume their at-rest position in which they are relaxed and extend axially from the rest of the tubular member32. This is shown inFIG. 15.

The fingers70have radially inwardly directed jaws84at their free ends. These jaws84include radial clamp surfaces86and axial surfaces88which are segments of a cylinder. The first tubular member20includes substantially radial end surfaces90at their free ends. The substantially radial surfaces86constitute substantially radial first clamp surfaces. The end surfaces90constitute substantially radial second clamp surfaces. The clamp surfaces86,90are arranged to confront each other in the axial direction when the tubular members20,30,32are in the position shown byFIG. 15.

Reference is now made toFIGS. 4–7and11–15. These figures show a sleeve S that consists of a tubular body92and a radial flange94. The body92is substantially cylindrical and the flange94extends in a plane that is substantially perpendicular to the axis of the body92. The body92and the flange94are both split, as clearly shown byFIGS. 4–7. The split96extends axially of the body portion92and radially of the flange94. In its extent in the flange94, the split96may widen as it extends radially outwardly. The sleeve S is internally lubricated to facilitate movement on the mandrel M through it.

Referring toFIG. 8, the mandrel M includes a small diameter inner portion98, a large diameter outer end portion100and a transition portion102extending between the portions98,101. The mandrel M preferably includes a tapered tip104, as illustrated.

FIG. 12shows the first tubular member retracted and the jaws84spread apart. This enlarges the opening that is formed by the surfaces88to make it large enough to receive the flange94.FIG. 13shows the flange94of the sleeve S being moved axially into a cavity within the end portion of the third tubular member32. The sleeve S may be fed by hand into this cavity. Or it may be supported in some suitable manner and either the support is moved toward the tool10, or the tool10is moved towards the support, in order to cause the flange94to enter into the cavity. Once the flange94is within the cavity, the first tubular member20is extended, so as to cause the jaws84to move together.FIG. 14shows the jaws84moved partway together andFIG. 15shows the jaws84moved all of the way together. When the members are in the position shown byFIG. 16, a tubular neck portion100of the sleeve S is positioned contiguous the cylindrical segments88(FIG. 12). The inner surface of the flange94is in contact with the clamp surfaces86. The outer or opposite surface of the flange94is in contact with the clamp surfaces90. Full extension of the first tubular member20pushes the clamp surfaces90against the flange94and clamps the flange94between the clamp surfaces86,90. When the sleeve S is clamped in this manner to the end of the tool10, the tool can be picked up and moved to a workpiece W and then put into axial alignment with an opening O in the workpiece W. Then, the puller tool10is moved towards the workpiece W for the purpose of placing the sleeve S within the opening O. This is all done with the mandrel M extended.

When the mandrel M is extended through the sleeve S, its tapered end portion104will guide the mandrel M into the sleeve S. Its large diameter portion101will expand the sleeve S, allowing the sleeve to move past the large diameter portion101and the transitional portion102and onto the small diameter portion98. When the sleeve S is on the small diameter portion98, it will be contracted and its tubular portion92will fit easily into the opening O in the workpiece W. Thus, with the mandrel M extended, and a sleeve S on the small diameter portion98of the mandrel M, the mandrel is first moved into and through the opening O, followed by the sleeve S.FIG. 18shows the extended mandrel M, the sleeve S and the tool10being moved towards the opening O in the workpiece W.FIG. 19shows the mandrel M moved through the opening O and the sleeve S within the opening O. When the tooling is in this position, the mandrel is ready to be retracted through the sleeve S, for cold expanding the opening O.FIG. 20shows the mandrel M retracted into the puller tool10and shows the sleeve S still in the opening O. The flange94is still clamped between the clamping surfaces86,90. As a result, the sleeve S is connected to the jaw end of the third tubular member32. This allows a retraction of the puller tool10away from the workpiece W. This retraction removes the sleeve S from the cold expanded opening O. Now, the sleeve can be moved to a discharge station. At the discharge station, the first tubular member20is again retracted, as shown byFIGS. 22–24. When it is fully retracted, the sleeve S is released from the jaws84. (FIG. 23) This allows the sleeve S to drop free of the tool10(FIG. 24). Then, the puller tool10can be reset for reception of another sleeve S and moved into position for insertion into another opening O.

The illustrated embodiments are only examples of the present invention and, therefore, are non-limitive. It is to be understood that many changes in the particular structure, materials and features of the invention may be made without departing from the spirit and scope of the invention. Therefore, it is my intention that my patent rights not be limited by the particular embodiments illustrated and described herein, but rather determined by the following claims, interpreted according to accepted doctrines of claim interpretation, including use of the doctrine of equivalents and reversal of parts.