Extractor

A device for pulling a bushing from a housing comprises a collet having legs which are expanded outwards by a cam action. The collet and cam are mounted on a shaft and the collet legs pushed onto a conical cam surface of the cam to expand them outwards. Ribs on the outer surface of the legs engage the end of the bushing as the shaft is withdrawn through the bushing and housing, pulling the bushing from the housing.

INTRODUCTION AND BACKGROUND 
The present invention relates to an extractor for bushings, sleeves, liners 
and the like. 
Present methods of extracting bushings, sleeves, liners and the like 
(hereinafter referred to generally as bushings) which are an interference 
fit in a housing often result in damage to the bushing and/or the housing. 
Using a drift to drive out the pushing will score the housing and deform 
the end of the bushing. 
SUMMARY OF THE INVENTION 
The present invention provides a device for extracting a bushing from a 
housing, in which a collet has a plurality of legs which are expanded 
outwards by a cam action. The outer surfaces of the legs carry lips for 
bearing on an end face of the bushing, and the legs are expanded out so 
that the lips extend out to a predetermined diameter which is slightly 
less than the inner diameter of the housing. The expanded collet is then 
used to pull the bushing from the housing. 
More particularly, a pulling shaft carries a cone shaped cam at one end 
which is inserted through the length of the bushing. The collet is carried 
on the shaft and the legs are urged up onto the cam by a nut carried on a 
thread on the shaft. 
Ends of the collet legs abut a flange at the base of the cone to limit the 
movement of the legs on the cam, and hence allow an accurate 
pre-determination of the expansion of the legs. 
The shaft is pulled from the housing, carrying the cam, collet, and bushing 
with it, preferably by a hydraulic ram. The shaft extends through a 
centerless ram, and the ram reacts against the housing, preferably via a 
sleeve into which the bushing can feed as it leaves the housing. 
By providing a system in which the collet legs are expanded to a fixed, 
pre-determined amount, the operator can be assured that the collet is 
expanded sufficiently to provide adequate purchase on the end of the 
bushing, whilst avoiding damage to the housing. 
The device of the invention is particularly suitable for removing bushings 
from aircraft components, such as the landing gear. The device is also 
useful in mining, marine and transportation applications.

DESCRIPTION OF THE PREFERRED EMBODIMENT 
FIG. 1 shows a particularly preferred embodiment of the invention, which is 
shown positioned for removing a bushing 2 from an aircraft landing gear 
component 4. The bushing 2 is housed in a cylindrical housing 6. 
The pulling device 8 of the invention comprises a central pulling shaft 10. 
A cam member 12 is screwed onto a threaded end 14 of the shaft 10 and a 
forward end 18 of the cam member 12 abuts a shoulder 16 on the shaft. 
The cam member 12 tapers outwards from the forward end 18 to form a 
frusto-conical cam surface 20 and ends in a peripheral flange 22. 
Shown in its expanded condition is a collet 24 which is seen more clearly 
in FIG. 2 in its contracted condition. The collet 24 has a central boss 26 
which is a sliding fit on the shaft 10. A plurality of legs 28, eight in 
the embodiment shown, extend radially outwardly from the boss 26 and then 
axially, generally to form a cylinder, the legs 28 being separated to 
allow them to spring inwardly at their free ends 30. The free ends 30 each 
have an inner surface 32 in the form of a frusto-conical segment which 
lays flat against the surface 20 of cam member 12 when the collet legs 28 
are fully opened apart. Outer surfaces 34 of the ends 30 are close, but 
not tight, against the inner surface 36 of the bushing 2 when the legs 28 
are fully opened apart. Engagement means in the form of a 
circumferentially extending lip or rib 37 is provided on each surface 34 
and has a radially extending surface 38 which abuts against an end 40 of 
the bushing 28. The collet 24 and cam 12 are machined from high tensile 
treated carbon steel, such as EN24 ' T'. 
The collet 24 is machined to its expanded shape, as seen in FIG. 1, and the 
outer surface 42 of each leg 28 is shot peened, which causes the legs to 
bend resiliently inwards, to the form seen in FIG. 2. The degree of bend 
is sufficient to allow the collet 24, with the legs sprung inwardly, to 
pass into the bushing 2. 
The collet 24 and cam 12 are dimensioned so that when the ends 30 of the 
legs 28 abut the flange 22, the ribs 37 are a few thousandths of an inch 
clear of the inner wall of the housing 6, typically five thousandths 
clearance is provided on the diameter. Since the bushing 2 is likely to be 
worn, no reliance is placed on the internal diameter of the bushing to 
limit the outward movement or positioning of the leg ends 30. 
The collet 24 is pushed onto the cam surface 32 by a collar 42 which is 
threadedly engaged on the shaft 10, the thread 44 being of opposite hand 
to the thread 46 securing the cam 12 on the shaft 10. 
The collar 42 has a central boss 46 which slides within the bushing 2 and 
bears on the boss 26. A flange 48 is arranged to bear on an outer end 50 
of the bushing 2, or on the component 4 if the bushing is let fully into 
the housing 6. The collar 42 and collet 24 are dimensioned so that when 
the flange 48 abuts the end 50 of the bushing 2, the ribs 37 just clear 
the end of the bushing 2. 
A cup 52 is a sliding fit on the shaft 10 and its open end 54 bears on the 
component 4, clear of the bushing 2. Where there is not sufficient bearing 
area around the bushing 2, an adjustable leg assembly 56 is provided to 
bear on another part of the component 4. The cup 52 has one or more axial 
slots 58 which each receive a guide pin 60 screwed to the flange 48, the 
pin(s) 60 serving to prevent rotation of the collar 42 relative to the cup 
52. 
The cup 52 at its closed end 62 is mounted on an end face 64 of a hollow 
central hydraulic ram 66, the shaft 10 passing through the ram 66. The cup 
is fixed against rotation relative to the ram 66, for example by a screw 
68, or the cup may be held on by magnets, an aperture in the end 62 
cooperating with a pin on the end face 64 of the ram 66 to prevent 
rotation of the cup. 
A support bar 70 is pivotally attached to a collar 72 on the ram 66 for 
slinging the apparatus from a jig or the like to take the weight of the 
apparatus. 
At the outer end 74 of the shaft 10, a nut 76 is threaded on the shaft 10 
and is arranged to be tightened up against the ram piston 78, (shown in 
dotted outline) the piston moving to the left in the drawing. 
A knurled nut 78 is screwed on the outer end 74 of the shaft 10. 
In operation, the cup 52 is located on the end face 64 of the ram 66 and 
the shaft end 74 slid through the cup and ram and nuts 76 and 78 screwed 
onto the shaft end. The collar 42 is slid over the shaft end 14 and 
screwed down towards the ram 66. The collet 24 is then slid over the shaft 
end 14 and a spring 80 slid over the shaft and the cam 12 screwed into 
place. The spring 80 serves to space the collet 24 from the cam 12 until 
the collar 42 is tightened. In this condition the legs 28 of the collet 24 
are contracted (bent inwardly) and so the cam 12 and collet 24 can be slid 
into the bushing until the flange 48 on the collar 42 abuts the end of the 
bushing. The shaft 10 is then rotated (using nut 78) to screw the collar 
42 towards the cam 12, (threads 44,46 being of opposite hand). The flange 
48 is pressed against the end of the bushing 2 so that as the legs 28 
expand outwards the ribs 37 are clear of the outer end of the bushing. The 
collar is prevented from rotating by the pins 60 in slots 58. The operator 
will feel when then ends 30 of the legs 28 have abutted the flange 22, 
which is when the collet 24 is fully opened. 
The nut 76 is then screwed down onto the piston 78 and the ram 66 operated 
to push the nut 76 and the shaft 10, to the left in the drawing. The ribs 
37 abut the end of the bushing 2 and so the bushing is drawn out of the 
housing, into the cup 52. 
A shoulder 82 on the shaft 10 limits the movement of the shaft 10 through 
the ram, to prevent force being applied to the collar 42. 
Where the throw of the ram is not sufficient to withdraw the bearing in one 
movement, a spacer can be added between the nut 76 and ram 66, or between 
the cup 52 and the component 4 after contracting the ram, and the ram then 
expanded again. 
It will be appreciated that the cam 12, collet 24, collar 42 and cup 52 are 
all dimensioned to suit a particular bushing in a particular component. 
Although this requires a large number of parts, a service kit for a 
particular application, such as aircraft landing gear, can be put 
together. The saving in time and cost on removal of bushings readily 
compensates for the cost of providing dedicated components for each 
bushing. By machining each collet and cam pair to close tolerances, it is 
possible to ensure that the lands 38 on ribs 37 abut squarely on the end 
of the bushing 2 and the ribs 37 do not foul the surface of the housing 6. 
After use, the shaft 10 is screwed down through the collar 42 to release 
the collet 24 from the cam 12, the resilience of the legs 28 causing the 
ends 30 to contract inwardly to release the bushing 2. 
It will be appreciated that for smaller bushings the ram 66 need not be 
used. A nut such as nut 76 may be screwed down the shaft 10 to abut the 
cup 52 and draw the shaft through the cup. Also, the cam may be integrally 
formed on the shaft. 
Various modifications may be made to the described embodiment and it is 
desired to include all such modifications as fall within the scope of the 
accompanying claims.