Apparatus and a method of support and retaining a curved sheet in position

An apparatus for supporting and retaining in position a curved sheet (5) which is to be subjected to a machining operation comprising a plurality of support devices (6) spaced apart at regular intervals on a support plate (7), which support devices are positionable at predetermined locations to support and retain the sheet (5), wherein each support device (6) comprises a sliding support member (10) positionable against a contact member, the support member having means (12) capable of adhering to a sheet (5) pivotally mounted thereon, and control means (31) for controlling the pivotal movement of the adhesion means (12) so as to bring the sheet (5) into contact with the positioned support member (6) and to hold the sheet in position to permit machining to take place.

FIELD OF THE INVENTION 
The present invention relates to an apparatus and method of retaining a 
curved sheet in position. More particularly, but not essentially the 
apparatus and method of the present invention are intended for retaining 
aircraft panels or the like, which are to be subjected to machining 
operations such as cutting, contouring and drilling using automatic 
machine tools. 
BACKGROUND OF THE INVENTION 
Apparatuses are known which are used to retain curved sheets in position. 
Such devices comprise a plurality of devices spaced apart at regular 
intervals on a support plane in a grid-like arrangement. Each device is 
provided with means for adhesion to the sheet to be retained in order to 
hold the sheet in position. Furthermore, each of the devices is positioned 
automatically, independently of all other devices, at a predetermined 
height so as to match the profile of the sheet in the region of the 
support device. The sheet is thus supported at a certain number of points 
on its surface, regardless of the configuration thereof. 
In industry, particularly the aircraft industry, it is frequently necessary 
to perform precision machining on sheets or similar two dimensional units 
having a curved surface. Obviously, for precise machining to be achieved, 
it is essential to position the sheet with maximum accuracy and to retain 
it in a fixed position whilst the various machining operations are being 
effected. The difficulties which arise when the sheet or panel has length 
and breadth dimensions of the order of meters but a thickness of the order 
of millimeters and has a curved surface, but which must, nevertheless, be 
retained in position without being deformed or damaged will be readily 
apparent. 
The use of fixed profiles corresponding to the geometry of a particular 
panel would be uneconomic in view of the relatively high number of 
profiles which it would be necessary to provide to ensure that any panel 
could be retained. 
For this reason, apparatuses have been developed which consist of a 
plurality of support members which can be positioned so as to produce a 
support structure corresponding to the profile of the sheet. The sheet is 
then attached to the support members. One particular apparatus of this 
type is disclosed in U.S. pat. No. 4,491,306. Reference should now be made 
to FIG. 1 of the accompanying drawings which shows, schematically, an 
apparatus as disclosed in U.S. Pat. No. 4,491,306. Such an apparatus 
comprises a support member A which can be positioned at various heights. 
The upper portion of the support member A is provided with a hemispherical 
cup B within which a cap C of a substantially complementary shape is 
rotatable. 
The cap C is provided, on its upper edge, with a suction cup D and the base 
thereof is connected to a spring E which is mounted on the base of the cup 
B and retains the suction cup D in the position illustrated in the figure. 
Within the cup C, a pin P is provided, which pin extends radially. The 
upper end of the pin P coincides with the center of rotation of cap C, as 
is disclosed in column 4 at lines 54-57 of U.S. Pat. No. 4,491,306. 
The rotatability of cap C within the cup B allows the suction cup D to 
correspond to the inclination of a sheet which is rested thereon. The 
sheet is retained in position by depressurising the interior of the cups 
D. The pin P also provides a further point of support for the sheet. 
The possibility of automatically controlling the raising of support A so as 
to bring pin p in contact with the sheet being machined is also foreseen 
in the above-mentioned patent. To achieve this, provision is made, as 
described in column 5 at lines 58 et seq, for the mounting of a proximity 
sensor. 
Such an arrangement does not, however, fully satisfy industrial 
requirements. The fact that the sheet itself is used as a contact for 
positioning the supports poses considerable problems, in that it is 
necessary to provide means whereby a panel having length and breadth 
dimensions of the order of meters can be positioned with maximum accuracy 
so that the support members may then be adjusted. A further disadvantage 
resides in the fact that the position of the upper extremity of the pin P, 
which constitutes a support point for the sheet, is fixed with respect to 
the edge of the suction cup D. In consequence, the device is not 
automatically adjustable so as to retain sheets of different curvature. To 
achieve this, the pin must be replaced by another pin of an appropriate 
length. Thus, in the case of concave sheets it is necessary to use a pin 
which projects outwardly from the suction cup and, in the case of a convex 
sheet, a pin which does extend as far as the suction cup. 
If an excessively long, that is to say, projecting pin is used, the sheet 
does not adhere adequately to the suction cup, so that adhesion to the 
corresponding support is thus correspondingly inadequate. A pin which does 
not extent as far as the suction cup provides good adhesion, but it does 
not provide the central support point for the sheet. 
SUMMARY AND OBJECTS OF THE INVENTION 
The present invention therefore seeks to provide an apparatus which can be 
used for securing curved sheets comprising support devices which can 
automatically assume a given configuration and which ensure that the sheet 
is held effectively. In a further aspect, the present invention seeks to 
provide a method of securing sheets in position so that machining 
operations can be carried out thereon. 
According to the present invention, there is provided an apparatus for 
supporting and retaining in position a curved sheet which is to be 
subjected to a machining operation comprising a plurality of support 
devices spaced apart at regular intervals on a support plate which support 
devices are positionable at predetermined locations to support and retain 
the sheet, wherein each support device comprises a sliding support member 
positionable against a contact member, the support member having means 
capable of adhering to a sheet pivotally mounted thereon, and control 
means for controlling the pivotal movement of adhesion means so as to 
bring the sheet into contact with the positioned support member and to 
hold the sheet in position to permit machining to take place.

DESCRIPTION OF THE PREFERRED EMBODIMENT 
In FIG. 2 there is shown an example of an automatic machine tool used for 
the operation of contouring or drilling curved sheets. Such machine 
includes a portal structure 1, which is displaceable along guides 2. The 
structure 1 has a displaceable arm 3 mounted thereon. At the lower end of 
the arm 3 is located a toolholder head 4. 
A curved sheet 5 which is to be machined is placed on and secured to, a 
plurality of support devices 6. These devices 6 are mounted on a base 
member 7 located between the guides 2 and are each equipped with means for 
adhering to the sheet so as to retain it in position. Each device 6 
comprises a flange member 8 affixed to the base member 7 and an upright 
member 9 which can be immobilized at different heights relative to the 
flange member 8. 
Within the upright member 9, a cylindrical chamber 20 is defined, within 
which a double-acting piston 10 is slidably displaceable. The piston 10 
has mounted thereon a support member 11 for a suction cup 12 by means of a 
ball joint. These features are illustrated more clearly in FIG. 4. 
Between the flange member 8 and the upright member 9, a collar 13 is 
disposed, which collar includes a projection portion 14 having an inclined 
surface which engages with a correspondingly-shaped surface of the flange 
member 8. The collar 13 is urged upwardly by means of a spring washer 15 
or the like and may be tightened by means of a bolt 16 which immobilizes 
the upright member 9. 
Substantially diametrically opposed to the bolt 16, a shaft 19 is mounted 
on the flange member 8. The shaft 19 has a collar integrally formed 
therewith which collar is provided with an eternal screw thread 18. This 
thread 18 meshes with a rack 17 formed on the upright member 9 and 
extending parallel to the longitudinal axis thereof. 
As previously mentioned, a cylindrical chamber 20 is defined by the 
interior of the upright member 9. This chamber 20 receives the 
double-acting piston 10. Ducts 22 and 23 respectively carry compressed air 
to the lower and upper regions of the chamber 20. 
At its upper end, the upright member 9 is provided with a head member 24 in 
which an annular chamber 25 is defined. The chamber receives a collar 26, 
also annular, which is provided with seals 27 on its underside to ensure a 
leaktight connection between the collar 26 and the annular chamber 25. 
On one side, the collar 26 rests on a protuberance 28 formed on the base of 
the chamber 25. Substantially diametrically across the chamber from the 
protuberance 28, a helical spring 29 is disposed. The spring 29 presses 
against the base of the collar 26. A duct 30, which is connected to 
devices (not shown) for injecting air under pressure into the lower 
portion of the chamber 25, is also provided in this region of the chamber. 
The collar 26 serves to immobilize the piston 10 when it is in its desired 
position. 
The piston 10 is also hollow, and a single-acting piston 31 is slidably 
displaceable therein. The piston 31 is guided from above by an upper cap 
member 32 and from below by a piston rod 33. An axial conduit 34, 
communicating with the interior of the chamber 35 in which piston 31 is 
slidably displaceable, is defined with the piston rod 33. The piston 31 is 
urged upwardly by means of a spring 36. 
At the upper end of piston 10, a ball joint 38 is provided on which the 
support member 11 for the suction cup 12 is mounted. The ball joint 38 is 
connected, through the intermediary of a pin 39, to the upper end of 
piston 31 by means of a nut 40. A bush 41, made from a friction-reducing 
material such as nylon, is disposed between the pin 39 and the ball joint 
38. The pin 39 is vertically slidably displaceable with respect to the 
piston 10 along a pair of slots 42. 
Within the support member 11 is fitted a membrane 43, made of hard rubber, 
for example, of the type known by the trade name VULKOLAN. The membrane 43 
abuts against the upper portion 37 of the ball joint 38. The support 
member 11 is pierced by a duct 44 which leads to the interior portion of 
the suction cup 12. At its other end, the duct 44 is connected to devices 
(not shown), for pumping and extracting air so as to maintain the interior 
of the suction cup at a higher or lower pressure than atmospheric pressure 
in dependence upon prevailing requirements. 
The support and securing devices 6 which, in use, are disposed around the 
periphery of the sheet 7 are also provided with a second suction cup 45 
mounted on an arm 46 which is integral with the support member 11 for the 
suction cup 12. The interior of the suction cup 45 is also connected by 
means of a duct 21, to the abovementioned devices for the delivery and 
extraction of air. 
The suction cups 45 serve, for example, to retain a portion of the sheet 
which is being cut off during sheet cutting operations. This prevents, or 
at least minimizes, deformation and vibration which would otherwise damage 
the sheet or panel. 
The use of the apparatus of the present invention will now be described. An 
approximate positioning of each support device is first performed by 
appropriately adjusting the height of the upright member 9. To achieve 
this, the bolt 16 is slackened, thereby allowing the spring washer 15 to 
push the collar 13 upwardly to release the upright member. The shaft 19 is 
then moved by rotating the collar carrying the external screw thread 18 
which engages with the rack 17 and which axially displaces the upright 
member 9. Once the desired approximate level has been reached, the upright 
is once more immobilized by re-tightening the bolt 16. 
Thereafter, the positioning operations will normally be performed 
automatically. This is because the toolholder head is usually controlled 
electronically through a computer system. The electronic devices which 
control the machine tool locate the toolholder head 4 on the upper 
surfaces of the support and retaining members 6 and lower these members to 
the level which they should occupy when the sheet is located thereon for 
the machining operation. 
Compressed air is then passed into the chamber 25, below the collar 26, 
through the duct 30. The pressure exerted by the air lifts the collar 
against the force of the spring 29, thereby releasing the piston 10. At 
this point, compressed air is also passed into duct 22 and thence into the 
lower portion of the chamber 20, which causes the piston 10 to rise. Such 
rising entrains the raising of the single-action piston 31, which is urged 
upwardly by the spring 36. At this stage, the relative positions of the 
pistons 10 and 31 are as shown in FIG. 4. 
The travel of the piston 10 is terminated when the rubber membrane 43 abuts 
against the toolholder head 4. Such abutment is detected by the use of 
sensors of a known type such as pressure sensors (not shown). The supply 
of air to the duct 30 is then interrupted, so that the pressure within 
chamber 25 drops and the spring 29 urges the collar 26 downwardly. The 
collar thus adopts an inclined position and immobilizes the piston 10. The 
computer which controls the machine tool then moves head 4 to the top of 
the next support and retaining member 6 and the operation is repeated. 
In this way, a series of support points is obtained, which corresponds to 
that of the sheet to be machined. The sheet 5 is then located on the 
support members 6 in approximately the desired position. Thereafter, 
compressed air is passed into the interior of the suction cups 12 and 45 
so as to create a cushion of air on which the sheet can be easily moved 
and positioned accurately relative to suitably preadjusted fixed lateral 
stops. 
At this point, the position of the sheet must be stabilized before 
machining can be commenced. To achieve this, air is first withdrawn from 
the ducts 44 and 21 so as to set up a reduced pressure in the suction 
cups, which therefore adhere firmly to the sheet. 
The next stage provides for the delivery of compressed air along the duct 
34 into the interior of the chamber 35. This overcomes the force of the 
spring 36 and draws the piston 31 downwardly. By so doing the pin 39 also 
moves downwardly in the slots 42, as do the lateral portions 38 of the 
ball joint and the support member 11 for the suction cup. Lowering in this 
manner occurs until the sheet comes into contact with the hard rubber 
membrane 43. This position, which is shown in FIG. 5, is maintained by 
suitably adjusting the pressure within the chamber 35 and maintaining it 
at a constant level until the machining is completed. 
On completion of the machining, ambient pressure is restored to the 
interior of the suction cups 12, thus releasing the sheet, and also within 
the chamber 35 which permits the spring 36 to move the piston 31 with the 
ball joint and suction cup support upwardly again. If necessary, 
compressed air may be passed through the duct 44 to assist in the removal 
of the sheet. 
The support and retaining device according to the present invention thus 
automatically matches the curvature of the sheet, irrespective of whether 
it is concave or convex. Moreover, the sheet is brought into contact with 
a support member which is automatically pre-positioned to the desired 
height and is held in position until the machining operation has been 
completed.