The invention provides a fitting, crane hook and crane hook assembly which are particularly suitable for lifting an aircraft, but may also be used to lift other loads. The invention also relates to a method of lifting an aircraft.
Crane recovery of an aircraft is a preferred method for many airports. However some aircraft do not have a strong point which is both accessible from above, and is suitably configured to attach a lifting sling or crane hook.
One solution to this problem is to inflate an airbag under a wing of the aircraft. However for large aircraft this may cause instability concerns, particularly if the airbag is wet. Also the tendency of the wing to bend as the lifting occurs increases the total height of the airbag lift required, thereby exacerbating the problem.
A first aspect of the invention provides apparatus for lifting an aircraft at a lifting location, the apparatus comprising:
The first aspect of the invention also provides a method of lifting an aircraft at a lifting location, the method comprising:
The first aspect of the invention recognises that a crane hook fitting permanently mounted to the aircraft would be unacceptably heavy. Therefore the fitting is only secured to the aircraft for the lifting operation, and removed afterwards. That is, the fitting is secured to the aircraft when the aircraft is at a lifting location such as a runway, or an area adjacent to a runway (if the aircraft has overshot or veered to the side of the runway during a landing).
Typically the fitting has a first part configured to engage the crane hook; and a second part configured to engage a lowering device (which may also be a crane hook).
A second aspect of the invention provides a fitting for transmitting lifting loads from a crane hook to an item, the fitting comprising:
The second aspect of the invention also provides a method of lifting an item using such a fitting, the method comprising:
The pivotal connection between the two parts of the fitting enables it to be secured in place without having to lift the whole fitting (which may weigh over 100 kg, and may be as much as 350 kg). Instead, the fitting is lowered into place, and only the lifting member needs to be lifted by rotating about the pivot. By making the lifting member sufficiently light (preferably less than 100 kg) this operation can be performed manually by one or two people.
Typically the attachment member and lifting member engage the same strong point (that is, a reinforced region of the item) giving a compact arrangement.
The lifting member may engage the item in such a way that it can transmit side loads to the item. However more preferably some or all of the side load from the crane hook is transmitted to the item via the attachment member.
Preferably the fitting is configured so that substantially no vertical lifting load is transferred from the crane hook to the item via the attachment member. For example the pivotal connection may be pivotally coupled to the attachment member by a floating connection.
The fitting may be used to lift any item, but is particularly suited to a method of lifting an aircraft.
A third aspect of the invention provides a crane hook assembly comprising:
The third aspect of the invention also provides a method of lifting an item using such a hook assembly, the method comprising:
coupling the hook to the item; and
The attachment link and associated biasing system ensure that the hook hangs substantially vertically when it is unloaded, making it easier to secure in place.
The hook assembly may be used to lift any item, but is particularly suited to a method of lifting an aircraft.
In its simplest form, the biasing system may consist of a biasing member such as a gas strut, or a tension or compression spring attached at one end to the attachment link and at the other end to the hook. However a problem with such an arrangement is that the biasing member must exert a large biasing force. Therefore in a preferred embodiment the biasing system comprises a first biasing link coupled to the hook at a first pivot point; a second biasing link coupled to the first biasing link at a second pivot point and to the attachment link at a third pivot point; and a biasing member which applies a biasing force causing the pivot points of the biasing links to move towards a co-linear configuration. Such a system employs mechanical advantage to reduce the force applied by the biasing member. The biasing member may be for example a gas strut or a spring, attached to the hook or the attachment link.
A fourth aspect of the invention provides a crane hook comprising a shank portion; and a hook portion extending from the shank portion, the hook portion having a ball or socket configured to couple with a socket or ball on an item to be lifted.
The fourth aspect of the invention also provides a method of lifting an item with such a hook, the method comprising:
In the preferred embodiment described below, the hook portion has a ball configured to couple with a socket in the item to be lifted. However in an alternative embodiment the hook portion may have a socket configured to couple with a ball in the item to be lifted. In both cases, the resulting ball-and-socket joint enables relative rotation between the parts in any direction.
Preferably the ball or socket remains stationary with respect to the hook during use: thus it may either be a separate part which is fixed to the hook, or it may be integrally formed with the hook.
The hook may be used to lift any item, but is particularly suited to a method of lifting an aircraft.
Embodiments of the invention will now be described with reference to the accompanying drawings, in which:
a is a second cross section through the side stay fitting and crane fitting;
b is a cross section through part of the side stay fitting and crane fitting;
a is an isometric view of the side stay fitting and crane fitting taken from the front and left hand side;
b is an isometric view of the underside of the crane fitting;
a is a view of the underside of the lifting pad;
b is a sectional view taken along line B-B in
c is a sectional view taken along line A-A in
A main landing gear of an Airbus A340 aircraft is shown in
In the event that the main landing gear 1 does not lower fully to its deployed position shown in
Because the large structural components above the main landing gear leg 2 are covered by an upper wing cover (not shown) it is not possible to gain access to them to attach a sling. The side stay fitting 7 provides a strong point which is more accessible from above, but has no structure which can support a sling easily. Accordingly, the fitting 10 shown in
In a first step, an aperture is made in the upper skin (not shown) of the wing by removing access panels. Next, the side stay assembly 6 (including a cardan pin 9 which couples it to the side stay fitting 7) is removed. Next, a crane lowers the fitting 10 through the aperture from above in the configuration shown in
The fitting 10 comprises an attachment assembly 11 which is configured to be secured to the side stay fitting 7, and a lifting assembly 12 which is pivotally coupled to the attachment assembly 11 and configured to be engaged by a crane hook so as to transmit lifting loads from the crane hook to the aircraft.
The attachment assembly 11 incorporates an eye pin 24 (shown in
The various parts of the fitting 10 are shown in the exploded view of
The attachment assembly 11 comprises a vertical plate 20 with a hole 21 bounded by a frame 22. A pair of lugs 23 extend from the lower edge of the vertical plate 20 (only one of the lugs 23 being visible in
An eye pin 24 is screwed into a hole 25 in the upper edge of the vertical plate 20, and has an eye which is engaged by a conventional crane hook or lifting sling to lower the fitting into place. Note that the eye pin 24 and hole 25 are shown in
The attachment assembly 11 is fitted to the side stay fitting 7 as shown most clearly in
a and 6b. The side stay fitting 7 has a pair of lugs 62 which receive the cardan pin 9, and upper and lower flanges 63,64 respectively. The fitting 10 is lowered by the crane hook until the tombstone 30 is aligned with the gap between the lugs 62 and flanges 63,64. The tombstone 30 is then inserted into the gap into the position shown in
The clearance (indicated at 69 in
As shown most clearly in
Because the side stay fitting 7 is handed, the blocks 42 are reversible to enable the same fitting 10 to be used on either wing. The wedges 50 between the vertical plate 20 and the side clamping plate 41 eliminate backlash in the assembly at zero load. By adjusting screws 53 passing through the wedge clamp plates 52, the screws 53 force the wedges 50 in, to provide a light clamping of the tombstone 30 onto the dummy cardan pin 60 and the trapezoidal blocks 42 onto the sidestay fitting.
Returning to
A hook socket member 74, hook retainer 75 and locking plate 76 are mounted on a lower face (not shown) of the lifting pad 70. The locking plate 76 comprises a pair of slots 77 and a handle 78. The locking plate is slidably mounted to the bottom face of the lifting pad by a pair of pins (not shown) extending downwardly from the bottom face of the lifting pad 70, and passing through the slots 77 of the locking plate 76. The pins have nuts screwed onto their distal ends which prevent the locking plate 76 from falling off. The locking plate 76 can be retracted to its release position shown in
The lifting pad is then locked into its operative position by grasping the handle 78 of the locking plate 76, and sliding it forward to the locking position shown in
An alternative locking plate 76b is shown in
The crane hook assembly 100 shown in
The hook assembly 100 includes a generally C-shaped hook with a vertical shank portion 102, a lifting portion 101 extending forwardly from an upper end of the shank portion; and a hook portion 103 extending forwardly from a lower end of the shank portion. The shank portion 102 is sufficiently long to accommodate the depth of the rear spar 8. The hook portion 103 has an integrally formed ball 104 projecting upwardly and positioned towards its distal end. The lifting portion 101 of the hook carries a pair of lifting mechanisms for ensuring that the hook will always be in the vertical position when being lifted, i.e. either loaded or unloaded. The weight of the assembly 100 is approximately 1500 Kg.
One of the two lifting mechanisms is attached to the left-hand side of the lifting portion 101 and is indicated at 105 in
The lifting mechanism 105 comprises an attachment link 106 having a first pivot pin 107 attached to the hook forward of its centre of gravity 108, and a second pivot pin 109 which is coupled to the attachment link of the right-hand lifting mechanism (not shown). The hook assembly is lifted by coupling a crane hook to the pin 109. A biasing system applies a biasing force to the attachment link 106 causing it to rotate about the first pivot pin 107 whereby the second pivot pin 109 moves towards the rear of the hook to the position shown in
The biasing system comprises a first biasing link 110 coupled to the hook via an arm 111 at the distal end of the upper lifting portion 103 and a first pivot point 112; a second biasing link 113 coupled to the first biasing link 110 at a second pivot point 114 and to the attachment link 106 at a third pivot point 115; and a compression spring 116 which applies a biasing force causing the pivot points 112,114,115 to move towards the approximately co-linear configuration shown in
In the unloaded configuration shown in
In an alternative embodiment (not shown) the spring 116 may be coupled at one end to the pivot point 114, and at its other end to the lifting portion 101 of the hook (instead of the attachment link 106).
As shown in
The ball 104 fits into the socket as shown in
If the locking plate 76 is insufficiently strong to support the full weight of the hook when the crane cable goes slack, then two alternative arrangements are possible:
After the ball 104 has been secured in place, the hook 100 is lifted and the lifting pad 70 transmits the vertical lifting load to the aircraft via the side stay fitting 7 and spar 8. Once the aircraft is level, a support cradle is placed under the wing, and the lifting load from the crane is gradually reduced until the support cradle carries the full weight. The fitting 10 is then engaged by the conventional crane hook which was previously used to lower it into place; removed from the side stay fitting 7, and lifted away from the aircraft.
The ball and socket joint coupling the hook assembly 100 to the fitting 10 can accommodate a relative rotation in any direction of 15 degrees. This accounts for the changing attitude of the aircraft as it is lifted and the probability that the slope of the contact surface of the lower flange 64 is not horizontal when the aircraft is horizontal. Note that in the case of the A340 the slope of the contact surface of the lower flange 64 is 11 degrees when the aircraft is horizontal.
The holes in the hinge lugs 71 and/or the hinge lugs 23 are oval (with the long axis of the oval aligned vertically). This provides a floating connection which enables the lifting pad 70 to float in the vertical direction, ensuring that substantially none of the vertical lifting loads are transferred into the vertical plate 20. Therefore all of the vertical lifting load passes through the lifting pad 70 into the lower flange 64 of the side stay fitting 7 and the rear spar of the wing.
Any side loads (i.e. fore-and-aft and transverse loads) arising from the lifting operation (typically due to the top of the crane jib slewing relative to the aircraft, which may arise from the aircraft lurching as it lifts) will pass from the lifting pad 70 into the attachment assembly 11, and then into the sidestay fitting 17. The hinge lugs 71, 23 are designed to accept a sideload of 33% of the vertical load, acting simultaneously with the vertical load and acting in any direction.
Aluminium alloys can be used for some of the major components of the fitting 10, thus reducing its weight.
Clearances are minimised so as to prevent as far as possible any slipping in the assembly. Pre-tensioning of the assembly using the wedges 50 removes backlash in the unloaded assembly.
Contact with the bottom wing skin (not shown) are restricted to areas immediately below the side stay fitting 7 and the bottom flange and web of the rear spar 8.
It should be noted that although the fitting and crane hook assembly described above are configured to lift an A340 aircraft via its side stay fitting, the invention is not limited to such use. Therefore a similar fitting and/or crane hook assembly may be used to lift the A340 via another strong point, to lift another aircraft, or to lift any other item.
Although the invention has been described above with reference to one or more preferred embodiments, it will be appreciated that various changes or modifications may be made without departing from the scope of the invention as defined in the appended claims.
Number | Date | Country | Kind |
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0701543.1 | Jan 2007 | GB | national |
This application is a Division of application Ser. No. 12/449,165, filed Jul. 27, 2009, which is the U.S. national phase of international application PCT/GB2008/050027, filed in English on 14 Jan. 2008, which designated the U.S. PCT/GB2008/050027 claims priority to GB Application No. 0701543.1 filed 26 Jan. 2007. The entire contents of these applications are incorporated herein by reference.
Number | Date | Country | |
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Parent | 12449165 | Jul 2009 | US |
Child | 13651543 | US |