The present invention relates to load handling apparatus and in particular to apparatus for loading and unloading portable bridge structures on to and off wheeled or tracked vehicles.
In many field operations there is a requirement for tracked and/or wheeled vehicles to traverse terrain which contains obstacles such as waterways, ditches or other similar topographical features which cannot be crossed by the said vehicles. The conventional method of negotiating such terrain is to span the said obstacles by means of a bridge structure which is brought up to the obstacle by a vehicle. The vehicle bringing the portable bridge must be provided with suitable apparatus to position the bridge to span the obstacle and the said apparatus must have the capability of recovering the bridge and transporting it to another site when required.
Known methods for accomplishing the bridging operation fall into two broad categories.
In prior art of the first type, translation is accomplished by a complicated rack-and-pinion mechanism driven by hydraulic motors, and the lowering by means of a system of levers. In prior art of the second type, both the rotation and translation processes are accomplished by a linkage system involving at least one pivotable structural element which is rotated by one or more hydraulic cylinders.
Bridges of this type have got longer as structural materials have improved.
In
There are three stages to the deployment process:
First the bridge 1, the foot 3, the raising and lowering member 4, the probe 5 and the linear actuators 7 and 8 are rotated about axis 9 by the linear actuator 6 until the foot 3 presses on the ground as shown in
Secondly the foot 3, the probe 5 and the linear actuator 8 are rotated about axis 10 until the foot 3 is flat on the ground (as shown in
Finally, the bridge 1 and the probe 5 are rotated about axis 11 until the bridge is in its deployed position (as shown in
The vehicle usually picks up the bridge after crossing it. The vehicle advances towards the bridge with the foot 3 just off the ground and the probe 5 lowered. Once the probe 5 has engaged with the socket on the bridge 1, it may be recovered using the reverse of the deployment process.
This prior art has the following disadvantages:
Preferred embodiments of the present invention seek to overcome all of the disadvantages of the prior art.
According to an aspect of the present invention, there is provided an apparatus for carrying a bridge on a vehicle and deploying the bridge to the ground, the apparatus comprising:
mounting means for mounting the apparatus to a vehicle;
ground engaging means pivotable relative to said mounting means between a first position in which the ground engaging means engages the ground for supporting a bridge and a second position in which the ground engaging means is separated from the ground to permit movement of the vehicle;
first actuator means for pivoting the ground engaging means between said first and second positions;
bridge engaging means pivotable relative to said ground engaging means between a third position in which the bridge is on the ground and a fourth position in which the centre of gravity of the bridge is raised relative to the third position; and
second actuator means for pivoting the bridge engaging means between said third and fourth positions;
wherein said first and/or said second actuator means comprises at least two respective actuators arranged such that the sum of the turning moments produced by said respective actuators is never zero when said actuator means pivots between said positions.
The present invention uses one or more instances of an unusual mechanism which rotates an arm about a pivot against the gravitational force due to the weight of said arm.
In contrast, the upright cylinder 14 provides a moment F*c which has a characteristic matching that of the load moment W*a. A hiatus occurs when the arm 12 and cylinder 14 are upright as the cylinder can exert no moment. This is overcome by using two smaller bore cylinder with pivots offset (at A and B) as shown. This arrangement can efficiently drive an arm through more than 180°. The optimum positioning of these two pivots is a major part of designing a bridge deploying apparatus of this kind.
The apparatus may further comprise a foot frame pivotable in use about an axis on the vehicle and transverse to the direction of travel of the vehicle and adapted to transfer the ground engaging means between the ground and a location substantially at the height of the roof of the vehicle.
The bridge engaging means may comprise a bridge engaging probe pivotably mounted on a transverse axis across the ground engaging means and adapted to lay the bridge on the ground when the ground engaging means is in the first position and above the vehicle when the ground engaging means is in the second position.
The second actuator means may be connected between the bridge engaging means and the ground engaging means and said first actuator means may be connected between the ground engaging means and the vehicle in use.
Pivots on the ground engaging means mounted to a plurality of said actuators of said second actuator means and/or pivots on the vehicle in use mounted to the actuators of said first actuator means may be angularly offset relative to each other in planes transverse to the respective pivot axis.
The apparatus may further comprise at least one roller adapted to be fixed on the vehicle roof for supporting the bridge when in contact therewith.
In the absence of a bridge, the bridge engaging means and ground engaging means in use can be positioned in different positions from said respective fourth and second positions.
This provides the advantage of enabling weight distribution to be optimised.
At least one said linear actuator may be a hydraulic cylinder.
The apparatus may further comprise means for changing the direction of flow of hydraulic fluid into or out of at least one said hydraulic cylinder at appropriate angular positions of support frames connected thereto so that the direction of movement and continuity of rotation of the said support frames proceed in the desired direction.
The apparatus may further comprise means for closing off the ports to the hydraulic cylinders so as to selectively lock the rotary mechanism in specified configurations or to allow free flow of hydraulic fluid in to or out of the actuators so that the chosen frame can rotate freely.
According to another aspect of the present invention, there is provided a vehicle comprising a vehicle body and an apparatus as defined above.
The apparatus may be adapted to be releasably mounted to the vehicle body.
The apparatus may be adapted to be releasably mounted to the vehicle body by means of interlocking parts on the apparatus and the vehicle body and at least one locking mechanism on the apparatus and the vehicle body such that said interlocking parts and the or each said locking mechanism can be released in use by releasing the or each said locking mechanism.
A preferred embodiment of the invention will now be described, by way of example only and not in any limitative sense, with reference to the accompanying drawings, in which:
Referring to
The bridge deploying apparatus 23 comprises a probe 17 for insertion into an aperture 21 in the bridge 1, the probe 17 being pivotably mounted at a pivot 16 to a foot 18 which engages the ground 20. The probe 17 is also connected to separate locations 22, 24 on a bracket 26 extending from the foot 18 by means of a first hydraulic cylinder actuator 28 and a second hydraulic cylinder actuator 30. The foot 18 is connected to the mounting bracket 19 by means of a pair of support struts 32 which pivot about the axis 25, driven by a third cylinder actuator 34 and a fourth cylinder actuator 36.
The first 28 and second 30 cylinder actuators are arranged such that their extension and/or contraction causes pivoting movement of the probe 17 relative to the foot 18 from a first position as shown in
Similarly, the third 34 and fourth 36 cylinder actuators are connected to respective separate locations 40, 42 on the vehicle mounting bracket 19, as a result of which the angular movement of the foot 18 relative to the vehicle 2 from the position shown in
This arrangement of the cylinder actuators 34, 36 provides the advantage of enabling the large forces to be generated when required to move the foot 18 from the position shown in
The operation of the bridge transporting vehicle 2 and bridge deploying apparatus 23 thereof will now be described.
Referring to
The first 28 and second 30 cylinder actuators are then contracted to pivot the bridge 1 upwardly relative to the foot 18 to a transition position when the second cylinder actuator 30 has no moment about the bridge pivot 16, while the foot 18 rests on the ground 20. The bridge 1 is then further pivoted in a clockwise direction by further contracting the first cylinder actuator 28 and extending the second cylinder actuator 30 up to a second transition point when the first cylinder actuator 28 has no moment about the bridge pivot 16.
The bridge 1 is then further pivoted in a clockwise direction by extending both the first 28 and second 30 cylinder actuators up to a point so that the centre of gravity 38 of the bridge 1 is located well within the wheelbase 41 of the vehicle, as shown in
The third 34 and fourth 36 cylinder actuators are then contracted to rotate the foot 18 clockwise about pivot 25. This causes the bridge 1 to further rotate clockwise relative to the vehicle 2 until the bridge 1 is in contact with the rollers 44 as shown in
In order to move the bridge 1 from the transport position shown in
It will be appreciated by persons skilled in the art that during certain phases of the rotation of the bridge 1 about the axis 16, the cylinder actuators 28, 30 are lifting the bridge 1 and at others are controlling the speed at which the bridge 1 falls under the action of gravity. For this reason, it would be possible to control the rotation of the bridge 1 using pressure in only the annular side the cylinder actuators 28, 30 or by using tension-only actuators (such as a cable and winch). The same statement can be made regarding the cylinder actuators 34, 36 as they control the rotation of the foot 18 about axis 25.
It will also be appreciated by persons skilled in the art that when the foot 18 is lifted from the ground (
Referring to
With the hooks 54 engaged in the brackets 56 and the feature 58 engaged in the slot 60 of the actuator 62 and the hydraulic cylinder pin 68 engaged in the hole 64 in feature 58, the second assembly 52 is securely connected to the first assembly 50 and thus the bridge deploying apparatus 23 is securely connected to the vehicle 2.
To disconnect the first 50 and second 52 assemblies from each other, the bridge deploying apparatus 23 is ideally arranged to be lying gently on the ground, although the following is true even if in an emergency situation the bridge deploying apparatus 23 is at some height above the ground. Pin 68 is then retracted by the cylinder 66 from the hole 64 in the lug 58. The first assembly 50 remains attached to the vehicle 2, and the second assembly 52 attached to the bridge deploying apparatus 23 will now fall away from the vehicle 2, the exact motion of the second assembly 52 depending on the position/height of the bridge deploying apparatus 23 at the time the pin 68 is retracted. The vehicle 2 can now be reversed away from the bridge deploying apparatus 23 and second assembly 52 and in doing so the hooks 54 in the second assembly 52 will disengage from the bracket 56 in the first assembly 50.
It will be appreciated by persons skilled in the art that the above embodiment has been described by way of example only, and not in any limitative sense, and that various alterations and modifications are possible without departure from the scope of the invention as defined by the appended claims.
Number | Date | Country | Kind |
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0907749.6 | May 2009 | GB | national |
0911206.1 | Jun 2009 | GB | national |
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Number | Date | Country | |
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20100281633 A1 | Nov 2010 | US |