Pipe-laying machine for oil pipelines, conduits and the like

A pair of self-propelled vehicles joined by an intermediate bridge having a rigid lifting arm hinged at one end to the intermediate bridge and having a device for gripping and lifting the pipes carried by the free end of the rigid arm such that the rigid lifting arm may be controlled to engage a pipe and lift it over the trench and lower the pipe into the desired position.

BACKGROUND OF THE INVENTION 
This invention relates in general to pipe-laying equipment, and, in 
particular, to apparatus operable from opposite sides of a trench for 
continuously lifting and laying pipe into the trench. 
More specifically, but without restriction to the particular use which is 
shown and described, this invention relates to an apparatus including 
self-propelled vehicles positionable on opposite sides of a trench and 
connected through an intermediate connection bridge for lifting and 
positioning pipe within the trench. 
Various types of pipe-laying equipment have been utilized to lift and 
position pipe within a trench. Such equipment includes self-propelled 
counterweighted vehicles which utilize counterweight apparatus to balance 
the vehicle during operation of the pipe-laying equipment. Such systems 
are generally employed along one side of a trench and, therefore, 
necessitate that the pipe-laying vehicle be counterweighted to maintain 
vehicle stability during the pipe-laying operation. Another type of 
pipe-laying system utilizes a carriage running along abridge which extends 
across the trench. This latter type of pipe-laying system requires the use 
of control and driving means to position and stabilize the running 
carriage and requires a complicated and complex structure and controls for 
the equipment. It is, therefore, an object of this invention to improve 
pipe-laying equipment. 
Another object of this invention is to simplify the structure and controls 
of pipe-laying equipment which is operable along both sides of a trench. 
These and other objects are attained in accordance with the present 
invention wherein there is provided a pair of self-propelled vehicles 
joined by an intermediate bridge having a rigid lifting arm hinged at one 
end to the intermediate bridge and having a device for gripping and 
lifting the pipes carried by the free end of the rigid arm such that the 
rigid lifting arm may be controlled to engage a pipe and lift it over the 
trench and lower the pipe into the desired position.

DESCRIPTION OF THE PREFERRED EMBODIMENT 
Referring now to FIG. 1, there is shown two self-propelled track-type 
vehicles, 4 and 5, commonly referred to as crawler tractors positioned on 
either side of a trench 1 dug in the ground and within which a pipe system 
2 is to be placed. The two self-propelled crawler tractors 4 and 5 are 
positioned on opposite sides of the trench 1 and connected by an 
intermediate connection bridge 3 which is supported at opposite ends by 
each of the crawler tractors 4 and 5. 
The intermediate connection bridge 3 is formed of a fork-shaped structure 6 
(best shown in FIG. 2) comprising side arms 6a and 6b which are supported 
at their free end from the crawler tractor 4 and a central leg 6c which is 
supported at the free end from the crawler tractor 5. Each of the free 
ends of the side arms 6a and 6b are supported for pivotal movement in a 
plane normal to the working surface or support plane of the crawler 
tractor 4 by a cross-brace structure 7. The free ends of the side arm 6a 
and 6b are pivotally hinged onto a cross arm 7a of the cross-brace 
structure 7, and this structure is pivotally connected to a pivotally 
supported arm 6b carried in a support structure 8 (best seen in FIGS. 2 
and 3) with its longitudinal axis normal to the longitudinal or pivot axis 
of the arm 7a. The support structure 8 is pivotally hinged onto a 
framework 9 rigidly secured to the self-propelled crawler tractor 4 to 
allow the support structure 8 to pivot about an axis perpendicular to the 
support plane of the crawler tractor itself. 
At the other end of the fork-shaped structure 6 of the free end of the 
central leg 6b is constructed in the form of a cylinder. The free end may, 
therefore, slide axially or laterally of the self-propelled supporting 
crawler tractor 5, as well as be rotated relative thereto through a 
tubular support body 10 which supports the free end of the central leg 6c 
on the crawler tractor 5. The tubular support body 10 is pivotally hinged 
about a pin 11 which extends in an axis normal to the longitudinal axis of 
the central leg 6c to allow pivotal movement of the fork-shaped structure 
6 in a plane normal to the tractor support surface. The pivot pin 11 is 
supported in a clevis-like structure 12 which is rotatably mounted on a 
support framework 13 rigidly connected to the self-propelled crawler 
tractor 5 to allow the clevis-like structure 12 to pivot about an axis 12a 
perpendicular to the support plane of the crawler tractor 5. 
The intermediate connection bridge extending between the two self-propelled 
crawler tractors 4 and 5 is, therefore, supported by two ball joints at 
its end to compensate for variations in the terrain forming the support 
surface for the tractors. To effect pivoting of the bridge about the 
longitudinal axis of the fork-shaped structure 6 the cross-brace structure 
7 has a projection 37 extending downwardly from the arm 7a. The free end 
of the projection 37 is hingedly connected to actuating rods 38a of two 
opposed hydraulic actuators 38. By operating the hydraulic actuators 38 it 
is therefore possible to rotate the cross-braced structure 7 about the 
axis of the arm 7b to effect rotation of the intermediate connection 
bridge 3 about its longitudinal axis as best seen in FIG. 3. The two 
self-propelled tractors can, therefore, move independently relative to 
each other over variable terrain within the limits determined by the 
dimensions of the structure of the intermediate connecting bridge and by 
the constructional characteristics in the type of coupling which supports 
the two ends of the connecting bridge on the self-propelled crawler 
tractors 4 and 5. However, the two ball joint connections formed between 
the connecting bridge 3 and the two self-propelled crawler tractors 4 and 
5 allow the apparatus to be utilized on varying grades about all axes of 
the crawler tractor. 
The mechanism for raising the positioning of pipe 2 in the trench 1, is 
best described with reference to FIG. 1. A support framework 14 is formed 
by two V-section structures 15 and 16. The V-section structure 15 is fixed 
in relation to the free ends of its two diverging arms 17, onto the side 
arm 6b of th fork-shaped structure 6. Similarly, the V-section structure 
16 is fixed to the side arm 6a of the fork-shaped structure 6 in a 
position parallel to the V-section structure 15. An interconnecting 
articulation pin 18 connects the two V-section structures 15 and 16 at the 
point of convergence of the diverging arms 17. 
A rigid lifting arm 19 is fixed onto the articulation hinge formed by 
interconnecting pin 18 and positioned between the two parallel side arms 
6a and 6b of the fork-shaped structure. The rigid lifting arm 19 is hinged 
onto the interconnecting pin 18 at the free end of its two diverging arms 
19a and 19b as best seen in FIGS. 1 and 3. At the converging ends of the 
rigid arm 19, shown by reference numeral 20, there is supported a group of 
pulleys 21 about which a cable 22 passes and is wound through transmission 
pulleys 23 onto a winch 29. Operation of the winch 29 and pulley systems 
23 and 21 varies the position of the rigid lifting arm 19 about the 
interconnecting articulation pin 18. A second group of pulleys 24 is 
supported from the end 20 of the lifting arm 19 and about which passes a 
cable 25 from which is suspended another group of pulleys 26 carrying a 
connecting hook 27. 
During pipe-laying operation a pipe 2 is connected to the hook 27 and by 
operation of a winch 28, supported from one of the diverging arms 17 of 
the V-section structure 15 and to which the cable 25 is connected, the 
pipe is raised and lowered. The rigid arm 19 is disposed in an almost 
vertical position as shown in FIG. 1 when the pipe 2 is connected to the 
hook 27 and when the winch 28 is operated, lifting the pipe vertically. 
The winch 29 is operated rotating the rigid lifting arm 19 about the 
interconnecting articulation pin 18 until the pipe is in the position 
indicated by the dotted line in FIG. 1 above the bottom of the trench 1. 
The winch 28 is then again operated lowering the pipe 2 to rest on the 
bottom of the trench itself. The pipe is then disconnected and the winches 
28 and 29 are again actuated to raise the hook and the rigid lifting arm 
structure while the two-self-propelled vehicles 4 and 5 are moved into a 
position to engage another section of pipe. 
While the invention has been described with reference to a preferred 
embodiment, it will be understood by those skilled in the art that various 
changes may be made and equivalents may be substituted for elements 
thereof without departing from the scope of the invention. In addition, 
many modifications may be made to adapt a particular situation or material 
to the teachings of the invention without departing from the essential 
scope thereof. Therefore, it is intended that the invention not be limited 
to the particular embodiment disclosed as the best mode contemplated for 
carrying out this invention but that the invention will include all 
embodiments falling within the scope of the appended claims.