Hydraulic boom for gantry or the like

Abstract

An improved method of lifting a load includes supporting a load on a first section of an extendible lift assembly, the first section being surrounded by a second section, a hydraulic cylinder being operatively coupled to the first section so as to be capable of lifting the first section, and the first and second sections being supported on and vertically extendible with respect to a base. Then, while the load is supported on the first section, the hydraulic cylinder is extended to extend the first section relative to the second section and the base, thereby lifting the load to a first height. Then, the first section is secured to the second section so as to at least substantially prevent downward movement of the first section relative to the second section. The cylinder is then retracted and operatively coupled to the second section. Then, while the load is supported on the first section, the hydraulic cylinder is extended to extend the first and second sections relative to the base, thereby lifting the load to a second height which is higher than the first height. This procedure results in lifting the load through a range which is greater than a maximum range of extension of the hydraulic cylinder. The lift assembly also includes a locking device which, in the event of hydraulic pressure loss in the hydraulic cylinder, automatically mechanically engages one of the first and second sections to prevent unintended lowering of the load.

Description

BACKGROUND OF THE INVENTION

This invention relates generally to an apparatus and method for lifting objects and, more particularly, to an apparatus and method for lifting heavy objects with an extendable boom gantry.

Various systems and methods for lifting heavy objects have been developed over thousands of years. Traditional gantries are well known in the prior art for their usefulness for lifting heavy objects. However, a satisfactory system for vertically extending the gantry boom has eluded those skilled in the gantry art. In particular, a number of design concerns must be addressed in developing a satisfactory gantry.

One prior art design utilizing jacks that can be in the form of telescopic lifting rams is disclosed by German Patent No. 2439667. While this structure allows vertical extension, structural limitations of traditional hydraulic cylinders may allow this structure to lift a heavy load to a point where the structure can no longer support the load. This is at least partly attributable to the fact that traditional hydraulic cylinders are designed to be strong in tension and compression, but fail at relatively low bending stress. Accordingly, a relatively simple structure for vertically extending the boom on a gantry while providing sufficient strength to withstand bending stress is needed.

To achieve substantial vertical lift heights, multi-stage hydraulic cylinders can be used. However, multi-stage hydraulic cylinders are expensive and heavy and the expense and weight increases with the overall extended length of the cylinder. Accordingly, it is desirable to provide a method of extending a lifting structure which is capable of extension greater than the extended length of the hydraulic cylinder.

Still another design concern is that it is difficult to precisely coordinate the extension of two hydraulic cylinders. In addition, it is difficult to coordinate two sets of driving wheels. Such lack of coordination can cause structural failure when a rigid gantry structure is attached to said mechanisms. Accordingly, means for allowing slight misalignments while retaining the structural integrity of the gantry structure are critically needed.

Finally, hydraulic systems occasionally fail by losing pressure. In a gantry system, such failure can cause catastrophic results because the load may drop in conventional designs. Accordingly, a safety feature which is independent of the hydraulic system for its holding force while being actuated by the hydraulic system failure is needed.

It is therefore an object of the invention to provide a new and improved method for lifting heavy objects with an extendable boom.

It is another object of the invention to provide a method of operating a vertically extendable gantry capable of extension greater than its lift cylinder extension range.

In accordance with one aspect of the invention, this object is achieved by supporting a load on a first section of an extendible lift assembly, the first section being surrounded by a second section, a hydraulic cylinder being operatively coupled to the first section so as to be capable of lifting the first section, and the first and second sections being supported on and vertically extendible with respect to a base. Then, while the load is supported on the first section, the hydraulic cylinder is extended to extend the first section relative to the second section and the base, thereby lifting the load to a first height. Then, the first section is secured to the second section so as to at least substantially prevent downward movement of the first section relative to the second section. The cylinder is then retracted and operatively coupled to the second section. Then, while the load is supported on the first section, the hydraulic cylinder is extended to extend the first and second sections relative to the base, thereby lifting the load to a second height which is higher than the first height. This procedure permits a load to be lifted through a range which is greater than a maximum range of extension of the hydraulic cylinder.

BRIEF DESCRIPTION OF THE DRAWINGS

The features of the present invention, which are believed to be novel, are set forth with particularity in the appended claims. The invention, together with the further objects and advantages thereof, may best be understood by reference to the following description taken in conjunction with the accompanying drawings, wherein like-referenced numerals identify like elements, and wherein:

FIG. 1 is a front elevational view of a gantry constructed in accordance with one aspect of the present invention in its fully lowered configuration, having cross-sectional details of the extendable portion of the boom assembly shown;

FIG. 2 is a front elevational view of the boom assembly in a fully extended innermost section configuration with the cylinder fully extended and a lock collar in place;

FIG. 2A is a front elevation view of a multi-stage hydraulic cylinder incorporated in the gantry;

FIG. 3 is a front elevational view of the boom assembly in its fully extended innermost section configuration with the cylinder retracted and an alternative embodiment of the lock collar in place;

FIG. 4 is a front elevational view of the boom assembly with its innermost section fully extended and the immediately adjacent intermediate section partially extended;

FIG. 5 is a front elevational view of the boom assembly in its fully lowered configuration having cutouts showing the boom assembly nesting structure and a driving means;

FIG. 6 is a side elevational view of the boom assembly in its fully lowered position, showing the cam-locking mechanism engaging the first stage and in its disengaged configuration (dotted outline);

FIG. 7 is a front elevational view of the cam;

FIG. 8 is a front elevational view of an alternative embodiment of the boom assembly with the boom pins and cylinder pin in place;

FIG. 9 is a front elevational view of the boom assembly in its fully retracted position with the boom and cylinder pins removed;

FIG. 10 is a front elevational view of an alternative embodiment of the boom assembly with the innermost section extended before pin insertion;

FIG. 11 is a front elevational view of the boom assembly with the innermost section pinned in place by the boom pins and hydraulic cylinder partially retracted;

FIG. 12 is a front elevational view of the boom assembly with the innermost section fully extended and locked in place with the boom and cylinder pins;

FIG. 13 is a front elevational view of the boom assembly with the innermost section pinned in place and a hydraulic cylinder lifting the first stage section and the innermost section therewith;

FIG. 14 is a cross-sectional view of a header plate in a neutral position;

FIG. 15 is a cross-sectional view of a header plate in a fully tilted position;

FIG. 16 is an expanded cross-sectional view of the header plate in a neutral position;

FIG. 17 is a cross-sectional front view of a powered rigging device;

FIG. 18 is a cross-sectional side view of the powered rigging device of FIG. 17 ; and

FIG. 19 is a cross-sectional top view of the powered rigging device of FIG. 17 .

DESCRIPTION OF PREFERRED EMBODIMENTS

Referring to the drawings, a hydraulic boom gantry 10 constructed in accordance with one aspect of the invention is shown in FIGS. 1-6 .

As illustrated, the hydraulic boom gantry 10 includes two sets of wheels 12 with one base 14 mounted on each set of wheels 12 . Lifting legs 16 are attached to each of the bases 14 . A beam 18 is connected to the top of the lifting legs 16 . Various rigging devices 20 may be mounted on the beam 18 , which, in turn, is supported by the lifting legs 16 and the bases 14 . The rigging devices 20 can include conventional chains, cables or the like that can be used to connect the load L ( FIG. 2 ) to the beam 18 or can include the powered rigging device 20 disclosed in FIGS. 17-19 .

The bases 14 and lifting legs 16 are kept in substantially parallel alignment with one another by the beam 18 and a header plate structure 22 . Preferably, a swiveling header plate 22 is used to connect the beam 18 to an innermost section 24 . As shown in FIGS. 1-6 and 14 - 16 , the swiveling header plate 22 comprises a hemispherical bearing 26 . The bearing 26 is mounted so as to allow relatively small differences in height between the lifting legs 16 and relatively small misalignments of the bases 14 . Larger misalignments are limited by the clearances around the bearing 26 . As a larger deviation starts to occur, it is limited by binding contact between the upper bearing structure 28 and the outer bearing cup exterior 30 . The clearance between the upper bearing structure 28 and the outer bearing cup exterior 30 can be varied with plates, shims or the like to vary the amount of unchecked deviation.

As shown in FIGS. 14-16 , the hemispherical bearing 26 comprises components located in and between the top of the innermost section 24 and the header plate 22 . The innermost section 24 includes an outer bearing cup 30 which is pressed into place in a pocket 32 . The outer bearing cup 30 includes an inner bearing cone 34 therein. After the header plate 22 , the upper bearing structure 28 , the hemispherical bearing 26 , and the inner bearing cone 34 are positioned in the outer bearing cup 30 of the innermost section 24 , a connecting bolt assembly 35 is used to retain the header plate structure 22 in an operating configuration. A spacer 40 is placed over the threaded hole 38 of the outer bearing cup 30 . Next, a washer 36 is placed over the spacer 40 and a bolt 42 is inserted into the threaded hole 38 and tightened securely. Finally, a cover plate 44 is bolted into place over the top of the bolt 42 head. In this way, the lifting legs 16 are securely fastened to the beam 18 while still allowing minor misalignments to occur without causing structural failure.

Extension of the lifting legs 16 permits lifting of the load by the beam 18 and rigging devices 20 as desired. Referring again to FIGS. 1-6 , the lifting legs 16 also include telescoping outer and intermediate sections 46 and 50 preferably made of square structural tubing. Though it will be readily preferably apparent to one skilled in the art that various materials may be used for the hydraulic boom gantry 10 components, steel is preferably used in the preferred embodiment described herein. Though the number of telescoping boom sections 46 , 50 and 24 used in a particular hydraulic boom gantry 10 can be varied, a hydraulic boom gantry 10 having three telescoping boom sections 46 , 50 and 24 is shown in the Figures and will be referred to for illustrative purposes.

Although various pressurized cylinder means can be used equivalently, a hydraulic cylinder 48 is described for nonlimiting, illustrative purposes. A conventional multiple telescoping stage hydraulic cylinder 48 (FIG. 2 A), mounted in an inverse orientation, is preferably disposed within the interior of the telescoping boom sections as shown in FIG. 14 . The inverse orientation of the cylinder 48 places the input and output ports of the cylinder 48 at a stationary position at the bottom of the lifting legs 16 . Thus, complex hydraulic hose reels are not required to provide additional hydraulic hose length when the cylinder 48 extends and to take up excess hose length as the cylinder 48 retracts.

This inverse orientation of the cylinder 48 also provides greater and more consistent bending moment resistance throughout the boom structure 10 by placing the largest and strongest part of the cylinder, i.e., the cylinder end or barrel portion 52 , in the weakest and smallest boom sections (the innermost section 24 and the immediately adjacent intermediate section 50 ) Also, any air which enters the hydraulic cylinder 48 rises to the top of the barrel portion 52 (in its inverse orientation) where it may be easily purged from the cylinder 48 . As the cylinder 48 is extended under pressure from a conventional hydraulic pump, the telescoping sections can be extended from a fully retracted position.

A preferred embodiment of the invention, which includes inner section 24 , the immediately adjacent intermediate section 50 , and an additional section 46 , is described for nonlimiting, illustrative purposes. If extension of the innermost section 24 is desired from the fully-retracted position as shown in FIG. 1 , the lock pins 58 , which lock the innermost section 24 in position with the adjacent intermediate section 50 in the cylinder pinning block 60 , are removed. The hydraulic cylinder 48 may need to be extended or retracted slightly to relieve binding pressure on the lock pins 58 . Once the lock pins 58 are removed from the cylinder pinning block 60 , the hydraulic cylinder 48 can be extended. As the hydraulic cylinder 48 extends, it presses against the top inner surface of the innermost section 24 and coordinately extends the innermost section 24 coupling C ( FIG. 2A ) as shown in FIG. 2 .

If additional hydraulic boom gantry 10 height is desired, the innermost section 24 is locked in place with the lock collar 62 . The lock collar 62 , best see in FIG. 3 , can consist of two rectangular steel blocks 64 which are inserted between the shear plates 66 and the top perimeter of the adjacent intermediate section 50 as shown in FIG. 2 . Alternatively, the lock collar 62 can consist of two rectangular blocks 68 having holes at both ends through which retaining bolts 70 can be inserted. The retaining bolts 70 are long enough to extend through both blocks 68 when the blocks 68 are inserted opposite each other under the shear plates 66 as shown in FIG. 3 . Retaining nuts 71 are threaded onto retaining bolts 70 to fasten the blocks 68 in place. It will be obvious to one skilled in the art that the lock collar 62 structure can be modified in many conventional ways.

After installing the lock collar 62 , the innermost section 24 is retracted slightly until the shear plates 66 contact the lock collar 62 . This locks the innermost section 24 in place in its extended position with the lock collar 62 supporting the load L (FIG. 2 ). The hydraulic cylinder 48 can then be retracted within the locked innermost section 24 . When the hydraulic cylinder 48 is fully retracted, both lock pins 58 are inserted into the holes in the adjacent intermediate section 50 , the lower part of the innermost section 24 and the cylinder pinning block 60 . In this way, the adjacent intermediate section 50 and the innermost section 24 extend coordinately with the hydraulic cylinder 48 as it extends. If additional extension is desired, another lock collar 62 is used to lock the adjacent intermediate section 50 in its fully extended position. Thereafter, the additional intermediate section is extended in the same manner as the adjacent intermediate section 50 . This technique can be used for additional sections as well.

Alternatively, each lifting leg 16 may be provided with two boom pins 72 and one cylinder pin 74 as shown in FIG. 8 . The two boom pins 72 are located on either side of the cylinder pin 74 as shown. Though various diameters may be used, the cylinder pin 74 is preferably 1.75 inches in diameter and the boom pins 72 preferably have diameters of 1.5 inches.

Extending the telescoping sections 46 , 50 , and 24 requires the following steps. First, while the sections 46 , 50 , and 24 are fully retracted, the boom pins 72 and the cylinder pin 74 are removed as shown in FIG. 9 . In some instances, the hydraulic cylinder 48 may need to be extended slightly to remove binding pressure from the cylinder pin 74 . Next, the hydraulic cylinder 48 is extended. The innermost section 24 is extended coordinately with the hydraulic cylinder 48 . If extension greater than the height provided by the innermost section 24 is desired, the hydraulic cylinder 48 is fully extended until the pinning holes 76 formed in the upper end of the adjacent section 50 become aligned with the pinning holes 78 formed in the lower end of the innermost section 24 as shown in FIG. 11 . Once the pinning holes 76 , 78 are aligned, the pins 72 are fully inserted in the pinning holes 76 . This locks the innermost section 24 to the adjacent intermediate section 50 . The hydraulic cylinder 48 may then be retracted within the innermost section 24 as shown in FIG. 11 . The hydraulic cylinder 48 is retracted until a pinning hole 80 formed in the cylinder end of the hydraulic cylinder 48 is aligned with the adjacent intermediate section hole 76 and a cylinder pin 74 is inserted as shown in FIG. 12 . Extension of the cylinder 48 now coordinately raises the adjacent intermediate section 50 and the innermost section 24 pinned thereto. Additional sections may be extended in the same manner. Specifically, the adjacent intermediate section can be pinned to an additional intermediate section 50 and the hydraulic cylinder lowered and reconnected to the pinned together sections to raise the combination.

Retraction of the sections is performed as follows: the adjacent intermediate section 50 is retracted with the hydraulic cylinder 48 until the cylinder pin 74 is freed from binding pressure. The cylinder pin 74 is then removed and the hydraulic cylinder 48 is extended until the pins 72 become free from binding pressure. The pins 72 are then removed and the hydraulic cylinder is retracted until both the pin holes 76 and the cylinder hole 80 are aligned with the holes 78 in the innermost section 24 . The innermost section 24 is retracted in the same fashion.

In both preferred embodiments, the pinning configurations provide additional structural strength and safety. Additional structural strength over conventional designs is provided by using the pins to fix the hydraulic cylinder 48 to the sections 46 , 50 , and 24 rather than using a single pin for a pivotal connection. While a pivotal connection does not allow bending stresses applied to the sections 46 , 48 , and 50 to be partly transferred to the hydraulic cylinder 48 , the pinned connections provided by the preferred embodiments effectively transfer such stresses, thereby significantly increasing structural strength. Further, pin removal may not occur until binding pressure is relieved. Therefore, the load will not drop due to inadvertent pin removal.

As shown in FIG. 5 , one or more wheels 12 for each of the bases 14 can be driven by a motor 82 . It will be obvious to one skilled in the art that an alternative drive structure can be used. The motors 82 are preferably controlled by a central control panel 84 .

Another embodiment of the invention uses a powered rigging device 20 . As shown in FIGS. 17-19 , the powered rigging device 20 is propelled by a rigging device motor 98 so that it may traverse the beam 18 while carrying a load. This rigging device motor 98 is preferably operated by the central control panel 84 which controls the powered movement of the bases 14 . The rigging device 20 preferably includes a housing 86 supporting a hook or other rigging fixture 88 which includes a swivel bearing 90 (as shown in FIG. 18 ) so that the load may be rotated easily without fixture entanglement.

A cam-locking mechanism 92 is also provided as an additional safety feature. This mechanism 92 comprises a toothed cam 94 as shown in FIGS. 6 and 7 . The cam-lock mechanism 92 is mounted on a support 96 which allows rotation about the support 96 . The cam-lock mechanism 92 is retained in its disengaged position by hydraulic pressure. If the hydraulic pressure drops to a level where the hydraulic cylinder 48 might begin to retract unexpectedly, the cam-lock mechanism 92 rotates under spring pressure to engage the outer boom section 46 to which it is mounted. This engagement prevents retraction of the lifting legs 16 , thus preventing unexpected lowering of the load.

While a particular embodiment of the invention has been shown and described, it will be obvious to those skilled in the art that changes and modifications may be made without departing from the invention in its broader aspects and, therefore, the aim in the appended claims is to cover all such changes and modifications as fall within the true spirit and scope of the invention.

Claims

1. In a gantry including first and second extendible leg assemblies and a beam extending between and supported on said extendible leg assemblies, each said extendible leg assembly comprising: a base; a plurality of telescoping sections, each having an upper end and a lower end, mounted on said base for vertical extension relative to said base, said plurality including an innermost section, an outermost section and an intermediate section immediately adjacent said innermost section; a hydraulic cylinder having a cylinder end and a rod end, disposed within said telescoping sections with said cylinder end uppermost and said rod end lowermost, said cylinder end having a coupling device being coupleable with and decoupleable from said innermost section, a detachable connection for detachably coupling said cylinder end to said adjacent intermediate section so that said cylinder end can be coupled to either said innermost section or to said adjacent intermediate section; and a selectively engageable connection between said lower end of said innermost section and said upper end of said adjacent intermediate section for detachably fixing said innermost section and said adjacent intermediate section to each other with said innermost section being extended relative to said adjacent intermediate section; said extendible leg assembly thereby being extendible over a range that is greater than the available extension of said cylinder, wherein said detachable connection includes coaxially alignable holes formed in said cylinder end and said intermediate section and further includes a pin insertable through said holes in said cylinder end and said intermediate section when said holes in said cylinder end and said intermediate section are coaxially aligned holes, a method comprising:(A) supporting a first end of said beam on said innermost section of said first extendible lift assembly; (B) supporting a second end of said beam on said innermost section of said second extendible lift assembly; (C) supporting said load on said beam and coupling said hydraulic cylinders to said innermost sections; then (D) while said load is supported on said beam, extending said hydraulic cylinders to extend said innermost section of each of said lift assemblies relative to said intermediate section and said base of each of said lift assemblies, thereby lifting said load to a first height; then (E) while said load is supported on said beam and said innermost section of each of said lift assemblies is extended relative to said intermediate section, detachably securing said innermost section of each of said lift assemblies to said intermediate section of each of said lift assemblies so as to at least substantially prevent downward movement of said innermost section of each of said lift assemblies relative to said intermediate section of each of said lift assemblies, the detachably securing step comprising, for each of said lift assemblies, detachably fixing said lower end of said innermost section to said upper end of said intermediate section using said detachably engageable connection; then (F) while said load is supported on said beam, decoupling said hydraulic cylinders from said innermost sections, retracting said hydraulic cylinders, and detachably connecting said hydraulic cylinder of each of said lift assemblies to said intermediate section of each of said lift assemblies using said detachable connection; and then (G) while said load is supported on said beam, extending said hydraulic cylinders to extend said innermost and intermediate sections of each of said lift assemblies relative to said base of each of said lift assemblies, thereby lifting said load to a second height which is higher than said first height, wherein the steps (D) and (G), in combination, lift said load through a range which is greater than a maximum range of extension of said hydraulic cylinders.

2. A method as recited in claim 1, wherein the hole in each said cylinder end extends completely through said cylinder end and wherein, during the step (F), the pin of each extendible leg assembly is inserted completely through the associated cylinder end.