Beam fabricating device

An I-beam fabrication device that positions and aligns two distinct T-shaped beam portions together in a predetermined longitudinally curved configuration and automatically welds the beam portions into a single integral prestressed I-beam capable of increased load capacity.

BACKGROUND OF THE INVENTION 
1. Technical Field 
I-beams of this type are used in the construction of trailers wherein a 
greater load capacity is desired. The I-beam has a longitudinally curved 
configuration to offset a given amount of deflection under load due to 
their great length. 
2. Description of the Prior Art 
Prior art construction of one-piece aluminum I-beams of the size and length 
required was technically difficult due to the present limitations of 
aluminum extrusion technology. A method of curved I-beam manufacture is 
disclosed in applicant's own presently pending patent application, Ser. 
No. 06/591,930 filed Mar. 21, 1984 disclosing the basic method of 
fabrication but not the apparatus. 
SUMMARY OF THE INVENTION 
An I-beam fabrication device that positions and aligns two distinct beam 
portions together in a predetermined longitudinally curved configuration 
and automatically welds the beam portions into a single integral 
prestressed I-beam capable of increased load capacity.

DESCRIPTION OF THE PREFERRED EMBODIMENT 
An I-beam fabrication device can be seen in FIGS. 1-5 of the drawings 
comprising a pair of vertically spaced and aligned support I-beams 10 and 
11 with said support I-beams 10 and 11 extending between and secured to 
end supports 12 and 13. The support I-beam 11 is secured to a foundation F 
via a foundation support 14 and has an end portion 15 of reduced height as 
best seen in FIG. 3 of the drawings. 
A plurality of tubular brackets 16 are secured to one side of said support 
I-beams 10 and 11 respectively in longitudinally spaced relation to one 
another and in oppositely disposed relation on said I-beams. Each of said 
tubular brackets 16 is comprised of a first tube portion 17 secured to its 
respective I-beam and a second tube portion 18 extending from said first 
portion 17. 
Referring to FIG. 3 of the drawings, it will be seen that the tubular 
brackets 16 do not extend from the end portion 15 of the support I-beam 
11. Guide rails 19 and 20 are secured to the free ends of the tubular 
brackets 16 extending from the support I-beams 10 and 11 respectively. The 
guide rails 19 and 20 are aligned with one another in spaced vertical 
relation. 
A series of alignment pins 21 are slidably positioned between said support 
I-beams 10 and 11. Each alignment pin 21 extends from a guide cylinder 22 
secured to a mounting plate 23 extending from and secured to said support 
I-beam 10 and said guide rail 19. A piston rod 24 of a hydraulic piston 
and cylinder assembly 25 drives the alignment pin 21 into and out of 
engagement with a socket 26 secured to the guide rail 20 as best seen in 
FIGS. 4 and 5 of the drawings. It will be seen that the alignment pins 21 
provide critical vertical alignment of the guide rails 19 and 20 during 
the beam fabrication, as will be described. 
Referring now to FIGS. 1, 2 and 6 of the drawings, a plurality of 
longitudinally spaced arm assemblies 27 are positioned along the other 
side of said support I-beams 10 and 11 in aligned oppositely disposed 
relation with said tubular brackets 16. Each of said arm assemblies 27 is 
comprised of a pair of spaced L-shaped pivot plates 28 secured to and 
extending outwardly from said support I-beams. A holding arm 29 is 
pivotally secured between the pivot plates 28 and extends outwardly 
therefrom. A journaled fitting 30 is secured to the free end of the 
holding arm 29 with a T-shaped rod 31 extending therefrom. A control lever 
32 is pivotally secured between the holding arm 29 inwardly from its 
pivoted end and a piston rod coupler 33 on the end of a piston rod and 
cylinder assembly 34. A pair of secondary control levers 35 are pivotally 
secured to said pivot plates at 35A and the piston rod coupler 33. 
In operation with the holding arm 29 in vertical position as shown in FIG. 
1 of the drawings, the piston and cylinder assembly 34 is connected to a 
pressurized fluid source via supply lines L as is well understood in the 
art. The piston rod of the piston and cylinder assembly 34 would retract 
pulling the control levers 32 and 35, raising the holding arm 29 in an 
arcuate path as shown in FIG. 2 of the drawings, and in broken lines in 
FIG. 1 of the drawings. The holding arms 29 opposite the support I-beam 11 
extend downwardly from their respective assemblies while the holding arms 
29 opposite the support I-beam 10 extend upwardly from their assemblies. A 
work piece support platform is positioned on the upper surface of the 
support I-beam 10 and is comprised of an elongated U-shaped channel member 
36 that is spaced in vertical relation to said support I-beam 10 by a 
plurality of flat rectangular legs 37 as best seen in FIGS. 1, 4 and 6 of 
the drawings. The legs 37 vary in height with the ones nearer the end 
support 13 decreasing in height. A number of inverted U-shaped channel 
members 38 are positioned in end to end relation over the elongated 
U-shaped channel member 36 with the inverted channel member 38 having a 
greater cross sectional interior dimension than that of the outside cross 
sectional diameter of said U-shaped channel member 36. The overlapping 
channel members 36 and 38 define an area therebetween in which a high 
pressure flexible hose 39 is positioned along the entire length of said 
channel member 36. A pressure plate 40 extends over the channel members 
the length thereof and defines a continuous unbroken surface for the 
placement of an inverted T-shaped beam portion 41 best seen in FIGS. 1 and 
10 of the drawings. 
The inverted T-shaped beam portion 41 is held in aligned position against 
the guide rails 20 by the T-shaped rods 31 extending from the holding arms 
29 and by oppositely disposed stop pins 42A and 42B secured to the holding 
arms facing the beam portion 41 and to the second tube portion 18. The 
stop pins 42A and 42B are adjustable to adapt to a variety of beam portion 
widths. 
A work piece forming plate 43 is suspended from the lower surface of the 
support I-beam 10 by a multiple spacer and plate assembly having a 
plurality of spacers 44 positioned between plates 45 with the plate 43 
engaging a secondary T-shaped beam portion 46 positioned in aligned 
relationship with said inverted T-shaped beam portion 41. The secondary 
T-shaped beam portion 46 is held in alignment by its respective holding 
arms 29 and stop pins 47A and 47B identical in configuration and mountings 
of stop pins 42A and 42B as hereinbefore described. 
Referring to FIG. 3 of the drawings, a convex curve is defined by the 
plates 43 and 45 by the gradually increasing of the vertical height of 
spacers 44 along the midportion of the plate 43. The end portion 15 of the 
support I-beam 11 has a movable upper guide 48 having a curved 
configuration. Pairs of piston and cylinder assemblies 49 are pivotally 
secured between the movable upper guide 48 and the end portion 15 adjacent 
either end thereof and on either side of said end portion. The piston and 
cylinder assemblies 49 are arranged to elevate the upper guide 48 into a 
position indicated by broken lines at 48A bending an end portion 50 of the 
beam portion 41 seen in FIGS. 10 and 11 of the drawings upwardly against a 
depending web portion 51 of the secondary T-shaped beam portion 46. 
Referring now to FIGS. 3 and 7-9 of the drawings, a welding carriage 
assembly 52 can be seen movably positioned along the support I-beam 10. 
The welding carriage assembly comprises a tubular support frame having 
pairs of oppositely disposed vertical tubular members 53 and 54, 
interconnecting tubular members 53A and 54A between their upper ends. 
Pairs of oppositely disposed, vertically spaced, horizontally extending 
tubular members 55 and 56 extend between said vertical tubular members 53 
and 54 respectively defining an inverted generally U-shaped carriage 
configuration that is supported on a carriage guide assembly 57 by a guide 
wheel assembly 58, best seen in FIG. 9 of the drawings. The welding 
carriage 52 has a pair of oppositely disposed welding guns 59, each of 
which is secured to the vertical tubular members 53 adjacent their free 
ends. 
The carriage guide assembly 57 is comprised of a track support channel 60 
on top of the support I-beam 10. A plurality of longitudinally spaced, 
vertically adjustable track support bolts 61 secure and vertically space a 
track member 62 that extends the length of the support I-beam 10. The 
track support bolts 61 are adjusted to curve the track member 62 to 
correspond to the desired curve of the beam to be fabricated. The guide 
wheel assembly 58 is comprised of multiple wheel sets, each of which has a 
main support bracket 63 with a pair of vertically spaced axle wheel and 
bearing assemblies 64 positioned thereon engaging either side of the track 
62. A secondary axle wheel and bearing assembly 65 is positioned 
horizontally within an opening in the support bracket 63 and is aligned to 
engage an edge 66 of the track 60 as best seen in FIG. 9 of the drawings. 
A rack 67 is centered transversely on the upper surface of said track 62 
extending the full length thereof. A right angular gear motor assembly 68 
is secured to the welding carriage assembly and engages the rack 67 as 
will be well understood by those skilled in the art moving the same along 
the carriage guide assembly at a predetermined rate. 
Referring now to FIG. 7 of the drawings, welding carriage controls 69 and a 
welding gun controller 70 can be seen that when activated moves the 
welding carriage assembly 52 along the length of the track 62 advancing 
the welding guns 59 which are positioned to align at the junction of the 
T-shaped beam portions 41 and 46 as best seen in FIG. 1 of the drawings. 
In operation, the holding arms 29 are opened as shown in broken lines in 
FIG. 1 of the drawings. The T-shaped beam portions 41 and 46 are prepared 
as shown in FIG. 10 of the drawings with the beam portion 46 being punched 
at 71 and cutaway at 72. The beam portion 41 is inverted with a large 
section of its web cutaway at 73. The beam portion 46 is loaded into the 
device first and the holding arms 29 opposite said support I-beam 10 are 
closed holding the beam portion 46 against the guide rail 19 and stops 47A 
and 47B. The other beam portion 41 is placed into the device resting on 
the pressure plate 40 and the holding arms 29 opposite said support I-beam 
11 are closed. The high pressure hose 39 is connected to a compressed air 
source and pressurized. The expanding hose 39 forces the multiple U-shaped 
channel members 38 and the pressure plate 40 upwardly against the base of 
the beam portion 41 moving the same for engagement with the beam portion 
46 bending both beam portions to the convex curve defined by the plates 43 
and 45. 
The movable upper guide 48 of the support I-beam 11 portion 15 is moved 
upwardly by the hydraulic piston and cylinder assemblies 49 as shown in 
broken lines in FIG. 3 of the drawings at 48A against the end portion 50 
of the beam portion 41 bending the same against the beam portion 46. 
The welding carriage assembly 52 is activated with the welding guns 59 
tracking along the seam between the abutting beam portions 41 and 46 
welding the same simultaneously. As the welding carriage assembly 52 moves 
along the guide track 62 from adjacent the end support 13 to the end 
support 12. The alignment pins 21 are retracted individually as the 
welding carriage approaches each one. Once the welding guns 59 pass the 
pin position, the pins 21 are re-engaged. The welding carriage 52 is then 
moved back to the beginning of the portion 50, the weld guns are 
repositioned to weld the seam between the end portion 50 and a web cutaway 
at 73. The end portion 50 opposite the cutaway at 72 of the beam portion 
46 is bent upwardly and is welded in place forming a complete beam 74 seen 
in FIG. 11 of the drawings. 
It will be apparent from the above description that the completed beam 74 
is then removed from the device by depressurization of the hose 39 and 
opening of the holding arms 29 in the reverse order of engagement as 
hereinbefore described. 
The completed beam 74 having been fabricated in a prestressed curved 
configuration is capable of increased load performance when used in a 
trailer construction which requires a relatively long beam span. By 
prestressing the completed beam 74 in a curved configuration the greater 
deflection characteristics of aluminum I-beams compared to steel beams of 
a like size is overcome and increased trailer performance is obtained with 
durability and weight savings advantage of aluminum construction. 
Thus it will be seen that a new and useful beam fabrication device has been 
illustrated and described and it will be apparent to those skilled in the 
art that various changes and modifications may be made therein without 
departing from the spirit of the invention and having thus described my 
invention,