Apparatus for lifting walls to a vertical position

A device for use in raising a wall, includes a footing member, an upright member, having a first end and a second end, a pulley, a flexible cable, the flexible cable having a first end and a second end, a cable guide member, a cable guide offset member, the cable guide offset member having a first end and a second end, and a wall engaging member. The upright member first end is fixed to the footing member and extends in a substantially vertical direction from said footing member. The footing sits on a floor or other generally horizontal surface. The cable guide member is secured to the cable guide offset member first end, and the cable guide offset member second end is fixed to said upright member second end. The flexible cable has its first end secured to the pulley, and its second end secured to the wall engaging member, and is supported between its two ends by the cable guide member.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The invention relates to a portable device to move large items, such as 
pre-built walls, into, or out of, the vertical position. 
2. Brief Description of the Prior Art 
The construction of buildings with prefabricated wall sections is a common 
practice. The process of standing a stud wall begins with the construction 
of the stud wall on a horizontal surface such as a floor or a slab 
foundation. The stud wall includes top and bottom plates and a plurality 
of structural members, or studs, joining the top and bottom plates Such 
prefabricated wall sections, which may vary in length, generally are 
placed horizontally on the floor of the building structure. The edge that 
will ultimately become the lower edge of the horizontal wall section, is 
placed immediately adjacent the floor location on which it will rest in 
its vertical, upright position. The wall section is lifted and tilted into 
its desired vertical position, and the section is then secured to the 
sub-floor. Standing a stud wall typically requires a minimum of three 
workers to accomplish the task safely and easily. The stud wall is urged 
into a vertical position and held in place by two workers as a third 
worker secures the stud wall to other building structures. 
The process works efficiently when the necessary manpower is present. 
However, with the trend toward do-it-yourself home building as well as the 
use of skeleton crews by commercial builders, the requisite minimum of 
three workers to stand a stud wall is not always available. When only two 
workers, such as a husband and wife building their own home, attempt to 
raise a stud wall the potential for serious injury is ever present. 
Many devices such as mobile cranes, have been provided for use in lifting 
loads, including prefabricated walls. Mobile cranes are quite expensive 
and due to their weight and cumbersome nature, they are usually moved to a 
job site by the use of a trailer type vehicle. It has also been suggested 
to provide lifting devices, such as wall jacks, to raise the prefabricated 
wall sections from horizontal to final vertical position. Patents have 
issued disclosing a wall jack construction comprising a mechanical hoist 
having an elongated boom, the lower end of which is pivotally attached by 
a hinge to the floor of the building construction. Attached to a lower end 
portion of the boom is a winch with cable. The cable passes about a sheave 
on the upper end of the boom, and the outer end of the cable is suitable 
connected to the prefabricated wall adjacent its eventual upper end. The 
winch is manually operated to pivotally raise the wall section to a 
vertical position as the boom pivots from vertical to a generally 45 
decree angular position during the lifting operation. 
U.S. Pat. No. 5,322,404 provides a lifting device for raising prefabricated 
wall sections of a building from a horizontal to a vertical upright 
position during building construction. 
U.S. Pat. No. 5,634,301 discloses a stud wall raising apparatus that 
permits a single user to raise a stud wall without assistance. The device 
has a T-shaped wall fixture, a fixed stud brace attached to the wall 
fixture by hinge means, a movable stud brace and a plurality of lock bars 
connecting the fixed and movable stud braces. 
A need has been recognized in the art for a stud wall raising apparatus 
that allows a single individual to raise a stud wall so that the stud wall 
can be properly positioned and attached to other building structures. Such 
an apparatus must be simple to use, such that it can be operated by 
construction workers and lay persons alike. Furthermore, the device should 
be inexpensive to manufacture and durable when used in a commercial 
setting. 
SUMMARY OF THE INVENTION 
A lift to enable a wall, or other item, to be lifted to, or from, a 
vertical position is disclosed. The lift comprises a vertical body portion 
and horizontal lift arm and support legs. In one embodiment the 
freestanding unit is heavily supported through the use of braces and 
supports to allow the lifting unit to lift and support the wall without 
buckling or tipping. In other embodiments the unit is secured to a sub 
floor. 
In its preferred embodiment, the wall lift device includes a footing 
member, an upright member, having a first end and a second end, a pulley, 
a flexible cable, the flexible cable having a first end and a second end, 
a cable guide member, a cable guide offset member, the cable guide offset 
member having a first end and a second end, and a wall engaging member. 
The upright member first end is fixed to the footing member and extends in 
a substantially vertical direction from said footing member. The footing 
sits on a floor or other generally horizontal surface. The cable guide 
member is secured to the cable guide offset member first end, and the 
cable guide offset member second end is fixed to said upright member 
second end. 
The flexible cable has its first end secured to the pulley, and its second 
end secured to the wall-engaging member, and is supported between its two 
ends by the cable guide member. The wall engaging member is preferably a 
"J" shaped hook. 
The pulley and/or cable guide member can be designed to provide a 
mechanical advantage in lifting a wall. Such designs are well known in the 
art. 
The relative dimensions of the upright member, the pulley offset member and 
the wall provide for a rotation of the wall through at least a 60 degree 
angle, and preferably through at least a 75 degree angle. 
The upright member is at least about six feet long and can be eight feet 
long, for use with ten foot walls. 
A reinforcing brace can be provided. The brace can have a first end fixed 
to the cable guide offset member, proximate the cable guide offset member 
first end, and a second end fixed to the upright member, at a position 
spaced from the upright member second end by a distance at least one third 
of the length of the upright member. Advantageously, it can be secured at 
a distance of least one half of the length of the upright member. 
The method of raising a pre-constructed wall member, comprising the steps 
of: 
a--constructing a wall member, having a first peripheral edge and a second 
peripheral edge in a position opposing the first edge. Most typically, the 
two opposing peripheral edges are parallel. 
b--positioning the wall lift member on a base, as for example, a horizontal 
floor, 
c--attaching the wall engaging member to the first peripheral edge of the 
wall member, then 
d--pivoting the wall about the second peripheral edge of the wall member, 
and 
e--rotating the wall to the vertical position. 
The pivoting of the wall about the second peripheral edge of the wall 
member is accomplished by winding the flexible cable about the pulley and 
raising the wall engaging member and the wall through an arc about the 
second peripheral edge of the wall.

DETAILED DESCRIPTION OF THE INVENTION 
The disclosed wall lift provides an easy to move lift for conveniently 
lifting framed walls and the like into a vertical position. Although most 
commonly used for framed walls, the disclosed walled lift can be used to 
lift or lower any heavy item to or from a vertical position. 
The preferred embodiment of the wall lift 10 of FIG. 1 has a vertical body 
12 which has a height generally determined by the weight and height of the 
wall and the maximum lift required. Thus, if 12 foot walls were being 
raised, the body 12 would require a greater height that if the walls were 
8 foot. Approximately one third the way from the top of the body 12 a 
pulley 16 is securely attached. Although the pulley 16 illustrated is 
manually operated, a powered pulley can be used that is either attached to 
the body or separate unit. The term pulley, as employed herein, is used as 
generic term to mean any device which can either pull or wind a rope or 
flexible cable. The terms rope and cable are employed herein, essentially 
interchangeably to indicate any flexible device which can be drawn by a 
pulley, winch or similar device, and guided by a guide wheel, roller or 
similar device. 
The pulley 16 has a handle 18 and standard locking means (not shown) to 
prevent the rope 20 from releasing and dropping the wall. A wall hook 26, 
designed to hook and maintain the grip on the wall during the lifting 
process, is affixed to the end of the rope 20. The means for locking, 
releasing and allowing the pulley to be turned in one direction is well 
known in the art. At the distal end of the body 12 a support arm 14 is 
secured to the body at right angles. The support arm 14 has a length 
approximately one third that of the length of the body 12 in order to 
provide the proper leverage and allow the wall to be moved along the arc 
90. At the unattached end of the pulley arm 14 a pulley wheel 22 is 
affixed to receive and guide the rope 20. It is also preferable that a 
second wheel 23 be used proximate the connection of the support arm 14 and 
the body 12 to evenly guide the rope 20. A top angle brace 24 prevents the 
support arm 14 from flexing in response to the weight of the item being 
lifted. The top angle brace 24 is attached to the arm 14 proximate the 
distal end and to the body 12, at a point about two thirds the distance 
below the body 12/arm 14 connection, to form an acute triangle. A 
secondary brace 32 connects the brace 24 to the body 12, forming a second 
triangle, to further reinforce the top portion of the lift 10. 
At the proximal end of the body 12 is the base unit, indicated generally as 
38. The base of the lift 10, in the preferred free standing embodiment, 
comprises a support leg 40 which extends at right angles to the body 12. 
To add further strength, the connection between the support leg 40 and the 
body 12 is reinforced through use of connecting frame 54. Preferably the 
connecting frame 54 has an inner diameter slightly greater than that of 
the body 12 in order to receive the body 12. The connecting frame 54 and 
body 12 are positioned inward from the one end of the support leg 40 to 
allow for reinforcement of the connection between the connecting frame 54 
and support leg 40 through use of a rear leg brace 48. A pair of side legs 
56 and 58 extend at right angles to the support leg 40 and are connected 
at one end to the connecting frame 54 proximate the juncture between the 
connecting frame 54 and the support leg 40. The opposite ends of the side 
legs 56 and 58 are again connected to the connecting frame 54 through use 
of support angles 50 and 52. As can be seen from FIG. 3, the side legs, 
body and support angle form a right triangle. To provide further support 
to the structure, side supports 42 and 44 extend from the side legs 56 and 
58, proximate the juncture between the side legs 56 and 58 and the support 
angles 50 and 52. The side supports 42 and 44 are affixed to the support 
leg 40, thereby forming a pair of right triangles. As can be seen in these 
figures, a number of angles are created through the supports and legs to 
provide stability and strength. 
As the wall is lifted, pressure is applied to the pulley arm 14 at 
approximately the same angle as the top angle brace 24. It is thus 
preferred that the placement of the top angle brace 24 in respect to the 
support brace 28 be such that its position corresponds to the direction of 
force on the pulley arm 14. Thus, the force on the pulley arm is supported 
by the top angle brace 24 that extends between the pulley arm 14 and the 
body 12. The support brace 32 is preferably secured to the body 12 at a 
point higher than the top angle brace 24 to further prevent the body 12 
from bending at a point just below the connection between the top angle 
brace 24 and the body 12. The braces can be connected to the body at other 
locations, however, the stability of the lift must be maintained. Any 
position, as would be evident to those versed in the art in view of this 
disclosure, which maintains the integrity of the lift can be used. 
In the preferred embodiment the material used is aluminum tubing having 
cross sectional peripheries ranged from 1.times.1 to 2.times.2. The 
specifications set forth in Table I are provided for example only and are 
not intended to limit the scope of the invention. 
TABLE I 
______________________________________ 
periphery 
length 
______________________________________ 
vertical body 12 1.5 .times. 1.5 .times. 1/8 
78.0 
support arm 14 1.5 .times. 1.5 .times. 1/8 
35.0 
top angle brace 24 
1 .times. 1 .times. 1/8 
59.69 
secondary brace 32 
1 .times. 1 .times. 1/8 
24.44 
support leg 40 2 .times. 1 .times. 1/8 
45.0 
rear leg brace 48 1 .times. 1 .times. 1/8 
15.0 
side legs 56 and 58 
1 .times. 1 .times. 1/8 
9.0 
support angles 50 and 52 
1 .times. 1 .times. 1/8 
15.0 
side supports 42 and 44 
1 .times. 1 .times. 1/8 
26.81 
connecting frame 54 
2 .times. 2 .times. 1/8 
18.00 
______________________________________ 
An alternate embodiment is illustrated in FIG. 4 wherein in lift 100 the 
leg brace 130 and body 112 are manufactured from L-shaped steel with holes 
along the length. As the lift 100 is free standing, the holes allow the 
leg brace 130 to be secured the lift 100 to the sub-floor through use of 
screws or bolts. The support brace 128 serves to reinforce the leg brace 
130 to the body 112 to prevent buckling. The top angle brace 124 and 
secondary brace 132 provide additional support and structural strength. 
The arm 114, support brace 128, top angle brace 124, and secondary brace 
132 are manufactured from piping having a diameter and thickness 
sufficient to provide the necessary strength and support. The piping is 
welded to the L-shaped steel to maintain maximum stability. Alternatively, 
the entire lift 240 can be manufactured from the L-shaped steel as 
illustrated in part in FIG. 5, illustrating leg brace 242, body 244 and 
arm 246. Other materials that provide for the same rigidity and stability 
as those disclosed herein can be substituted and will be obvious to those 
skilled in the art. 
FIG. 6 illustrates a front view of an alternate wall lift 250 wherein a 
pair of legs 262 and 264, separated by support 266, extend parallel to, 
and on the same plane, as the overhead arm 268. The use of the pair of 
legs 262 and 264 provides the advantage that the lift 250 would be self 
supporting and, if the lifted load is sufficiently light, would not 
require securing to the sub-floor. 
FIG. 7 illustrates an additional embodiment of the invention wherein lift 
280 has a single leg 284 at right angles to the body 282. The use of a 
single leg 284 would require the lift 280 to be secured, as stated 
heretofore, to the sub-floor of the structure. 
FIGS. 8 through 12 illustrate the lifting process of the wall 290 using 
lift 280. As can be seen in FIG. 8, in the initial position, the wall 290 
is placed on the base 284 and the hook 292 placed over the top of the wall 
290. The pulley handle 294 is turned to raise the wall 290 to the maximum 
height achievable by the lift 280, as illustrated in FIG. 11. Once the 
pulley handle 294 is locked in position, the user can simply raise the 
wall into position. At this height level a relatively light weight wall 
can easily be lifted by a single person to a vertical position along the 
arc path illustrated in FIG. 12. 
FIGS. 13 and 14 illustrate the arc of an eight foot wall 290 in relation to 
a five (5) foot lift 300 versus an eight (8) foot lift 320. As can be seen 
in these figure, the point along the arc to which the lift 300 can take 
the wall 290 is further from vertical than the point obtained with lift 
320. The determination of the lift height required is based on weight of 
the wall and number of people available to lift the wall to the vertical 
position. Therefore a large 400 pound wall would required either a larger 
number of people or a taller lift than a 200 pound wall. 
The critical dimensions of the disclosed invention lie with the height of 
the wall, height of the body and length of the arm. The length of the arm 
must be sufficient to swing the wall out as close to vertical as possible. 
It should be noted that as the wall approaches the vertical, the force 
necessary to rotate the wall fully to the vertical decreases. The force 
necessary to raise the wall decreases directly with the decreasing of the 
horizontal distance between a vertical line through the center of gravity 
of the wall and the pivot point. That is, the lifting force required to 
pivot the wall through the first ten degrees of rotation is dramatically 
greater than the force required to pivot the wall through the last ten 
degrees of rotation. Accordingly, it is not critical that the device be 
sufficiently tall to raise the wall to the full vertical position. 
Depending upon the weight and height of the wall, a point is reached at 
which the remaining moving can easily be accomplish by one person. 
Preferably, the proportions of the device relative to the wall should 
provide for at least a 45 degree rotation, and preferably, at least a 60 
degree rotation of the wall. Relative proportions which provide for a 
rotation of the wall to at least a 75 degree angle is most preferred. At 
the 75 degree angle, one person can readily rotate a large wall to the 
full vertical position. 
Since other modifications and changes varied to fit particular operating 
requirements and environments will be apparent to those skilled in the 
art, the invention is not considered limited to the example chosen for the 
purposes of disclosure, and covers all changes and modifications which do 
not constitute departures from the true spirit and scope of this 
invention.