Load balancing lifting apparatus

Apparatus for balancing and lifting a load supported from opposite ends of a cable or chain and which includes a sheave engageable by the cable or chain and through which extends a pin member. The pin member is radially offset from the center of the sheave and is supported, at opposite ends thereof, by structural members which may be attached to a source of lifting power.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention pertains to rigging and lifting equipment. More 
specifically, the present invention pertains to apparatus for balancing 
and lifting a load supported from opposite ends of a cable or chain. 
2. Description of the Prior Art 
Rigging and lifting equipment are frequently used to lift pumps, motors, 
vessels, small buildings and other equipment in loading, unloading or 
transferring such items to a new location. In doing so, a lifting sling is 
typically fabricated including at least one cable or chain from opposite 
ends of which the load is supported. The hook from a crane or other 
lifting equipment would be attached to some midportion of the sling for 
lifting of the load. 
The are two major problems in rigging and lifting equipment in this manner: 
1) the location of the center of gravity of the load is typically not 
known and 2) the center of gravity of the load is not symmetrically 
located relative to the pick up points of the sling. Even when the weight 
and location of gravity of the load are known, the lifting slings 
typically require fabrication to different lengths. Thus, the slings may 
only be used for one lift, making them relatively expensive. 
Another serious problem is safety. Chains with "come-alongs" are typically 
used in rigging and lifting to make length adjustments necessary for 
balancing loads. Come-alongs wear out and may become dangerous. 
Come-alongs also require field adjustments, while a load is suspended, 
exposing personnel to possible injury. 
Thus, the rigging and lifting equipment of the prior art leaves much to be 
desired in effectively and safely balancing and lifting heavy loads. 
Obviously, improvements are needed. 
SUMMARY OF THE PRESENT INVENTION 
In the present invention, apparatus is disclosed for automatically 
balancing and lifting a load supported from opposite ends of a cable or 
chain. The apparatus of the present invention automatically adjusts for 
center of gravity of the load without having to provide slings of 
different lengths. 
The apparatus of the present invention includes a sheave engageable by the 
cable or chain by which the load is being lifted. A pin member extends 
through the sheave and is supported at opposite ends thereof by structural 
members which may be attached to a source of power for lifting the load. 
The pin member is unique in that its central axis is offset from the 
center of the sheave. It is this arrangement which permits balancing and 
equalizing of the load at the opposite ends of the cable or chain. 
The apparatus of the present invention automatically balances the load 
being supported from opposite ends of a cable or chain without requiring 
fabrication of different length slings and without requiring personnel to 
make adjustments while the load is being supported. Thus, the lift is made 
much more efficiently and in much greater safety. Many other objects and 
advantages of the invention will be apparent from reading the description 
which follows in conjunction with the accompanying drawings.

DESCRIPTION OF A PREFERRED EMBODIMENTS 
Referring first to FIGS. 1 and 2 there is shown apparatus A of the present 
invention for balancing and lifting loads from opposite ends of cables and 
chains. The apparatus A comprises a sheave 1 which may be engageable by a 
cable or chain 2. The terms "cable or chain" as used herein are intended 
to include any type of long, slender, strong member to the ends of which a 
heavy load may be attached for lifting. This includes wire rope, hemp 
rope, and any rope, chain or cable of sufficient strength. 
The center of the sheave is indicated at 3. Typically, the sheave 1 would 
include outer circular plates or flanges 4 and 5 separated by a hub 6 
forming one or more cable receiving grooves 6a. The groove 6a would be at 
least wide enough to accept one cable and in some embodiments wide enough 
to receive a cable once wrapped around the sheave 1. 
A pin member 7 extends through the sheave for support at opposite ends 
thereof by structural members 10 and 11. It will be noted that the center 
8 and central axis a--a of the pin member 7 is offset from the center 3 
and central axis b--b of the sheave 1. The fit between the pin member 7 
and sheave 1 may be loose enough so that the sheave 1 may rotate on the 
pin 7. In other embodiments, the pin 7 and sheave 1 might be fixed 
together with the mounting of the pin 7 in holes provided in structural 
members 10 and 11 being loose enough to allow rotation of pin 7 relative 
to the structural members 10 and 11. 
The structural members 10 and 11 may be connected transversely by a 
structural member 12, the straps 10 and 11 and the connecting structural 
member 12 then forming the block for the sheave 1. The connecting 
structural member 12 may be provided with a hole 13 for engagement by 
hooks or other lifting members as will be understood hereafter. 
Referring now also to FIG. 3, the apparatus A of the present invention is 
shown in use for lifting a heavy load L such as a skid mounted engine and 
pump. For purposes of illustration, the center of gravity of the load L is 
assumed to be at the point 20. The apparatus A of the present invention is 
shown suspended from the hook 21, block 22, cable 23 of a crane arm 24. 
The crane to which the crane arm 24 is attached simply provides the power 
for lifting the load L. The cable 2 is shown engaged with the sheave 1 and 
the ends of the cable 2 are passed around the ends of a spreader bar or 
member 25 and then attached to opposite ends of the load L. As the crane 
arm 24 is lifted or the cable 23 shortened, the weight of the load L is 
eventually supported by the crane arm 24. As the load begins to be assumed 
by the apparatus A, the sheave 1 rotates about its pin 7 and the cable 2 
shifts on the sheave 1 until the forces are equalized about a center line 
which corresponds with the center of gravity 20 of the load L, balancing 
the load L as it is lifted off the ground. 
FIG. 4 is a force diagram which illustrates the force vectors and moments 
in the lift of a load L by the apparatus A of the present invention. For 
purposes of illustration it will be assumed that the load L is 20,000 
pounds, the distance between lifting points a and b is 20 feet and the 
center of gravity for the load L (designated as point d) is 14 feet to the 
right of point a and 6 feet to the left of point b. Tension in the cable 2 
will be referred to as T.sub.1 and T.sub.2. The horizontal (x) and 
vertical (y) force vectors of T.sub.1 and T.sub.2 will be referred to as 
T.sub.1x, T.sub.1y, and T.sub.2x, T.sub.2y, respectively. 
For the load L to be in equilibrium, the sum of the vertical components 
T.sub.1y and T.sub.2y must equal 20,000 pounds. The sum of the horizontal 
components T.sub.1x and T.sub.2x must equal 0 and the summation of moments 
about any point must be 0; i.e.: 
##EQU1## 
The magnitude of horizontal components T.sub.1x and T.sub.2x (which equal 
each other) depends on angles of the cable or sling at points a and b. The 
sling angles also depend on total length of the sling. For purposes of 
calculation, points a, b and c (the point of equilibrium where T.sub.1 and 
T.sub.2 meet above sheave 1) will form a triangle abc. One angle 
.THETA..sub.1 will be assumed from which the other angle .THETA..sub.2 
will be determined. Assuming angle .THETA..sub.1 to be 45.degree., both 
legs ad and cd of the triangle adc are equal; i.e.: 
EQU ad=cd=14 ft. 
Then ac can be determined by the formula: 
##EQU2## 
The other angle .THETA..sub.2 can be found. 
##EQU3## 
To find tension T.sub.1 and T.sub.2 : 
##EQU4## 
These calculations have made no mention of the apparatus A because the 
equilibrium equations must be met whether the apparatus A is used or not. 
The apparatus A does not change the equilibrium equations, it complies 
with them. The vector force diagram in the equilibrium, assuming the 
angles .THETA..sub.1 =45.degree. and .THETA..sub.2 =66.8.degree., would 
have a lifting force at apparatus A of 20,000 pounds. T.sub.1 would equal 
8,485.7 pounds and T.sub.2 would equal 15,230 pounds. Obviously, if a 
rolling or center mounted sheave were used, equilibrium would not be 
maintained because T.sub.2 would overcome T.sub.1 and the load would 
rotate with the rolling sheave. The vector force diagram is duplicated 
when the offset lifting block (10,11,12) automatically rotates so that all 
the forces act at a point and there is no tendency to rotate. The lifting 
block counters the tendency of (T.sub.2 -T.sub.1) to make the sheave 
rotate. 
FIG. 5 shows the sheave portion of the force diagram of FIG. 4 on a greater 
scale. It also illustrates that the pin 7 is offset from the center 3 of 
sheave 1 by a distance r which is less than the radius R of sheave 1. 
However, it must be pointed out that the sheave could be designed so that 
the pin 7 would be offset from the center 3 of the sheave 1 by a distance 
greater than the radius of the portion of the sheave engaged by the cable. 
For example, the cable receiving groove (such as 6A in FIG. 2) might lie 
on a smaller circle, such as circle 1A as in FIG. 5. 
Since T.sub.1 and T.sub.2 are usually not equal, one of the factors to 
consider in using the apparatus A of the present invention is friction, 
slippage and control of the cable or cables 2 in contact with the sheave 
1. The diagrams of FIGS. 6 and 7 will illustrate this point. If the cable 
2 is not wrapped around sheave 1, the cable 2 will frictionally engage the 
sheave 1 only through an angle which equals .THETA..sub.1 +.THETA..sub.2 
and is less than 180.degree.. If the cable is wrapped once around the 
sheave, the angle of engagement will be increased by 360.degree. 
(.THETA..sub.1 +.THETA..sub.2 +360 .degree.). This will provide 
substantially more friction to prevent slippage. However, the additional 
wrap may be somewhat cumbersome in making adjustments with the crane from 
which the apparatus A is supported. 
For there to be no slippage, T.sub.2 &lt;T.sub.1 e.sup..mu..beta. where: e is 
2.718 . . . , the base for natural logarithms; .mu. is the coefficient of 
friction between the cable and sheave (assume 0.2 for steel on steel); and 
.beta. is the angle, in radians, through which the cable engages the 
sheave. In the example of FIG. 7, without wrap and assuming .THETA..sub.1 
=45.degree., .THETA..sub.2 =66.8.degree., .pi. radians=180.degree., 
T.sub.1 =8,485.7 # and T.sub.2 =15,230.0 #: 
EQU T.sub.1 e.sup..mu..beta. =T.sub.1 e.sup.0.2(111.8.degree.) =T.sub.1 
e.sup.0.2(0.621.pi.) =T.sub.1 e.sup.0.39 =1.48T.sub.1 =12,558.4 # 
This is less than T.sub.2, causing possible slippage. 
In the example of FIG. 7, with a wrap: 
EQU T.sub.1 e.sup..mu..beta. =T.sub.1 e.sup.0.2(471.8.degree.) =T.sub.1 
e.sup.(0.2(2.621.pi.) =T.sub.1 e.sup.1.65 =5.21T.sub.1 44,210.5 # 
This is much greater than T.sub.2 (no slippage but more cumbersome). 
FIGS. 8 and 9 illustrate an arrangement which will provide greater friction 
than the arrangement of FIGS. 6 and 7 with no wrap but less friction and 
more control (less cumbersome) than with a full wrap. In the arrangement 
of FIGS. 8 and 9 the opposite ends of cable or cables 2 cross each other 
and are connected to the lifted load at lifting points opposite the 
lifting points illustrated in FIGS. 6 and 7 or as in FIGS. 3 and 4. The 
dashed line representation of the cable 2A in FIG. 3 also illustrates the 
crossed arrangement of FIGS. 8 and 9. 
In the crossed arrangement of FIGS. 8 and 9, .beta., the angle of cable 
contact with sheave 1, is equal to 360.degree.-(.THETA..sub.1 
+.THETA..sub.2). This is more than 180.degree. but not as great as a full 
wrap (360.degree.+.THETA..sub.1 +.THETA..sub.2). However, it is enough to 
prevent slipping and should be less cumbersome or easier to adjust and 
control. For example: 
EQU T.sub.1 e.sup..mu..beta. =T.sub.1 e.sup.0.2(248.2.degree.) =T.sub.1 
e.sup.0.2(1.379.pi.) =T.sub.1 e.sup.0.87 =2.39T.sub.1 =20,280.8 # 
In this arrangement the apparatus A is not altered in design. It is still 
balanced about the offset pin 7 of the sheave 1. However, the pin 7 will 
be above the point of equilibrium c rather than below it as in the 
arrangement of FIGS. 7 and 8. 
Referring now to FIG. 10, there is shown another load L.sub.1 being lifted 
by the crane arm 24 and crane block 22 attached to apparatus A such as the 
apparatus described with reference to FIGS. 1 and 2. The load L.sub.1 has 
a longitudinal axis X--X and a transverse axis Z--Z. The center of sheave 
1 of the apparatus A lies on an axis parallel with the axis of Z--Z. In 
this embodiment additional support assemblies similar to apparatus A are 
utilized. They will be referred to as first support assembly B and a 
second support assembly C. Each of the first and second support assemblies 
B, C includes a sheave, similar to the sheave 1 of apparatus A through 
which is inserted a pin member, such as the pin member 7 in apparatus A. 
The central axis of each pin is offset from the center of its 
corresponding sheave. Each of the sheaves of the assemblies B and C is 
engageable with center portions of second and third cables 30 and 31, 
which partially support, from the opposite ends thereof and transversely 
to the cable 2, the load L.sub.1. Thus, the axes of the pins supporting 
the sheaves of support assembles B and C are parallel with the X--X axis 
of the load L.sub.1. With this arrangement, the load L.sub.1 may be 
balanced about its center of gravity in two planes, along two axes X--X 
and Z--Z. 
As previously mentioned, the sheave 1 of the apparatus A of any of the 
embodiments of this invention described with reference to FIGS. 1-10 could 
be designed to receive one, two or more cables or chains. This allows an 
increase in the ratio D/d where: 
D=sheave diameter 
d=diameter of the cables or chains. 
The increased ratio of D/d reduces stress on the cables and the engagement 
surface of the sheave and helps prevent rotation about the vertical axis. 
Of course, the more cables or chains used, the less tension per cable or 
chain. 
The apparatus of the present invention automatically balances a load being 
lifted or supported from opposite ends of a cable or chain. No special 
slings need to be designed. No field adjustments need to be made, 
eliminating the subjection of personnel to dangerous situations. The 
apparatus is relatively simple and is certainly less expensive and safer 
to operate than methods of the prior art. 
Several preferred embodiments of the invention have been described herein. 
Several applications or methods of using the invention are described 
herein. However, many variations of the invention and its uses may be made 
by those skilled in the art without departing from the spirit of the 
invention. Accordingly, it is intended that the scope of the invention be 
limited only by the claims which follow.