Abstract:
An improved device for the measuring of weight or force is disclosed. This is an apparatus that allows for measurement of weight or force using a cantilever beam that is substantially insensitive to location of the weight or force within certain limits on the beam and is capable of correction for off-level conditions.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The invention relates generally to the field of weighing, and specifically to measurement of force or weight in situations where the location of the force or weight is not known and/or cannot be controlled. This is especially relevant to weigh-in-motion or mobile applications such as fork trucks and refuse collection vehicles where the location of the center of the load is unknown and the ground or floor may not be level. In this application, the load is contained in some large bin or atop a pallet, and is acquired by the vehicle via a “fork” comprised of a cantilever beam that is inserted into receptacles in the bin or under the pallet. 
     2. Description of Related Art 
     Devices for measuring weight or force are common in everyday life and commerce. Often these devices function by measuring the mechanical strain in a small area of the device with an attached resistor commonly referred to as a “strain gauge” which changes resistance with strain or by balancing against an accurately known reference weight on a lever device. In these devices the location of the weight must be controlled or the effect of the weight on the loading platform must be controlled mechanically. In some devices, where position of the weight cannot be precisely controlled or known, such as scales for use in refuse truck front forks, the designers have opted to use a shear force measuring load cell or to place strain gauges in a location and in geometric features optimized to measure shear force near the root of the cantilever beam which comprises the lifting fork. Theoretically, the shear stresses anywhere in the lifting fork between the proximal end of the beam (the end where the beam is attached to the vehicle) and the load are a function of the applied load and geometry and are independent of the exact location of the loading of the beam. This means is described in patent (Ruge U.S. Pat. No. 2,597,751). In practice this has been difficult and resulted in cantilever beam scales which contain mechanical complications, produce inaccurate results, and are fragile. Further, replacement of the strain gauges or retrofit of a gauged system to a non-weighing one requires removal of the fork. Further, the “shear” type load sensors cannot compensate for off-level loading condition by themselves. The shear sensing beams must also include weakening features such as cutouts (described in Ruge and shown here as typically practiced) due to the fact that the shear forces, while constant over some length of the beam, are small compared to the bending forces. The bending forces in the cantilever beam are generally greater, but vary relative to the position of the weight or load and thus in prior art, cannot be used to measure a weight in devices that cannot control or determine location of the load. What is needed therefore is a means to resolve a weight or force without knowing or controlling it&#39;s location in the bin, on the pallet or knowing or controlling the angle of the approach (off-level condition of the ground) using a mechanically simple and robust, easily serviced and retro-fittable device. This device should use the greater bending forces present in the lifting fork instead of the shear forces. 
     SUMMARY OF THE INVENTION 
     In light of problems associated with the current art, it is an object of the present invention to provide a mechanically robust, accurate, and inexpensive means to weigh or measure force by detection of bending stresses without regard to location of the load to be measured, and to provide correction for real world difficulties such as off-level weighing. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The objects and features of the present invention, which are believed to be novel, are set forth with particularity to the appended claims. The present invention, both as to it&#39;s organization and manner of operation, together with further objects and advantages, may be best understood by reference to the following description, taken in connection with the accompanying drawings, of which: 
         FIG. 1  is a view of prior art. 
         FIG. 2  is a view of a preferred embodiment of the present invention. 
         FIG. 3  shows a non-limiting example of a non-straight beam. The present invention need not be limited only to a straight beam. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     The following description is provided to enable any person skilled in the art to make and use the invention and sets forth the best modes contemplated by the inventor of carrying out his invention. Various modifications, however will remain readily apparent to those skilled in the art, since generic principles of the present invention have been defined herein specifically to provide an Improved Cantilever Beam Scale. 
     “Sensor” is not limited to a strain gauge; by non-limiting illustration, “sensor” can be a Wheatstone bridge, a strain gauge, a resistor, or any combination thereof. 
     Present art, depicted in  FIG. 1  shows a beam affixed to a load cell. The load cell of  FIG. 1  is designed to change shape as a load “W” is applied to the cantilever beam lifting fork. Due to geometry, the load cell of  FIG. 1  by design increasingly changes shape with increasing load from a nominal rectangle into a nominal parallelogram. Because of this, it is intended by design to react to a shear force and thus be affected as little as possible by the location of the load “W” along the length of the beam. Strain gauges can be applied in the high strain areas of the load cell to measure this local strain. This local strain can then be used to calculate the load much as described by Ruge (U.S. Pat. No. 2,597,751). This is the current state of the art as practiced. 
     The present invention can be best understood by consideration of  FIG. 2 . 
     Shown in  FIG. 2  is a cantilever beam, fashioned to use bending forces to resolve a weight or load independent of the location of the load, and easily compensated for off-level condition. To describe function, we will first examine the well-known means of analysis of stress in a cantilever beam. 
     The well known formula for stress in a cantilever beam is given as “MC/I” where “M” is a moment (twisting force) resulting from the amount of load applied and it&#39;s “lever arm” or distance from the attachment point of the beam. In our  FIG. 2 , “M” becomes “WD 1 , so our stress equation becomes WD 1 C/I where “W” is some weight to be measured, “I” is the moment of inertia of the beam and C is the distance from the “neutral axis” (a well known concept from Engineering) where there is no compressive or tensile stresses from bending. Obviously, these compressive or tensile stresses are greatest at the top and bottom surfaces of the beam shown, as well as being greatest close to the attachment point of the beam shown here as the cross hatched area to the right of the beam. This would be at or near to where the beam is attached to the vehicle or mobile platform. In the case shown here, “I” is well known to be (b h^3)/12 for a beam with rectangular cross section as depicted in  FIG. 1  and  FIG. 2  though it is not intended to limit the device to such rectangular cross sections nor to consistent cross sections as shown here out of simplicity. Note that this beam of  FIG. 2  has devices  1 ,  2 ,  3 ,  4  applied to measure local strain of the material. This is a well established practice and involves the use of elements whose properties, usually electrical resistance, change in a predictable manner with strain of the underlying material. These can be applied directly to the beam with an adhesive, mechanical fastener, or the strain gauges might be incorporated into a unit which is pressed into a hole or welded to the structure. These devices can for higher performance, economy, and simplicity be complete implant-able or attachable Wheatstone Bridges so that any correction of the flex element and strain gauge properties may be done on the small implanted element in a volume production manner such as described by Jacobson U.S. Pat. No. 4,530,245, avoiding the in-situ correction described by Cheruby. 
     The stress at any location in the beam is determined by the load, given in  FIG. 2  as “W” and geometry. The tensile stress that would be given by a strain gauge or other sensing device would be (W Dn C)/(I) where: 
     Dn is the distance along the beam from the load to the point of local strain measurement. In  FIG. 2  Dn is denoted as D 1  to elements “ 2 ” and “ 4 ” and D 1 -D 4  to elements “ 1 ” and “ 3 ” in the simplified case shown where “ 1 ” and “ 3 ” are co-axial and “ 2 ” and “ 4 ” are coaxial, ie “D 3 ”=“D 4 ”. 
     C is the distance from the neutral axis of the beam to the point of measurement as shown in  FIG. 2 . 
     W is the applied force or weight 
     I is the moment of inertia of the beam, in this case, (b h^3)/12 as described earlier. 
     Obviously, to obtain the highest sensitivity, these gauges, (or complete insertable Wheatstone Bridge devices) would be located as near to the attachment point of the beam, and as near to the upper and lower surfaces as practical. 
     From this, it can be shown that each individual strain measuring device will have an output that varies predictably with both W and Dn. The gauge  2  will have an output in tension higher than gauge  1  (i.e.: D 1 &gt;D 1 −D 3 ). The gauge  4  will have an output in compression higher than gauge  3  (i.e.: D 1 &gt;D 1 −D 4 ). Further, if the beam is level, the output of “1” will be of equal magnitude but opposite in sign (compressive vs. tensile) to “3”, and the same for “2” versus “4” for the case where these devices are co-axial as described above. If D 4  and D 3  are known, it will be possible to resolve an unknown weight at an unknown location on the beam. Further, it will also be possible to correct for off-level condition by using the difference in magnitude of the upper (“1” and “2”) versus lower (“3” and “4”) sensors. For situations where the beam is pointing upwards such as picking up a load from an uphill approach, the output of the bottom sensors (in compression) will exceed the output of the upper sensors (in tension). The opposite situation would apply for a downhill approach. This “disagreement” can be used by the solution algorithm to correct for and even to determine slope. 
     Resolution of the weight will start with the realization that local strain measured at 1, 2, 3, and 4 will vary linearly with D 1 . An increase in D 1  results in higher output of any of these sensors. For the purposes of this explanation, we will imagine individual strain sensing elements  1 ,  2 ,  3 , and  4  at positions  1 ,  2 ,  3 , and  4  respectively. These can be applied directly to the beam at these locations or may be of a self contained type of local strain sensor with strain gauges arranged in Wheatstone Bridge configuration across an internal membrane. These sensors are in common use typified by products such as the “Gozinta” manufactured by SI Technologies of Tustin, Calif. and as described in Jacobson U.S. Pat. No. 4,530,245 that can be pressed into the holes shown at these locations. In fact, the location of the load on the beam can be determined by knowing the ratio of the outputs of 1:2 and D 4  and/or 3:4 and D 5 . Given this, it can be shown that with a beam material that follows Hooke&#39;s Law: (strain sensed by gauge  1 )/(strain sensed by gauge  2 )=(D 1 −D 3 )/D 1 . Accurately knowing D 4  allows us to substitute D 3  in the expression with its equivalent (D 1 −D 3 ) for the shown case where “2” and “4” are coaxial and “1” and “3” are coaxial. 
     Note that it is correct to express the output of sensor “1”, in units of local stress, as:
 
Stress @ 1 =M 1 *C/I=W *( D 1 −D 3)* C/I  
 
     And the output of sensor “ 2 ” as:
 
Stress @ 2 =M 2 *C/I=W *( D 1) C/I =( W *( D 1 −D 3)+ W ( D 3))* C/I  
 
     Where Mn is the moment resulting from the application of load (n in this case being 1 or 2 for M 1  or M 2 ) W and C and I are as described earlier. 
     For simplicity, the output of the sensors can be said to be calibrated to read in units equal to the local stress in the beam at the location of the sensor. This is not strictly necessary, but if done for this example, it serves the purposes of illustration. 
     Note here that D 3 , C, and I are all knowns from the geometry of the cantilever beam. Further, from examination of the expressions for Stress @ 1 and Stress @ 2, it follows that Stress @2=Stress @ 1+(W*D 3 ) C/I. Now all items in the equation are known except W, which can be solved by algebra: W=((Stress @ 2−Stress @ 1)I)/(D 3 *C) 
     Here we can define a constant “K” as D 4 (Cy/I). 
     The weight applied to the beam can then be described as:
 
 F=K (local stress at gauge2)((local stress at gauge1−local stress at gauge 2)/(local stress at gauge2)).
 
     Symmetry will obviously apply to the lower gauges as well though the stresses will be opposite, ie in compression. Further mathematical formulation can be employed to compensate for such real world situations such as bending or curving of the beam and off-level loading.