Continuous automatic weighing conveyor for flowable solids

Flowable solids are continuously and accurately weighed during transport to a collection or discharge point. A counterweight pivoted conveyor carries a rotating disc at its discharge end, one face of which frictionally engages a relatively stationary comparatively small diameter wheel having a plane of rotation at right angles to the plane of the disc. The disc rises and falls with the pivotal conveyor in response to varying amounts of material on the conveyor, thereby changing the effective radius of the disc relative to the wheel. The wheel activates a counter once during each rotation thereof to register a unit of weight in the counter. The structure is useful in agriculture or industry.

BACKGROUND OF THE INVENTION 
Continuous and automatic conveyors are known in the prior art including 
conveyors for flowable aggregates and solids. Generally speaking, the 
prior art weighing conveyors are large industrial installations which 
include sophisticated and costly components, either electrical or 
mechanical in nature. Because of their high cost, the prior art devices 
are not suitable for use by farmers or in small industrial operations 
where the more expensive equipment cannot be justified economically. Some 
examples of the known patented prior art are contained in the following 
U.S. Pat. Nos: 1,032,183; 3,070,214; 1,751,898; 3,339,650; 2,630,312; 
3,478,830; 2,882,036; 3,718,197. 
With the above drawbacks of the prior art in mind, it is the objective of 
this invention to satisfy the need of the art for a wholly practical and 
reliable continuous automatic weighing conveyor for flowable solids which 
is particularly useful to farmers, and also finding utility in light 
industry where the heavier and much more costly equipment cannot be 
utilized. 
A further object is to provide a weighing conveyor which is virtually free 
of the necessity for adjustment once properly set up, and which can have 
its capacity increased merely by increasing the speed of the drive unit so 
as to operate the material conveyor at an increased rate. 
Another object is to provide a continuous weighing conveyor which is not 
sensitive to belt slippage and which can operate in conjunction with 
either an electrical or mechanical counter for handling a wide range of 
dry flowable solids, such as silage, grain, sand, coal or the like. The 
length of the conveyor can be changed to meet the needs of a particular 
application, as will be made clear during the course of the following 
description. 
Other features and advantages of the invention will become apparent in the 
detailed description of this application.

DETAILED DESCRIPTION 
Referring to the drawings in detail wherein like numerals designate like 
parts, the numeral 10 designates a low horizontal base frame which may be 
conveniently constructed from angle bars 11, and preferably provided with 
adjustable support feet 12 for approximate leveling of the machine on 
uneven surface. Near the longitudinal center of the frame, a pair of rigid 
support posts 13 rise from the opposite sides of the frame, FIG. 3, and 
are provided at their tops with bearings 14 within which is journaled a 
transverse horizontal support shaft 15 for a vertically swingable rigid 
frame 16 of the continuous weighing conveyor. The frame 16 comprises 
sturdy side channel members 17 which are equipped somewhat rearwardly of 
their longitudinal centers with bearings 18, rockably mounted on the 
transverse shaft 15 inwardly of the bearings 14. The length of the 
conveyor frame 16 can be varied to suit individual installations and to 
provide the necessary distance between the deposit and delivery points for 
the material which is being conveyed and weighed. In this connection, the 
drawings are illustrative only and should not be taken in a limiting 
sense. 
As shown in FIG. 1, the frame 16 extends some distances fore and aft of the 
pivot shaft 15, and near the rear end of the frame suitable counterweights 
19 are bolted or otherwise rigidly secured to the bottom of the frame. To 
allow fine balancing of the pivoted conveyor, a small adjustable weight 
19' may be provided as illustrated in FIG. 1. Near and above the 
counterweights 19 an electric motor 20 for the conveyor is mounted on a 
suitable platform 21 carried by the frame 16. The armature shaft 22 of the 
motor 20 extends transversely of the frame 16, and near one side of the 
frame carries a drive sheave 23 coupled by a belt 24 to a larger pulley 
25, mounted on one end of a transverse horizontal countershaft 26, 
supported in bearings 27 on the frame members 17. The countershaft 26 at 
one end carries a smaller pulley 28 outwardly of the pulley 25, and the 
pulley 28 is drivingly connected by a belt 29 with another pulley 30 on 
the transverse horizontal shaft 31 of a rear conveyor roll 32. The shaft 
31 is supported by bearings 33 mounted on the frame members 17. 
A conveyor belt 34 for flowable solids engages the rear powered roll 32 and 
also engages a forward end idler roll 35 having its transverse shaft 36 
held in bearing 37 on the frame members 17 at their forward ends. The 
position directly above the pivot shaft 15 of the conveyor is the flowable 
solids deposit or input point of the machine, while the material delivery 
point or discharge point is at the forward conveyor roll 35. The linear 
speed of the belt 34 in the direction of the arrow, FIG. 1, can be changed 
to meet particular needs by simply changing the size of the motor pulley 
23 or by using variable speed pulleys in the drive system. In some cases, 
a variable speed motor rather than a constant speed motor can be employed. 
The capacity of the weighing conveyor is adjusted merely by changing the 
speed of the conveyor belt and without the necessity for any other 
adjustments in the apparatus. 
While a belt conveyor has been shown for simplicity, it should be 
understood that other forms of conveyor elements such as chain and slat or 
flighted endless conveyor elements may be utilized. 
At the forward end of the pivoted frame 16, a comparatively large diameter 
flat vertical disc 38 is bodily mounted on the front roll shaft 36 of the 
conveyor to rotate therewith, the disc 38 being spaced laterally outwardly 
of one frame member 17, as shown in the drawings. A coacting preferably 
rubber-tired wheel 39 of considerably smaller diameter than the disc 38 is 
supported for free rotation on a small vertical support shaft 40 while 
being held in frictional contact with the outer face of the disc 38 in a 
plane at right angles to the plane of the disc. The shaft 40 of the 
friction wheel 39 is mounted on a horizontally swingable support bracket 
41 having a vertical axis hinge connection at 41' to a rigid horizontal 
support arm 41a carried by and extending forwardly of an upright member 42 
rising from one of the base frame bars 11. The upright member 42, FIG. 3, 
is positioned outwardly of the disc 38 and outwardly of the adjacent post 
13. A leaf spring 42' attached to the rigid arm 41a bears against the 
outer side of horizontally swingable bracket 41 and urges the wheel 39 
into firm frictional contact with the disc 38. Other spring arrangements 
for this purpose may be utilized, such as a torsion spring on the hinge 
connection 41' or mounting the wheel 39 directly on a leaf spring member 
which is biased toward the disc 38. 
The wheel 39 carries an upstanding pin 43 near its periphery and in the 
rotational path of movement of this pin is an actuator element 44 of a 
microswitch 45 fixed to a support bracket 45' on the swingable bracket 41. 
Electrically connected with the microswitch 45 in a conventional manner is 
a digital counter 46 which may be mounted at a convenient control center 
on or remote from the machine. In lieu of the electrical counter 46 and 
microswitch 45, a mechanical counter can be placed at the location of the 
switch 45 with its digit actuator in the path of movement of the pin 43 so 
that the counter will be tripped once during each revolution of the wheel 
39. 
The upright 42, FIG. 1, extends well above the top of the conveyor at one 
side thereof and a transverse horizontal beam 47 extending from the top of 
the upright 42 supports a center longitudinal rigid arm 48 to which a 
vertical rectractile spring 49 is attached and extends therebelow. The 
spring 49 has its lower end connected to a cradle or yoke 50 which in turn 
is secured to the pivoted frame 16 of the conveyor somewhat rearwardly of 
the forward end of the frame. The spring 49 is used to control the descent 
of the discharge end of the conveyor by counter-balancing the additional 
weight of any increasing amount of material as it is added to the conveyor 
belt. Other forms of retarder means may be used instead of the spring 
arrangement shown. Preferably, a positive stop member 51 rising from one 
of the base frame members 11 limits the downward swinging movement of the 
rear end of conveyor frame 16. The stop member 51 is not essential to the 
operation of the invention and may be omitted, if preferred. 
The simple mode of operation of the invention is best understood in 
connection with FIGS. 1, 4 and 5. In FIG. 1, there is no material on the 
conveyor belt 34 and the conveyor is in balance on the axis of the pivot 
shaft 15. When this condition prevails, the wheel 39 is at the neutral 
position on the center of the rotating disc 38 and no rotation is imparted 
to the wheel by the disc which is rotating in response to movement of the 
conveyor belt at a given speed under influence of the drive motor 20 and 
associated gearing. As previously noted, the conveyor speed and hence the 
capacity of the machine can be increased or decreased by changing pulley 
size or using variable diameter pulleys. 
Referring to FIG. 4, when dry flowable material 48 is placed on the 
conveyor belt 34 above the pivot 15 and such material is transported 
forwardly by the belt toward the discharge end of the conveyor, the weight 
of this material will overcome the effect of the counterweights 19 and 
begin to tilt the discharge end of the frame 16 downwardly or clockwise 
about the axis of the shaft 15. This action causes the rotating disc 38 to 
descend relative to the wheel 39, FIG. 4, the wheel being at a fixed 
elevation on the standard 42 but held frictionally against the disc at all 
times, as described. As the disc 38 thus descends, it imparts rotation to 
the friction wheel 39 at an ever-increasing rate as a larger and larger 
effective circumference of the disc moves into driving contact with the 
wheel. The ultimate relative positions of the disc and wheel will depend 
on the amount and weight of the material 48 being transported. In any 
case, the induced rotation of the wheel 39 will cause its pin 43 to trip 
the microswitch actuator 44 (or the equivalent actuator of a mechanical 
counter) once during each revolution of the wheel to thereby advance the 
counter 46 one count. The machine is calibrated so that each revolution of 
the wheel 39 represents a unit of weight of the material, such as one 
pound. Therefore, with the belt continuously moving with any given amount 
of material 48 on it, the continuing rotation of the wheel 39 will 
automatically and continuously weigh and register on the counter 46 the 
weight of the material being conveyed to the discharge end of the conveyor 
where such material can be collected in any desired way. 
FIG. 5 illustrates the operation when an increased weight of material 48 is 
placed on the conveyor near the pivot shaft 15 to further tilt the 
discharge end of the frame 16 downwardly, thus further lowering the disc 
38 relative to the wheel 39 so that a larger diameter part of the disc is 
driving the wheel 39. The wheel is now turning at a faster rate and 
consequently in conjunction with the elements 43 and 44 an increased 
weight of material is being continuously and automatically registered on 
the digital counter 46 as the material is transported on the conveyor 
belt. The same mode of operation takes place for all relative positions of 
the disc 38 and wheel 39, and to this extent, the machine is infinitely 
self-adjusting between points of zero rotation of the wheel 39 to maximum 
rotation when the wheel is being driven by the largest diameter portion of 
the disc 38. In this manner, various types of flowable solids can be 
continuously and automatically weighed during transport on the conveyor to 
a point of discharge and collection. The speed and hence the capacity of 
the conveyor can be adjusted in the manner described. 
It should be noted that it is unnecessary to place the material 48 on the 
belt 34 in a smooth uniform layer, as illustrated. When the material is 
irregular or has gaps therein, the conveyor will automatically rebalance 
itself and correct the relative positions of the disc 38 and wheel 39 to 
continuously and accurately weigh the material as it is being conveyed. As 
previously noted, the length of the conveyor forwardly of the pivot shaft 
15 can be varied to meet particular needs. Similarly, the placement of the 
counterweights 19 can be changed from that illustrated in the drawings. 
For example, an overhead suspended pivot bar with counterweights thereon 
may be used, or other equivalent means. 
It is to be understood that the form of the invention herewith shown and 
described is to be taken as a preferred example of the same, and that 
various changes in the shape, size and arrangement of parts may be 
resorted to, without departing from the spirit of the invention or scope 
of the subjoined claims.