Abstract:
A spreader with a material divider that is adjustable from side to side so as to change a percentage of a stream of material which flows through portions of the material divider and also supports and moves laterally with a spinner while the spinner is adjustable longitudinally. The geometry of spread patterns can be adjusted by laterally manipulating the location of the material divider.

Description:
BACKGROUND OF INVENTION 
     Spinner spreaders for granular, i.e. flowable material are well known in the art, for agricultural application, lawn care and road maintenance application. Typically, such spreaders are mounted onto a truck body, truck chassis, trailer, or slid into a truck&#39;s dump body. The spreader includes a material storage bin(s), a conveyor system(s), metering method, and rotating spinners. The conveyor systems transfer material from the storage bin(s) to the spinners. The spinners broadcast the material across the field, lawn, or road. Usually a single spinner or a pair of laterally spaced spinners are provided with a material divider plate positioned above the spinners to direct the material from the discharge end of the conveying means onto the spinners. 
     Many factors influence the spreading of granular materials and uniform distribution of the particles. They include the size, shape, hardness, density, and volumetric flow rate of the material particles. The diameter of the spinner disk or fan, the speed of the spinner disk, the radial angle of the fins, the loft angle, friction factors also among others that influence the spreading of material. As taught in U.S. Pat. No. 6,517,281 to Rissi, many of these factors can be accounted for by adjusting the drop point of material onto the spinning disks. This patent is hereby incorporated herein in its entirety by this reference. 
     Spreader manufacturers are constantly trying to improve the value of their spreaders by increasing the amount of acres spread per hour. The vehicles carrying or towing the spreader are operating at a higher speed to cover more acres per day. More importantly, the manufacturers are developing spreaders capable of uniform symmetrical distribution over a wider swath width. Wider patterns result in less use of expensive fuel, less soil compaction, and less time spent spreading each acre. The result is a significantly higher return on investment for those using this equipment. These types of spreaders are typically broadcast spreaders with two spinner disks. 
     Global positioning systems (GPS) and automatic steering systems are able to guide the vehicles accurately through field and help maintain uniform coverage of materials. However, in order to cover the field area completely, the wider spread patterns of a broadcast spreader make it difficult to avoid overlapping areas or spreading into areas that should be avoided. Likewise, spreading on irregular shaped fields may result in inadequate coverage when the spreading vehicle is approaching areas at an angle that is not perpendicular to areas already covered. The difference in an overlapping area to an area without coverage will show significantly as plants are growing. In most cases, the applicator makes sure that all areas are covered rather than skipping small areas that are inefficient to cover. This results in using more fertilizer and higher costs. 
     To some extent, the width of a symmetrical pattern with regard to the center line of the carrying or towing vehicle can be reduced by simply decreasing the amount of metered material conveyed to the spinner in proportion to the reduced width in combination with reducing the spinner rpm to throw the particles less distance. High throughput spreaders producing wide flat top patterns produce results with some compromise to a uniform spread distribution unless the drop point of material onto the spinner disks can be adjusted as taught in the &#39;281 Rissi patent. European spreaders typically producing a pyramid spread pattern can likewise reduce the material flow and the spinner speed to result in a lesser width. 
     Spreaders producing wide flat top patterns have the most abrupt decline of the spread pattern at the outside edges of the distribution. Because of this abrupt fall off of the pattern, flat top patterns require the least amount of edge overlap to produce a uniform distribution. At the same time, too much overlap of these spreaders quickly produce areas that can double the intended rate per area. Spreaders producing pyramid patterns have a generally declining distribution from the centerline to the outside edges and require an overlap equal to half of the total width. Pyramid pattern spreader overlap errors have a more gradual effect. 
     When spreading the outside perimeter of a field, flat top patterns also have a distinct advantage over the pyramid pattern because of the more abrupt cutoff. To aid spreading around the perimeter of the field, pyramid pattern spreaders usually use a combination of mechanical deflectors, reduced spinner speed, and reduced flow to produce an acceptable reduced width boundary condition at one side of the centerline of the carrying or towing vehicle. 
     Many of the pyramid pattern spreaders utilizing two spinner disks are gravity fed. These spreaders rely on accurate placement of fertilizer on to the spinner disk through an orifice directly above each spinner. The throughput of these spreaders are limited by how fast the material can gravity flow from a funnel shaped bin through the restrictive orifice and on to the spinner. While they can produce a wide pyramid pattern and the flow can be adjusted easily, the orifice limits the speed of the carrying or towing vehicle and overall throughput. 
     Many of the flat top pattern spinner spreaders rely on accurate placement of fertilizer across a larger radial portion of the fins on the spinner disk. As in the &#39;281 patent, this accurate placement is accomplished by positioning the spinners under a fixed drop edge. Material conveyed from a bin can fall onto the guiding drop edge without being restricted by a gravity fed orifice at the bottom of a bin. These spreaders can produce a wide flat top pattern with the conveying system capable of high flow rates and high overall throughput. 
     The twin spinner gravity fed spreaders have an advantage of varying the flow rate to each spinner by adjusting individual orifices. If an asymmetrical pattern is desired for a field boundary condition, an angled headland, an irregular field profile, or a narrowed swath, the orifice is reduced and the spinner speed is lowered to maintain the distribution rate for the narrower side of the spread pattern. To accomplish the same in a twin spinner conveyor fed spreader, some manufacturers have tried to position a split gate upstream from the conveyor end. Another way of reducing the flow to one spinner is to provide twin conveyors capable of varying the amount of flow to each spinner. Doing so requires independent control of each conveyor. 
     It is common for present day spinner spreaders to have multiple product bins with conveying or metering systems for each bin. This allows the user to spread multiple fertilizer or seeding products in one pass down the field while constantly varying the outputs to match the needs or capabilities of the soil, thus producing the highest yield for the least amount of input costs and gives the farmer a higher return on investment. 
     As taught in the U.S. Pat. No. 6,817,551 to Williams et al, having the conveyors of each bin meter directly into a common material gravity flow column allows multiple products to be mixed without any other delay in transport. For common thinking, combining multiple bins of a conveyor fed twin spinner spreader with the need to meter the product independently to each spinner would require a split conveyor for each bin. While electronics and software can easily control doubling the number of conveyor systems, the doubling of hydraulic motors, hydraulic valves, sensors, conveyors, bearings, drive shafts, etc. are expensive, add weight to the spreader, add volume to the drive components and take away usable volume for the spreader bins, hurt hydraulic efficiencies, etc. The increase in mechanical and hydraulic parts increase repair items and the dense packaging of those components would make access to the repair items more difficult. 
     Another way of solving the problem is to have independent upstream orifice control, commonly accomplished and referred to as a feed gate, which could meter material independently from each bin unto conveyors feeding each spinner. This also creates a doubling of mechanisms and requires movement of the gate to meter the correct amount of product. Having the orifice upstream creates the need to “look ahead” for the controls to anticipate changes in the swath width and there is the need to determine master and slave relationships between the conveyors and gates as metering is accomplished by both speed and opening. 
     The increased swath widths and the limitations of conventional dual spinner prior art create the need for a simple method of metering product flow from each spinner spreader conveyor bin to produce asymmetrical flow to each spinner to match asymmetrical spreading conditions required for various field boundary conditions. 
     Furthermore, there is also a need to create a simple method to place product onto the spinner disk in a manner to permit spreading to one side of the spreading vehicle allowing the product to be spread into a field from a road, tramline, or as the spreader is approaching a headland at a non-perpendicular angle. 
     The need for a simple method to do the above also needs to be accomplished with minimum compromise to the spread pattern coefficient of variation or restriction to the material flow. 
     SUMMARY OF THE INVENTION 
     Accordingly, a primary objective of the present invention is an improved particulate material spreader with a provision that achieves proper placement of product onto a field, lawn or other area in both symmetrical and asymmetrical patterns with relationship to the line of travel. 
     Another objective of the present invention is to divide the flow of product being delivered to twin spinners from a shared conveyor in the same ratio as the asymmetry of the required spread pattern. 
     Another objective of the present invention is to divide the flow of product being delivered to twin spinners from shared conveyors of multiple bin spreaders in the same ratio as the asymmetry of the required spread pattern. 
     Another objective of the present invention is to divide the flow of product being delivered to twin spinners by moving a divider, fixed in location with respect to the spinner disks, transversely beneath the flow of material leaving a conveyor system. 
     Another objective of the present invention is to divide the flow of product being delivered to twin spinners by moving a divider, fixed in location with respect to the spinner disks, transversely beneath the flow of material leaving a conveyor system whereas the product flow is placed on the spinner disk at a point that aids proper placement onto the field, lawn, or other area. 
     Another objective of the present invention is to combine the benefits of dividing the flow into necessary ratios via the transverse divider movement with independent fore and aft movement of the spinner under the same divider to achieve proper placement of material onto a field, lawn, or other area. 
     Another objective of the present invention is to is to divide the flow of product being delivered to twin spinners by moving a divider, fixed in location with respect to the spinner disks, transversely beneath the flow of material leaving a conveyor system whereas the product flow is placed on the spinner disk at a point that aids proper placement onto the field while spreading field boundaries. 
     The adjustable spinner of the present invention is adapted for use with a spreader for broadcasting particulate material onto a field, lawn, or other area. The spinner includes a frame which is adapted to be adjustably mounted transversely beneath a conveyor discharge. Fixed to the transversely adjustable frame is a material divider above a pair of rotating spinner disks whereas the transverse adjustment of the frame moves both the divider and disks causing a split of material flow in any number of variable ratios to each spinner disk in a ratio necessary to facilitate variable asymmetric spread patterns. The position of the divider and spinners relative to the conveyor discharge can be controlled, either manually or automatically, with or without automatic position feedback, by any number of means such as mechanical, electrical, pneumatic, or hydraulic so as to adjust the ratio and placement of material onto the spinners to accomplish any number of symmetrical or asymmetrical patterns. The position of the divider and spinners can be further aided by varied spinner rotational speeds, independent of each other, to further aid definition of spread pattern shape and position. 
     The present invention comprises: 
     A container containing flowable matter; 
     A carriage, which is movably coupled to the container; 
     A material divider which is movable with the carriage; 
     A spinner disk coupled to the carriage; 
     Means for simultaneously moving the carriage, in a first direction, which is at an angle with respect to flowable matter falling onto the material divider. 
    
    
     
       BRIEF DESCRIPTION OF DRAWINGS 
         FIG. 1  is an overview of truck mounted spreader with material storage box, conveyor, divider, and spinner spreader, of the prior art. 
         FIG. 2  is an overview of truck mounted spreader with multi-compartment storage box, a plurality of conveying means, divider, and spinner spreader, of the prior art. 
         FIG. 3  is an overview of angled headland showing variable spread widths and a spreader. 
         FIG. 4  is a simplified top view of spinner, divider, conveyor discharge for symmetrical spreading, of the present invention. 
         FIG. 5  is a spread pattern symmetry associated with the division of material in  FIG. 4 . 
         FIG. 6  is a simplified top view of spinner, divider, and conveyor discharge for a spinner offset to divide the material flow in a ratio of 2 to 1. 
         FIG. 7  is a spread pattern symmetry associated with the division of material in  FIG. 6 . 
         FIG. 8  is a simplified top view of spinner, divider, and conveyor discharge for a spinner offset to place all material onto one spinner disk. 
         FIG. 9  is a spread pattern symmetry associated with the division of material in  FIG. 8 . 
         FIG. 10  is a simplified top view of spinner, divider, and conveyor discharge for a spinner offset to place all material onto one spinner disk with divider placed to drop material later in the rotation of the disk than  FIG. 8 . 
         FIG. 11  is a spread pattern symmetry associated with the division of material in  FIG. 10 . 
         FIG. 12  is a perspective view of underside of present invention noting basic frame structures. 
         FIG. 13  is a perspective view of present invention. 
         FIG. 14  is a longitudinal vertical cross section of the present invention with details of supporting and actuating means. 
         FIG. 15  is a perspective view of present invention. 
         FIG. 16  is a perspective view of underside of present invention noting details of longitudinal movable frame. 
         FIG. 17  is a simplified top view of spinner with details of divider, conveyor and spinner disk relationships. 
         FIG. 18  is a simplified top view of spinner with details of divider, conveyor and spinner disk with spinner shifted. 
         FIG. 19  is a top view of spinner with details of vertical dividers. 
         FIG. 20  is a diagrammatic overview of a control system for the present invention. 
         FIG. 21  is a sectioned view of  FIG. 2  showing detail of conveyors, metering cylinders, and adjustable openings. 
         FIG. 22  is a depiction of a system of the present invention in its intended environment. 
     
    
    
     DETAILED DESCRIPTION 
     Now referring to the drawings, wherein like numerals refer to like matter throughout and more particularly referring now to  FIG. 1 , which is a perspective view of a typical prior art truck mounted spreader  10  comprising a single v-body hopper  11 , an endless conveyor  12  capable of transporting particulate material from the hopper  11  through an adjustable opening or feed gate  13  to the conveyor discharge end  14 . Note: while an endless conveyor belt is shown, slat conveyors, chain conveyors, augers or any suitable means of conveying the flowable matter could be used. Mounted under the conveyor discharge end  14  is a spinner spreader generally designated  20 . The spinner spreader  20  comprises two rotatable spinner disks  21  with blades  22  that can accept metered material flowing from the conveyor discharge end  14  and distribute the particulate material onto a field, lawn, or road. Any number of spinner disks more than one, could be used in the present invention, two is merely an exemplary embodiment. (For example, more could be used if subflow dividers were used for the main flow and spinners were deployed at multiple levels). Between the spinner spreader  20  and conveyor discharge end  14  is a material divider  25  that separates the material being discharged into columns of equal measure for placement onto the spinner disks  21 . Note: the material divider  25  can have an open end or can have a rear panel limiting the size of the flow. This material divider  25  may be adjustable fore and aft to direct placement onto the spinner disks  21  in a manner that affects when the particulate material leaves the disk blades  22  and therefore, the placement of the particulate material on the area being covered. As taught in Rissi patent &#39;281, the material divider  25  may also be fixed and the spinner spreader  20  itself moveable fore and aft to further affect the precise placement of material on the area being covered. 
     Now referring to  FIG. 2  and  FIG. 21 , there is shown another perspective view of a typical prior art truck mounted multi-compartment spreader  30  comprising multiple material hoppers  32 ,  33 ,  39 , and  40  with independent conveying means capable of transporting particulate material from each hopper to a discharge end. In the example shown, hoppers  32  and hopper  33  utilize endless conveyors  34  and  36  and adjustable openings  37  and  38  similar to the example in  FIG. 1  to transport and meter material to the conveyor discharge end  14 . Hoppers  39  and  40  are mounted above, and gravity feed particulate material to, metering cylinders  41  and  42 . These metering cylinders  41  and  42  and conveyor discharge ends  14  of the endless conveyors  34  and  36  all discharge material into the same vertical space where the materials fall nearly unrestricted by gravity on to a spinner spreader  20  as described earlier for the single hopper spreader  10 . Therefore, any change in the endless conveyors  34  and  36  or meter cylinders  41  and  42  revolutions per time will immediately and independently affect the volume of material discharging from each hopper. Between the spinner spreader  20  and the conveyor discharge ends  14  and metering cylinders  41  and  42  is a material divider  25  that separates the material being discharged into columns of equal measure as described earlier for the single hopper spreader  10 . Likewise, this divider  25  is typically either adjustable fore and aft or fixed as described for the single hopper spreader  10 . 
     For simplicity, the remainder of the detailed description will use references for a typical truck mounted spreader  10  comprising a single v-body hopper  11 . It shall remain understood that the present invention can be employed by spreaders with any number of material hoppers. 
     Now referring to  FIG. 3 , there is shown a somewhat diagrammatic bird&#39;s eye view of a condition encountered by spreaders in an agricultural setting where the field is in an irregular shape. The angled headland  45  is being approached by a truck mounted spreader  44 , running parallel to the previous swath  46  that was spread. As the truck mounted spreader  44  enters the acute angle formed by the headland  45  and parallel swath  46 , the need is to reduce the left hand spreading distance  47  from 100% to 0% from the centerline of travel  49  of the truck mounted spreader  44 . Also, as the truck mounted spreader  44  enters the headland area  45 , the right hand spread width  48  remains at 100% but with the desired material being spread further and further from the centerline of travel  49 . The condition described and shown is also encountered as spreaders traverse through grassy waterways or spread around potholes and similar objects creating irregular boundaries. 
     One should note that as the desired total width of the swath formed by the right hand spreading distance  48  plus the left hand spreading distance  47  is decreased, there is a corresponding need to decrease the speed of the conveyor  12  or flow through a metering device such as the adjustable opening  13  to maintain the desired rate per acre. 
     Now referring to  FIG. 4 , there is shown a simplified bird&#39;s eye view of the spinner spreader  20  with material divider  25 , rotatable disks  21 , and conveyor discharge end  14  in position for symmetrical spreading that is of similar geometry to that of the prior art. In this case, the conveyor discharge end  14  is directly placed over a referenced centerline  50 , typically that of the spreader vehicle centerline of travel  49 . The material divider  25  is also centered to the referenced centerline  50  and therefore will divide material coming from the conveyor discharge end  14  of one or more conveyors into equal amounts onto each spinner disk  21 . With volume and placement of the particulate material is divided equally and for each spinner disk  21  turning at the same revolutions per minute, the resulting distribution onto the field, lawn, or roadway will be symmetrical from the referenced centerline  50 . 
     Now referring to  FIG. 5 , there is shown a simplified representation of the resulting spread pattern of a spinner apparatus with the relationship between conveyor discharge end  14 , divider  25 , and spinner disks  21  as shown in  FIG. 4  if tested to a known standard such as ASABE S341.4. 
     Now referring to  FIG. 6 , there is shown a simplified bird&#39;s eye view of the present invention including a spinner spreader  20  with material divider  25 , rotatable disks  21 , and conveyor discharge end  14  in position for asymmetrical spreading. In this case, the conveyor discharge end  14  is directly placed over a referenced centerline  50 , typically that of the spreader vehicle centerline of travel  49 . The spinner spreader centerline  51  with material divider  25 , and spinner disks  21 , is offset from the referenced centerline  50  to divide the material flow to ⅔ to the right hand material divider opening  55  and ⅓ to the left hand material divider opening  56  and spread 75% of the original total width or 100% of the original right hand width  48  and 50% of the original left hand width  47 . Note: the offset of the material divider  25  is accomplished by a mechanism (not shown) which can move it from side to side. With a corresponding change to 75% of the original conveyor revolutions per minute, the volume of divided material passing through the right hand material divider opening  55  and onto the spinner remains equal to that of the symmetrical pattern described and shown in  FIG. 4  &amp;  FIG. 5 . Likewise, the volume of divided material falling to the left hand material divider opening  56  is reduced to 50% (33% of width multiplied by 75% of the conveyor discharge rate) of the original volume to correspond to the desired reduced left hand width  47 . 
     Now referring to  FIG. 7 , there is shown a simplified representation of the resulting spread pattern of a truck mounted spreader  440 , of the present invention, with a spinner apparatus with the relationship between conveyor discharge end  14 , divider  25 , and spinner disks  21  as shown in  FIG. 6 , if tested to a known standard such as ASABE S341.4. 
       FIG. 8  is a simplified view of a portion of truck mounted spreader  440  with spinner  20 , divider  25 , side deflector  26 , and conveyor discharge end  14  for asymmetrical spreading. In this case, the conveyor discharge end  14  is directly placed over a referenced centerline  50 , typically that of the spreader vehicle centerline of travel  49 . The material divider  25 , along with the spinner disks  21 , is offset to divide the material flow 100% to the right hand material divider opening  55  and 0% to the left hand material divider opening  56  and spread 50% of the original total width or 100% of the original right hand width  48  and 0% of the original left hand width  47 . With a corresponding change to 50% of the original conveyor revolutions per minute, the volume of material passing through the right hand material divider opening  55  and onto the spinner remains equal to that of the symmetrical pattern described and shown in  FIG. 4  &amp;  FIG. 5 . Likewise, the volume of material falling to the left hand material divider opening  56  is reduced to 0% of the original volume to correspond to the desired left hand width  47 . 
       FIG. 9  is a simplified representation of the resulting spread pattern of truck mounted spreader  440  with a spinner apparatus with the relationship between conveyor discharge end  14 , divider  25 , and spinner disks  21  as shown in  FIG. 8 , if tested to a known standard such as ASABE 5341.4. 
     Now referring to  FIG. 10 , when the truck mounted spreader  440  with a material divider center of symmetry  51  which is offset from the conveyor centerline  50  as shown in  FIGS. 6 and 8 , a simple deflector  26  is used to keep material funneled into the material divider  25 . Because the material divider opening  55  is offset from the original column of material coming from the conveyor discharge end  14 , this also creates a heavier flow near the right hand edge  57  of the right hand material divider opening  55  as shown in  FIGS. 6 and 8 . This material is placed closer to the inside of the corresponding disk  21  rotating in the direction shown, requires more rotation before it leaves the disk  21 , and is therefore thrown further away from the referenced centerline  50  at a distance defined by material shape, size, density, and by the rotational speed of the spinner disk itself. 
     Likewise, the hinged deflector  26  hangs vertically and keeps the reduced column to the left hand material divider opening  56  concentrated to the right hand edge of the left hand material divider opening  56 . The natural effect of shifting the material divider  25  therefore places most of the material to the outside of the left hand spinner disk  21  where it interacts with the blades  22  on the disk  21  rotating in the direction shown and is distributed after a small amount of disk rotation. The landing point of this particulate material is therefore directly behind the spreader without large dependence on material shape, size, density, or by the rotational speed of the spinner disk itself. 
     By utilizing a fixed divider  25  and longitudinally movable spinner frame as described in the Rissi &#39;281 patent, the shape and distribution of the particulate material can be further influenced to meet the needs of various asymmetrical conditions. In  FIG. 10 , the divider  25  and spinner disks  21  are shifted completely to one side and the longitudinally movable spinner frame is moved further under the conveyor discharge end  14  which places material on the spinner disk  21  and blades  22  later in rotation. The resulting simplified representation of the spread pattern in  FIG. 11  shows that the spread pattern onto the field can be shifted completely to the side of the centerline of travel  49  with correct fore and aft and side to side positioning of the spinner disks  21 . 
     In the preferred embodiment of the invention a spinner spreader generally designated  20  is mounted below a conveyor discharge end  14  of one or more conveying and metering means. As noted earlier and for the simplicity of describing the present invention, the remainder of the detailed description will use references, unless otherwise noted, for a typical truck mounted spreader  10  comprising a single v-body hopper  11 . It shall remain understood that the present invention can be employed by spreaders with any number of material hoppers. 
     Typically the material transported by the endless conveyor  12  passes through an adjustable opening  13 . The conveyor(s), and metering cylinders of a multi-compartment spreader, are fixed longitudinally and vertically centered with respect to each other to discharge a stream of particulate material onto the spinner disks  21  of the spinner spreader  20 . 
     In  FIG. 12 , the spinner spreader  20  contains subcomponents of the main spinner supporting frame generally denoted  60 , a transversely movable spinner frame generally denoted  70 , a longitudinally movable spinner frame generally denoted  80 , a means to move the transversely movable spinner frame  70  side to side and a means to move the longitudinally movable spinner  80  frame fore and aft. 
     Referring to  FIGS. 13  thru  16 , the main spinner supporting frame  60  is attached fixedly to the spreader  10  and is stationary with respect to the conveyor discharge end  14  or any plurality of conveying or metering means. The main spinner supporting frame  60  has one or more guiding  61  and supporting means  62  for the transversely movable spinner frame  70 . Attached to the main spinner supporting frame  60  are material deflectors  63  to keep particulate material from being cast forward from rotating spinner disks  21  into the spreader supporting chassis. 
     The transversely movable spinner frame generally denoted  70  comprises a frame  71 , one or more guiding  72 , supporting  73 , and captivating means  74  that interact with the guiding  61  and supporting means  62  of the main spinner frame  60  and a material divider  25  that is fixed to the transversely movable spinner frame  70 . The transversely movable spinner frame  70  in turn supports the longitudinally movable spinner frame generally denoted  80  via one or more guiding  81  and supporting means  82 . 
     The longitudinally movable spinner frame generally denoted  80  comprises a frame  89  that is supported by the transversely movable spinner frame  70 , one or more guiding  81 , supporting  82 , and captivating  83  means that interact with the guiding  72  and supporting  73  means of the transversely movable spinner frame  70 . Mounted to each side of the longitudinally movable spinner frame are spinner motors  84 . The spinner motors  84  rotate the spinner disks  21  and the attached spinner blades  22 . Material falling from conveyor discharge end  14  passes through the material divider  25 , onto the disks  21 , and are broadcast from the blades  22 . The longitudinally movable spinner frame  80  also supports spinner disk speed sensors  85  capable of monitoring the disk rotational speed. 
     Mounted between the main frame  60  and transversely movable frame  70  is a linear actuator  75  that is sufficient in size to shift the transversely movable frame  70  from side to side along the guiding means  72  and supporting means  73  so as to divide the material flow from the conveyor discharge end  14  into infinitely variable ratios between 0:100 and 100:0 whereas the position for a symmetrical spread pattern, generally seen in  FIG. 4 , divides the material to a 50:50 ratio. In the preferred embodiment, the linear actuator  75  is a hydraulic cylinder with an internal magnetoresistive sensor  76  capable of providing position feedback to a control system generally shown in  FIG. 20 . Whereas anyone skilled in the art of actuators will also understand that the hydraulic cylinder linear actuator  75  and sensor  76  could be replaced with any number of actuating devices and sensors that take a like form, such as an electric actuator or pneumatic cylinder with a potentiometer or LVT sensor. 
     Mounted between the transversely movable frame  70  and the longitudinally movable frame  80  is a linear actuator  86  that is sufficient in size to shift the longitudinally movable frame  80  fore and aft along the guiding  81  and supporting  82  means so as to place the material flow from the conveyor discharge end  14  and passing through the material divider  25  onto the spinner disk  21  as described in the Rissi &#39;281 patent. In the preferred embodiment, the linear actuator  86  is a hydraulic cylinder with an internal magnetoresistive sensor  87  capable of providing position feedback to a control system generally shown in  FIG. 20 . Whereas anyone skilled in the art of actuators will also understand that the hydraulic cylinder linear actuator  86  and sensor  87  could be replaced with any number of actuating devices and sensors that take a like form, such as an electric actuator or pneumatic cylinder with a potentiometer or LVT sensor. 
       FIGS. 17-19  are overhead views of spinner  20 , of the present invention with details of other features related to aiding position and directing the flow of material falling from the conveyor discharge end. One should note that the material divider  25  forms two symmetrical openings, the right hand material divider opening  55  and left hand material divider opening  56 , that funnel material to the spinner disks  21  below. Each divider opening is defined by three walls. The first wall  90  is a forward sloped surface that funnels material and defines the leading drop edge  91 . The second wall  92  is an inside sloped surface that rises to meet the inside surface of the adjacent divider opening and defines both the dividing edge  93  of the material stream and the outer drop edge  94  with respect to the spinner disk  21 . The third wall  95  is the outside surface that extends upward and away from the spinner centerline  51 . This outside surface  95  extends well beyond the outer edges of the conveyor  14 , and any metering cylinders of a multi-compartment spreader, when the transversely movable frame  70  is centered with the conveyor  12 . 
     As the transversely movable frame  70  is shifted to divide all material to one of the openings designated  55  and  56 , this extended outside surface  95  interacts with the hinged deflector  26  to funnel the material through the opening and, to the most part, towards the center of the spinner disk  21 . 
     Also aiding positioning and directing the flow of material falling from the conveyor discharge end  14  are one or more generally vertical segmenting vanes  96  that keep the falling material divided into channels during free fall from the conveyor discharge end  14  to the material divider  25 . To further aid positioning and directing the flow of material falling from the conveyor end  14  is a material divider backplate  97  that keeps the column of falling material from deviating more than a set distance from the leading drop edge  91  of the forward sloped surface  90 . This backplate  97  is removable to facilitate large flows exceeding the opening areas defined by the three walls  90 ,  92 , and  95  and backplate  97 . 
     Across the upper edge of the first wall that is the forward sloped surface  90  is a pliable material that forms a seal  100  between the bottom of the discharge conveyor end  14  and the top of the material divider  25  to further keep falling material within the defined area of the three walls. 
     In this preferred embodiment, the drop edge  91  of the forward sloped surface  90  is straight and perpendicular to the conveyor centerline  50 . It should also be understood that the shape of this drop edge  91  and the angle to the conveyor centerline  50  can be modified to further shape the distribution and pattern of the broadcast material. Likewise the distance between the spinner disks  21  and the width of the inverted vee formed by the second wall that is the inside sloped surface  92  of the material divider  25  can be modified to further shape the distribution and pattern of the broadcast material. 
     U.S. Pat. No. 6,517,281 has enjoyed considerable success in the industry. The systems and methods of that patent have been manufactured and automated. The systems and methods of the present invention can be readily automated with hardware similar to those systems which currently automate the 281 patent. Of course it would be necessary to include a transversely movable frame; an actuator; a sensor or an actuator/sensor as well as software changes to result in moving the transversely movable frame and longitudinally movable frame to produce variations in spread patterns as discussed above. It is believed that those skilled in the art of automating the 281 patent could readily adapt such systems to carry out the innovative aspects of the present invention. The following discussion is provided as a summary of some of the control requirements that may exist or components or features which could be contemplated when automating the present invention. 
     Now referring to  FIGS. 20 and 22 , there are shown simplified diagrammatic overviews of control system elements for the present invention. The machine controller element generally designated  115  comprising electronics, software, and user interfaces. The machine controller element  115  can take many different physical forms from a single, stand alone box including all electronics, software and a user interface, to a user interface  116  and a plurality of boxes  117  at different locations and with different functions. A machine controller element  115  with a plurality of boxes  117  and a user interface  116  are typically connected via ISO Bus or CAN Bus networks. This machine controller element  115  processes information and initiates machine actions based on external input elements generally designated  110 , empirically derived target elements generally designated  120 , and feedback from spreader device elements generally designated  125 . 
     The external input elements  110  comprises inputs that define spreader position and speed through a Global Positioning System (GPS) pictorially shown as a GPS satellite  112  and a GPS receiver  111 . In combination with speed and position information, the external input elements  110  also include variable symmetrical or asymmetrical swath width definitions, variable rate nutrient prescription files, nutrient material densities, and conveyor metering volumetric constants inputs that are used by the machine controller element  115  to meter the correct volume of material for variable rates and swath widths. Material ID or named material inputs are used for association with, and editing of, the empirically derived target elements  120  as it is understood from previous descriptions materials have unique size, shape, density, and hardness that affect spread characteristics. These external input elements  110  may be entered into the machine controller element  115  via the user interface  116  or any number of devices, wireless or wired to the controller element, such as laptop computers, keyboards, phones, flash drives, memory cards, etc. that are generally shown  113 . 
     Empirically derived target elements  120  include information needed to control symmetrical or asymmetrical variable swath widths for named materials broadcast at variable rates. The type of information contained in the empirically derived target elements  120  includes the spinner disk rpm for desired widths of a named material as well as movable frame positions needed for desired broadcast pattern symmetry. Empirically derived elements  120  are determined by field tests common to prior art spreaders. 
     The spreader device elements  125  include drivers and feedback for conveyor speed  126 , independent spinner rpm  127 , transversely movable frame position  128 , longitudinally moveable frame position  129 , and movable metering gate  130  per the needs of the external driver elements  110  and empirically derived target elements  120 . 
     It is understood that all elements of  FIG. 20  can be applied to single or multi-compartment spreaders. Those skilled in the art of designing automated broadcast spreader systems may create a system which is different from those shown here however it is believed that various modifications and changes to the systems described could be made without deviating from the spirit and scope of the present invention. The appended claims are intended to cover such modifications and changes.