Abstract:
A bale shape monitor for assisting an operator of a round baler. The bale shape monitor has an indicator with variable sensitivity. The indicator is less sensitive for small bales and more sensitive for larger bales so that the indicator de-emphasizes bale shape problems at the beginning of bale formation and emphasizes bale shape problems when the bale is almost fully formed. The indicator also changes colors according to the degree the bale is misshapen and provides textual driving instructions.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to round balers and other baling equipment. More particularly, the invention relates to a bale shape monitor for round balers that assists an operator in forming uniform bales of crop. 
     2. Description of the Prior Art 
     Conventional round balers pick-up crop from a windrow and form it into compacted bales in a bale forming chamber. When a bale reaches a desired size and/or shape, sensors signal a controller that subsequently sends a signal to an operator&#39;s panel to instruct the operator to stop forward motion of the baler so that a bale wrapping operation can be performed. Once a bale has been formed and wrapped, it is ejected from the baler so a new bale can be formed and wrapped. 
     In most instances, the crop windrow picked up by a round baler tends to be narrower than the overall length of the baling chamber. The baler must consequently be steered left and right as it pulled across the field so an equal amount of crop material is delivered along the length of the chamber during the bale cycle; otherwise, the baler will likely form an asymmetrical bale having an uneven diameter from end to end. For example, if the baler is positioned relative to the windrow so that a disproportionate amount of crop is delivered to the left end of the baling chamber, the bale will likely have a conical shape, with the left end of the bale having a greater diameter and density than the right end. Nonuniform bale formation results in unsightly bales that are difficult to sell, stack and tie. Moreover, nonuniform bale formation often damages or places undue wear on the bale forming components. 
     Even the most skilled baler operator has difficultly in tediously weaving the baler from side to side for ensuring even delivery of crop material between the sidewalls of the baler. Accordingly, bale shape monitors have been developed to assist the operator with uniform bale formation. Conventional bale shape monitors typically include indicators placed within the cab of the tractor to signal to the operator when the bale is not being properly shaped. Traditional indicators include bale shape displays which represent the shape of the bale from end-to-end or at certain locations along the length of the bale. Some indicators also include “driving lights” which signal to the operator when to steer left, steer right or simply drive forward. Additionally, some balers have been equipped with a steering mechanism for automatically steering the baler left and right in response to the bale shape sensed by the monitor. 
     The indicators mentioned above are traditionally operated by one or more sensors on the baler. In round balers having an expandable baling chamber defined in part by a plurality of endless belts, the sensors are often associated with the endless belts adjacent the sidewalls of the baler. Each end sensor is often positioned along a stretch of the corresponding belt to detect when the stretch becomes slackened or tightened. The belts are traditionally tensioned by a single slack takeup mechanism, and accordingly, slackening of one of the belts relative to the remaining belts indicates that the area of the baling chamber bound by the one belt is receiving less crop material than the others. Alternatively, the end sensors are positioned along stretches of the belts defining the baling chamber so as to directly sense the diameter of the bale. The operator may consequently steer the baler left or right depending upon the diameter of the bale sensed adjacent the ends thereof. 
     Known bale shape monitors suffer from several limitations. For example, existing bale shape monitors have indicators that are too sensitive to non-uniform bales when the bales are relatively small and aren&#39;t sensitive enough when the bales are almost fully formed. This is because it takes a smaller amount of crop to change the shape of a bale when the bale is small and a much larger amount of crop to change the shape when the bale is nearly fully formed. The indicators therefore “jump around” when the bale is small, because a small amount of crop can quickly make one end of the bale relatively larger than the other end, causing the bale shape indicators to change rapidly and thus prompting the operator to needlessly weave the baler back and forth at a high frequency. Just as seriously, the indicators don&#39;t signal an uneven bale quickly enough when the bale is nearly fully formed, causing many bales to reach full size before the operator can make necessary driving adjustments. 
     Known bale shape monitors also typically present information about uneven bales in black and white text and/or graphs that fail to get the operator&#39;s attention quickly enough. 
     Accordingly, there is a need for an improved bale shape monitor that overcomes the limitations of the prior art. 
     SUMMARY OF THE INVENTION 
     The present invention solves the above-described problems and provides a distinct advance in the art of bale shape monitors for round balers and other baling equipment. More particularly, the present invention provides a bale shape monitor with a bale shape indicator having variable sensitivity. In one embodiment, the indicator is less sensitive for small bales and more sensitive for larger bales so that the indicator de-emphasizes bale shape problems at the beginning of bale formation and emphasizes bale shape problems when the bale is almost fully formed. This prevents the bale shape indicator from changing rapidly, or jumping around, at the beginning of a bale forming operation, and provides the operator more immediate notice of uneven bales when the bales are almost fully formed. 
     In accordance with another important aspect of the present invention, the bale shape monitor has a bale shape indicator that changes colors according to the degree a bale is misshapen. In one embodiment, the indicator includes three bars for representing the diameter of the left side, center, and right side of a bale. When the three bars are all within a certain size of one another (and therefore the bale is relatively even) all three bars may be colored green. However, if the middle, left, or right sides of the bale deviate in size from at least one other portion of the bale by a first threshold, one or more of the bars may be colored yellow, and if a portion of the bale deviates in size by a second, larger threshold, one or more of the bars may be colored red. The bale shape monitor may also display textual instructions such as “Fill Right” or “Fill Center” to assist the operator. 
     These and other important aspects of the present invention are described more fully in the detailed description below. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWING FIGURES 
       A preferred embodiment of the present invention is described in detail below with reference to the attached drawing figures, wherein: 
         FIG. 1  is a schematic, side elevational illustration of a rotary baler with a near sidewall thereof removed to reveal mechanisms within the baler. 
         FIG. 2  is a schematic, isometric illustration of some of the internal mechanisms of the baler. 
         FIG. 3  is a schematic illustration of a user interface of the bale shape monitor. 
         FIG. 4  is a sample screen display of the user interface. 
         FIG. 5  is another sample screen display of the user interface. 
         FIG. 6  is yet another sample screen display of the user interface. 
         FIG. 7  is yet another sample screen display of the user interface. 
         FIG. 8  is yet another sample screen display of the user interface. 
         FIG. 9  is yet another sample screen display of the user interface. 
         FIG. 10  is yet another sample screen display of the user interface. 
         FIG. 11  is yet another sample screen display of the user interface. 
     
    
    
     The drawing figures do not limit the present invention to the specific embodiments disclosed and described herein. The drawings are not necessarily to scale, emphasis instead being placed upon clearly illustrating the principles of the invention. 
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     The present invention is susceptible of embodiment in many different forms. While the drawings illustrate and the specification describes certain preferred embodiments of the invention, it is to be understood that such disclosure is by way of example only. There is no intent to limit the principles of the present invention to the particular disclosed embodiments. 
     The present invention is preferably incorporated as part of a round baler  10  such as the 900 series round balers manufactured by Agco Corporation including the Hesston 945, 955, 956, 946A, 956A, New Idea 6454, 6464, 6465, and Challenger RB45, RB46 and RB56 round balers; however, the invention may be incorporated as a part of other types of baling equipment such as fixed chamber balers, square balers, etc. Referring to  FIG. 1 , the preferred baler  10  includes a pair of laterally spaced apart sidewalls  12  (only one being shown) carried by ground wheels  14  (only one being shown) for advancement across a field in response to pulling force supplied to a generally fore-and-aft extending tongue  16  at the front of the sidewalls. A suitable power transmission device (not shown) incorporated as part of baler  10  is normally connected to the power-take off shaft of a tractor or other vehicle towing baler  10  for thereby supplying driving power to the various moving components of baler  10  including a crop pickup  18  thereof which may be of conventional design. 
     Because the sidewalls are laterally spaced-apart respective to the normal path of travel of the baler  10 , room is provided therebetween for formation and transport of a bale of crop formed by material which is picked up and loaded into the space between the sidewalls by pickup  18 . Hence, the sidewalls cooperate in part to define a baling chamber. The fore-and-aft limitations of the baling chamber are defined by opposed, initially generally vertically disposed stretches of an endless, flexible web means broadly denoted by the numeral  20  and preferably comprising a series of endless, side-by-side, flexible rubber belt elements having their respective longitudinal axes disposed in a plane parallel to the sidewalls. 
     The endless belts  20  are looped around a number of cylindrical rolls spanning the distance between the sidewalls. For example, a roll  22  adjacent the lower front end of baling chamber may be driven by the output of the power transmission mechanism so as to provide motive force for driving the endless belts  20  longitudinally of themselves. The other rolls may be idlers. The bottom of the baling chamber is open to present a crop inlet  24  for the pickup  18 . 
     The round baler  10  also includes a twine dispensing arm which dispenses twine or other wrapping material for wrapping bales formed in the bale forming chamber. The twine dispensing arm preferably has two twine tubes and is pivotally mounted to a pivot point at the front of the baler  10 . The twine dispensing arm is mechanically controlled by a linear actuator coupled to the arm by a drive chain and sprocket. When the actuator retracts, the end of the twine arm moves to the right side of the baler. When the actuator extends, the twine arm moves to the left side of the baler. 
     The baler  10  also includes a bale shape monitor for assisting the operator in forming uniform bales of crop. As best illustrated in  FIGS. 2 and 3 , the bale shape monitor preferably includes a bale size sensor  28 , a bale shape sensor assembly  30 , and a user interface  32 . 
     The bale size sensor  28  is preferably a rotary hall-effect sensor such as those manufactured by Power Components in Mishawaka, Ind. The bale size sensor  28  includes a rotation element which is coaxially mounted to one end of a mounting shaft  34  for belt tensioning arms  36  to produce an output signal corresponding to the rotational position of the shaft  34 , which position is representative of the size of the bale being formed in the baling chamber. The output signal of the bale size sensor  28  preferably has a range of 1-4V. 
     The bale shape sensor assembly  30  includes a center reference assembly  38 , a left side sensor assembly  40 , and a right side sensor assembly  42 . The center reference assembly  38  includes a center arm  44  swingably mounted within the baler by a transverse bar  46 . The center arm  44  is welded or otherwise fixed to the bar  46 . The ends of the bar  46  are rotatably supported to the belt tensioning arms  36  by bearing supports. A feeler wheel  48 , formed of rubber or other suitable material, is mounted to one end of the center arm  44  by a nut and bolt assembly. A bearing assembly within the wheel serves to journal the wheel on the nut and bolt assembly. The center arm  44  is positioned so that its feeler wheel  48  rides against the exterior surface of one of the centermost belts  20   a . The wheel  48  is yieldably biased against the belt  20   a  by tension springs. The center reference assembly  38  does not include its own active bale size sensor, but instead serves as a reference for the left side and right side sensors as described below. 
     The left side sensor assembly  40  also includes a swingable arm  50  and a rotatable wheel  52  mounted adjacent one end of the arm by a nut-and-bolt assembly for relative rotational movement by a bearing assembly (not shown) contained within the wheel. Fixed to the opposite end of the arm  50  is a cylindrical collar for supporting the arm  50  on the bar  46 . The collar loosely receives the bar so as to allow relative movement therebetween. The wheel  52  is yieldably pressed against the front stretch of the leftmost belt  20   b  by a tension spring. The location of the collar along the length of the bar is maintained so that the wheel presses against the leftmost belt at a point spaced equally between the sides of the belt. 
     The left side sensor assembly  40  also includes a bale shape sensor  54 , including a signal sender mounted to the bar  46  and an actuator rod mounted to the arm  50 . The bale shape sensor  54  senses the relative difference in the bale diameter at the left side of the bale versus the center by sensing differences in the tension of the leftmost belt  20   b  versus the center belt  20   a . Relative tension can be sensed because the signal sender is mounted to the bar  46 , which moves with the center arm  44 , whereas the actuator rod is mounted to the left arm  50 , which can move independently of the center arm  44  and bar  46 . When the tension on the left  20   b  and center  20   a  belts is the same, the signal sender and actuator rod rotate together so that the output signal of the signal sender doesn&#39;t change. However, if the tension on the left belt  20   b  is more or less than the tension on the center belt  20   a , the actuator rod will rotate one direction or the other relative to the signal sender to cause the signal sender&#39;s output signal to increase or decrease a proportional amount. 
     The signal sender preferably has an output signal range of 4 Volts. The signal sender and actuator rod are preferably installed and calibrated so that an output signal of 1V means the leftmost belt  20   b  is in its most slackened position relative to the center belt  20   a , an output signal of 2.5V means the leftmost belt is under the same tension as the center belt, and an output signal of 4V means the leftmost belt is in its highest tension relative to the center belt. 
     The right side sensor assembly  42  is structurally and functionally similar to the left side sensor assembly  40 , and includes a swingable arm  56 , a rotatable wheel  58  supported on the bar  46 , and a bale shape sensor  60 . The wheel  58  is yieldably pressed against a rightmost belt  20   c.    
     The bale shape sensor  60  includes a signal sender mounted to the bar  46  and an actuator rod mounted to the arm  56 . The bale shape sensor senses the relative difference in the bale diameter at the right side of the bale versus the center by sensing differences in the tension of the rightmost belt  20   c  versus the center belt  20   a  as described above with respect to the left side sensor assembly. 
     The signal sender for the right side sensor assembly preferably has an output signal range of 4 Volts. The bale shape sensor is preferably installed and calibrated so that an output signal of 4V means the rightmost belt  20   c  is in its most slackened position relative to the center belt  20   a , an output signal of 2.5V means the rightmost belt is under the same tension as the center belt, and a signal output of 1V means the rightmost belt is in its highest tension relative to the center belt. 
     It will be appreciated that the left and right side sensor assemblies  40 ,  42  are not necessarily limited to being associated with the endmost belts of the baler. In some baler constructions, it may be sufficient to associate the sensor assemblies  40 ,  42  with a belt that is only proximate to the adjacent baler sidewall. For example, the bale diameter may be sufficiently detected by associating the sensor assemblies with a belt spaced inwardly from one or more of the other belts. Furthermore, it is entirely within the scope of the present invention to utilize a pair of left and right side sensors and an intermediate sensor such as described in United States Statutory Invention Registration No. H1,819, hereby incorporated into the present application by reference. 
     The user interface  32  receives inputs from an operator of the tractor. An external control device or other computing device connection to the user interface receives output signals from the bale size sensor  28  and the left and right side bale shape sensors  54 ,  60 . The user interface  32  is preferably compatible with ISO 11783 standards so that it can be used to control operation of any implement used with the tractor or other towing vehicle. The user interface  32  is programmed with a computer program comprising an ordered listing of executable instructions for implementing logical functions of the user interface  32 . The computer program can be embodied in any computer-readable medium for use by or in connection with an instruction execution system, apparatus, or device, such as a computer-based system, processor-containing system, or other system that can fetch the instructions from the instruction execution system, apparatus, or device, and execute the instructions. In the context of this application, a “computer-readable medium” can be any means that can contain, store, communicate, propagate or transport the program for use by or in connection with the instruction execution system, apparatus, or device. The computer-readable medium can be, for example, but not limited to, an electronic, magnetic, optical, electro-magnetic, infrared, or semi-conductor system, apparatus, device, or propagation medium. More specific, although not inclusive, examples of the computer-readable medium would include the following: an electrical connection having one or more wires, a portable computer diskette, a random access memory (RAM), a read-only memory (ROM), an erasable, programmable, read-only memory (EPROM or Flash memory), an optical fiber, and a portable compact disk read-only memory (CDROM). The computer-readable medium could even be paper or another suitable medium upon which the program is printed, as the program can be electronically captured, via for instance, optical scanning of the paper or other medium, then compiled, interpreted, or otherwise processed in a suitable manner, if necessary, and then stored in a computer memory. 
     As best illustrated in  FIG. 3 , a preferred embodiment of the user interface  32  includes a display screen  62 , a control knob  63 , a plurality of function keys  65  or other inputs, and an internal controller, processor or other control device. The user interface  32  is preferably connected to the tractor key switch so that it automatically turns on when the tractor key is used to start the tractor. The control knob  63  allows the operator to scroll through the functions shown on the display screen and select one of the functions when the knob is pressed. The function keys  65  enable a displayed function or cause display of another screen. The particular operation or function of each function key is determined by software and can be changed. 
     Other details of round balers which may be used with the present invention are described in U.S. Pat. Nos. 6,477,824; 6,675,561; 4,850,271; and 4,224,867, all incorporated into the present application by reference. 
     Operation 
     To begin a bale-forming operation, an operator pulls the baler  10  across a windrow with a tractor or other vehicle in a conventional manner. As crop material is added to the bale forming chamber, the belts  20  stretch to accommodate the ever-increasing size of the bale. The bale shape monitor monitors the size and shape of the bale as it is being formed and provides important feedback to the operator via the display  62  on the user interface  32 . 
     In a preferred embodiment, the display  62  provides a representation of the bale size and shape with a three bar indicator  64  as illustrated in  FIGS. 3-11 . The middle bar  66  provides an indication of the overall bale size and is driven by the output signal of the bale size sensor  28 . For example, a bale size sensor output of 1V, which corresponds to a bale that has just started to form, results in a relatively short middle bar  66 . A sensor output of 4V, which corresponds to a bale that is fully formed, results in a relatively a tall middle bar  66 . 
     The left bar  68  provides an indication of the size of the left side of the bale and is driven by an algorithm that takes into account the output signal from the left side sensor assembly  40  and a selected bale shape sensitivity variable. In accordance with one important aspect of the present invention, the user interface  32  is programmed to provide a bale shape display that is less sensitive at small bale sizes and relatively more sensitive at larger bale sizes. For example, when the left side sensor assembly  40  determines that the leftmost belt  20   b  is slackened relative to the centermost belt  20   a , the left bar  68  of the indicator  64  will be slightly shorter than the middle bar  66  when the bale is small, but may be significantly shorter than the middle bar for the same amount of slack when the bale is almost fully formed. This prevents the indicator from “jumping around” when the bale is small (and a relatively small amount of crop can change its diameter) and gives the operator a more exaggerated indication of an uneven bale shape when the bale is nearly full (and the operator needs to quickly make changes before the bale is full size). 
     Similarly, the right bar  70  of the indicator  64  provides an indication of the size of the right side of the bale and is driven by an algorithm that takes into account the output signal from the right side sensor assembly  42  and a selected bale shape sensitivity variable. 
     The algorithm which drives the left bar of the display is:
 
Left Bar Value=Bale Size×(1.0+((1.0−LeftDiff/(EmptyChamber Left Shape Sensor Voltage−Left Limit)−1.0)×SensFactor))
         Where:   Bale Size=current size of the bale in the chamber in inches as measured by the bale size sensor.   Left Diff=difference between bale size sensor output and left bale shape sensor output voltages.   Left Limit=lower voltage limit of left bale sensor.   EmptyChamber Left Shape Sensor Voltage=the signal output of the left bale shape sensor when the bale chamber is empty. SensFactor=a variable to make shape bar graphs move more (or less) than “normal” for a given amount of voltage difference.       

     The following are examples of the algorithm results for different bale shape and size scenarios: 
     1) The bale is approximately ¼ formed and the left side is bigger than the center.
         Bale Size Setting=72″   ¼ formed bale=18″   Left Shape Sensor Voltage=3.1V   Bale Size Sensor Voltage=2.6V   Empty Chamber Left Shape Sensor Voltage=2.6V   SensFactor=1.0 (normal sensitivity)   Left Limit=0.5V   LeftBarValue=Bale Size×(1.0+((1.0−LeftDiff/(EmptyChamber Left Shape Sensor Voltage−Left Limit)−1.0)×SensFactor)) =18×(1+(1−(2.5−3.1)/(2.6−0.5)−1)×1)) =23 inches
 
Thus, the left bar  68  indicates a left side size of 23″ and the middle bar  66  indicates a bale size of 18″. For one embodiment, this may result in the left bar being 37% filled and the center bar being 29% filled.
       

     2) The bale is ½ formed and the left side is smaller than the center.
         Bale Size Setting=72″   ½ formed bale=36″   Left Shape Sensor Voltage=2.6V   Bale Size Sensor Voltage=3.1V   Empty Chamber Left Shape Sensor Voltage=2.6V   SensFactor=1.0 (normal sensitivity)   Left Limit=0.5V   LeftBarValue=Bale Size×(1.0+((1.0−LeftDiff/(EmptyChamber Left Shape Sensor Voltage−Left Limit)−1.0)×SensFactor)) =36×(1+(1−(3.1−2.6)/(2.6−0.5)−1)×1)) =27 inches
 
Thus, the left bar  68  indicates a left side size of 27″ and the middle bar  66  indicates a bale size of 36″. For one embodiment, this may result in the left bar being 40% filled and the center bar being 53% filled.
       

     3) The bale is almost fully formed and the right and/or left sides are smaller than the center.
         Bale Size Setting=72″   Almost formed bale=68″   Left Shape Sensor Voltage=3.5V   Bale Size Sensor Voltage=4.0V   Empty Chamber Left Shape Sensor Voltage=2.6V   SensFactor=1.0 (normal sensitivity)   Left Limit=0.5V   LeftBarValue=Bale Size×(1.0+((1.0−LeftDiff/(EmptyChamber Left Shape Sensor Voltage−Left Limit)−1.0)×SensFactor)) =68×(1+(1−(4.0−3.5)/(2.6−0.5)−1)×1)) =52 inches
 
Thus, the left bar  68  indicates a left side size of 52″ and the middle bar  66  indicates a bale size of 68″. For one embodiment, this may result in the left bar being 73% filled and the center bar being 96% filled.
       

     4) The bale is almost fully formed and the right and/or left sides are bigger than the center.
         Bale Size Setting=72″   Almost formed bale=68″   Left Shape Sensor Voltage=4.5V   Bale Size Sensor Voltage=4.0V   Empty Chamber Left Shape Sensor Voltage=2.6V   SensFactor=1.0 (normal sensitivity)   Left Limit=0.5V   LeftBarValue=Bale Size×(1.0+((1.0−LeftDiff/(EmptyChamber Left Shape Sensor Voltage−Left Limit)−1.0)×SensFactor)) =68×(1+(1−(4.0−4.5)/(2.6−0.5)−1)×1)) =84 inches
 
Thus, the left bar  68  indicates a left side size of 84″ and the middle bar  66  indicates a bale size of 68″. For one embodiment, this may result in the left bar being 100% filled and the center bar being 96% filled.
       

     As illustrated by the above examples, at an 18″ bale size, a 0.5V difference between bale size sensor voltage and left side bale shape sensor voltage results in a difference of 5 inches in representative size of the center and left bars,  66 ,  68 . At a 36″ bale size a 0.5V difference results in a difference of 9 inches. At a 68″ bale size, a 0.5V difference results in a difference of 16 inches. So as the bale size grows, the same voltage difference produces more bar graph difference between bars  66  and  68 . The effect is a more sensitive bar graph display as the bale gets closer to full size. 
     The above examples include a sensitivity of “normal” in all cases. For a “high” sensitivity setting, the values could be scaled up by 25% or some other amount to further increase the sensitivity of the bar indicator to shape problems. For a “low” sensitivity setting, the values could be scaled down by 25% or some other amount to decrease the sensitivity of the bar indicator to shape problems. 
     In accordance with another important aspect of the present invention, the color of one or more of the bars  66 ,  68 ,  70  on the display changes when the bale shape falls outside of certain shape limits. For example, the right bar  70  may turn yellow as depicted in  FIG. 8  if the controller determines the right side of the bale is a percentage smaller than the center of the bale. Similarly, the left bar may turn red and the right bar yellow as depicted in  FIG. 7  if the left side is a percentage bigger than the center and the right side is a percentage smaller than the center. The left and right bars may also simultaneously turn yellow or red as depicted in  FIGS. 10 and 11  if both the left and right sides deviate from the center. 
     The user interface  32  may also provide certain text messages to assist the operator in forming uniformly shaped bales. For example, “Fill Left” may be displayed as depicted in  FIG. 9  when the left bar  68  is lower than the right bar  70 . “Fill Left” may also be displayed when the right bar is higher than both the middle bar and the left bar. 
     “Fill Right” may be displayed when the right bar  70  is lower than either the left bar  68  or the middle bar  66  as depicted in  FIGS. 7 and 8 . 
     “Fill Edges” may be displayed as depicted in  FIG. 10  when both the left and right bars  68 ,  70  are lower than the middle bar  66 . “Fill Center” may be displayed as depicted in  FIG. 11  when both the left and right bars  68 ,  70  are higher than the middle bar  66 . 
     “Near Full” may be displayed for 2 seconds when the bale nearly reaches the full bale size limit. “Near Full” display takes priority over bale shape texts for 2 seconds. 
     “Full Bale” may be displayed as depicted in  FIG. 6  when the bale reaches the full bale size limit. “Full Bale” text takes priority over all other texts on the General Text object. 
     Although the invention has been described with reference to the preferred embodiment illustrated in the attached drawing figures, it is noted that equivalents may be employed and substitutions made herein without departing from the scope of the invention as recited in the claims. For example, although the bale size and shape indicator of the present invention is particularly suited for use with round balers, it may also be used with other baling equipment.