Load control system and method for an agricultural harvester

We claim: 1. In an agricultural combine harvester ( 100 ) supported on a ground engaging arrangement ( 108 ) for over-the-ground travel in a forward direction during harvesting operation and including a forwardly extending feederhouse ( 104 ) mounted to a frame ( 110 ) of the harvester ( 100 ) by right and left pivots ( 140 ) and ( 142 ), respectively, for pivoting vertically about a first, horizontal transverse axis and a harvesting head ( 102 ) mounted at a forward end of the feederhouse ( 104 ) for pivoting vertically about a second, horizontal transverse axis ( 154 ), a system for controlling a load imposed on the feederhouse ( 104 ) due to the harvesting head ( 102 ) colliding with the ground, comprising: a first load sensor ( 124 , 126 , 128 , 130 ) disposed to sense a first load applied to a left side of the feederhouse ( 104 ); a second load sensor ( 132 , 134 , 136 , 138 ) disposed to sense a second load applied to a right side of the feederhouse ( 104 ); a controllable powered driving arrangement ( 122 , 212 ) coupled to said ground-engaging arrangement ( 108 ) for selectively controlling a ground speed of the around-engaging arrangement ( 108 ); a controllable, powered lifting arrangement ( 144 , 146 , 210 , 214 , 216 ) connected between the frame ( 110 ) of the harvester ( 100 ) and the feederhouse ( 104 ) for selectively effecting vertical movement of the feederhouse ( 104 ) about said first horizontal transverse axis; an electronic control unit ( 200 ) coupled to the first load sensor ( 124 , 126 , 128 , 130 ) and the second load sensor ( 132 , 134 , 136 , 138 ), wherein the electronic control unit ( 200 ) is configured to (a) read a first load signal from the first load sensor, (b) read a second load signal from the second load sensor, (c) determine whether a difference of the first load and the second load exceeds a threshold load, and (d) if the difference exceeds the threshold load, to control one of said powered lifting arrangement to lift the harvesting head ( 102 ) and said powered driving arrangement ( 122 , 212 ) to stop over-the-ground travel of the agricultural harvester ( 100 ). 2. The agricultural combine harvester ( 100 ) of claim 1 , wherein the first load sensor ( 124 ) is disposed adjacent to the first pivot ( 140 ), and the second load sensor is disposed adjacent to the second pivot ( 142 ). 3. The agricultural combine harvester ( 100 ) of claim 1 , wherein the agricultural harvester ( 100 ) further comprises a frame ( 148 ) wherein the frame ( 148 ) is pivotally coupled to the front of the feederhouse at a third pivot ( 150 ) and a fourth pivot ( 152 ), which are located along said second horizontal transverse axis ( 154 ), and further wherein the frame ( 148 ) is configured to support and supports the harvesting head ( 102 ). 4. The agricultural combine harvester ( 100 ) of claim 3 , wherein the first load sensor ( 130 ) is disposed adjacent to the third pivot ( 150 ) and the second load sensor ( 138 ) is disposed adjacent to the fourth pivot ( 152 ). 5. The agricultural combine harvester ( 100 ) of claim 1 , wherein the powered lifting arrangement) comprises a first feederhouse lift cylinder ( 144 ) and a second feederhouse lift cylinder ( 146 ), wherein the first feederhouse lift cylinder ( 144 ) and the second feederhouse lift cylinder ( 146 ) are configured to move a forward end of the feederhouse vertically, and further wherein a rear end of the first feederhouse lift cylinder ( 144 ) is coupled to the frame ( 110 ) of the self-propelled agricultural harvesting vehicle ( 106 ) at a third pivot, and a rear end of the second feederhouse lift cylinder ( 146 ) is coupled to the frame ( 110 ) of the self-propelled agricultural harvesting vehicle ( 106 ) at a fourth pivot. 6. The agricultural combine harvester ( 100 ) of claim 5 , wherein the first load sensor ( 126 ) is disposed adjacent to the third pivot, and the second load sensor ( 134 ) is disposed adjacent to the fourth pivot. 7. The agricultural combine harvester ( 100 ) of claim 5 , wherein the first feederhouse lift cylinder ( 144 ) has a front end pivotally coupled to a first front end location of the feederhouse and the second feederhouse lift cylinder ( 146 ) has a front end pivotally coupled to a second front end location of the feederhouse, and wherein the first load sensor ( 128 ) is disposed adjacent to a front end of the first feederhouse lift cylinder ( 144 ), and wherein the second load sensor ( 136 ) is disposed adjacent to a front end of the second feederhouse lift cylinder ( 146 ). 8. The agricultural combine harvester ( 100 ) of claim 1 , wherein the first load sensor ( 124 , 126 , 128 , 130 ) is disposed to sense the first load at a first position on the left side of the agricultural harvester ( 100 ), and wherein the second load sensor ( 132 , 134 , 136 , 138 , is disposed to sense the second load at a second position on the right side of the agricultural harvester, and further wherein the first position and the second position are disposed directly opposite each other and equidistant from a longitudinally and vertically extending plane that passes through the lateral middle of the feederhouse ( 104 ). 9. A method for controlling a load on a feederhouse of an agricultural harvester ( 100 ) comprising: a step of automatically and electronically sensing a first load transmitted to a first location at a left side of the feederhouse of the agricultural harvester by a harvesting head ( 102 ) of the agricultural harvester; a step of automatically and electronically sensing a second load transmitted to a second location at a right side of the feederhouse of the agricultural harvester by the harvesting head ( 102 ) of the agricultural harvester; a step of automatically and electronically determining whether a difference in magnitude between the first load and the second load exceeds a threshold load; a step of automatically and electronically performing one of (a) raising an agricultural harvesting head ( 102 ) and (b) stopping over-the-ground movement of the agricultural harvester ( 100 ), when the difference in magnitude between the first load and the second load exceeds the threshold load. 10. The method of claim 9 , wherein the first location and the second location are disposed directly opposite to each other, and equidistant from a longitudinal and vertically extending plane passing through the lateral middle of at least one of the feederhouse ( 104 ). 11. The method of claim 9 , wherein the first load is location is at a forward end of the feederhouse ( 104 ), and wherein the second location is at a forward end of the feederhouse ( 104 ). 12. The method of claim 9 , wherein the first location is at a rear end of the feederhouse ( 104 ), and wherein the second location is at a rear end of the feederhouse ( 104 ). 13. The method of claim 9 , wherein the first load is measured at a front end of a left side feederhouse lift cylinder ( 144 ), and wherein the second load is measured at a front end of a right side feederhouse lift cylinder ( 146 ). 14. The method of claim 9 , wherein the first load is measured at a rear end of a left side feederhouse lift cylinder ( 144 ) and wherein the second load is measured at a rear end of a right side feederhouse lift cylinder ( 146 ).