Combine crop conveying and feeding system

What is claimed is: 1. A combine feeding system that maintains a constant clearance between a header auger and a feeder comprising: a feeder housing comprising (i) a first housing wall extending from a front end of the feeder housing to a rear end of the feeder housing and (ii) a second housing wall extending from the front end of the feeder housing to the rear end of the feeder housing, the second housing wall being spaced away from and substantially parallel to the first housing wall; a drive shaft coupled to at least one of the first housing wall and the second housing wall, extending lengthwise between the first housing wall and the second housing wall proximate to a rear end of the feeder housing and configured to rotate around a drive shaft axis substantially perpendicular to the first housing wall and the second housing wall; a lower conveyor roller proximate to the front end of the feeder housing, coupled to at least one of the first housing wall and the second housing wall, extending lengthwise between the first housing wall and the second housing wall and configured to rotate around a lower conveyor roller axis substantially perpendicular to the first housing wall and the second wall; an upper conveyor roller located proximate to the front end of the feeder housing, coupled to at least one of the first housing wall and the second housing wall, spaced from the lower conveyor roller, extending lengthwise between the first housing wall and the second housing wall and configured to rotate around an upper conveyor roller axis substantially perpendicular to the first housing wall and the second housing wall; at least one chain configured to move over the drive shaft, the lower conveyor roller and the upper conveyor roller; at least one lower support arm coupled to the drive shaft and the lower conveyor roller and configured to pivot about the drive shaft axis; the at least one lower support arm pivots around the shaft axis to regulate a tension in the at least one chain without reducing a predetermined distance between an auger associated with the feeder housing and a front surface of the at least one chain. 2. The combine feeding system of claim 1 , further comprising at least one upper support arm coupled to the drive shaft and the upper conveyor roller and configured to pivot about the drive shaft axis, wherein the at least one force mechanism is coupled to at least one of (i) an outer surface of the at least one upper conveyor roller and another outer surface of the at least one lower support arm; and (ii) an outer surface of the at least one upper support arm and an outer surface of the at least one lower support arm. 3. The combine feeding system of claim 2 , wherein the at least one lower support arm comprises: a first lower support arm proximate to the first housing wall, and a second lower support arm proximate to the second housing wall and spaced lengthwise from the first lower support arm; the at least one upper support arm comprises: a first upper support arm proximate to the first housing wall, and a second upper support arm proximate to the second housing wall and spaced lengthwise from the first upper support arm; the at least one chain comprises: a first chain proximate to the first housing wall and configured to move over the drive shaft, the lower conveyor roller and the upper conveyor roller, and a second chain proximate to the second housing wall, spaced lengthwise from the first chain and configured to move over the drive shaft, the lower conveyor roller and the upper conveyor roller; and the at least one force mechanism comprises: a first force mechanism configured to apply a first force to (i) the first chain and the first lower support arm in the first direction and (ii) the first chain and the first upper support arm in the second direction substantially opposite the first direction, a second force mechanism configured to apply a second force to (i) the second chain and the second lower support arm in the first direction and (ii) the second chain and the second upper support arm in the second direction substantially opposite the first direction. 4. The combine feeding system of claim 2 , wherein the lower conveyor roller, the upper conveyor roller, the at least one lower support arm and the at least one upper support arm together comprise a conveyor assembly which is configured to pivot about the about the drive shaft axis; and the at least one upper support arm is configured to independently pivot about the drive shaft axis with respect to the at least one lower support arm. 5. The combine feeding system of claim 2 , wherein when the tension of the at least one chain decreases, the at least one force mechanism is further configured to: (i) move the lower conveyor roller and the upper conveyor roller away from each other; and (ii) control a distance between an outer surface of a header auger and an outer surface of the at least one chain facing the header auger to remain substantially the same. 6. The combine feeding system of claim 2 , wherein the at least one upper support arm extends an upper support arm distance from the drive shaft to the upper conveyor roller; and the at least one lower support arm extends a lower support arm distance from the drive shaft to the lower conveyor roller, wherein the upper support arm distance and the lower support arm distance are the same. 7. The combine feeding system of claim 2 , wherein, the at least one lower support arm extends a lower support arm distance from the drive shaft to the lower conveyor roller; and the at least one upper support arm extends an upper support arm distance from the drive shaft to the upper conveyor roller, wherein the upper support arm distance is less than the lower support arm distance. 8. The combine feeding system of claim 2 , wherein the at least one lower support arm extends a lower support arm distance from the drive shaft to the lower conveyor roller; and the at least one upper support arm extends an upper support arm distance from the drive shaft to the upper conveyor roller, wherein the upper support arm distance is greater than the lower support arm distance. 9. A method of maintaining a constant clearance between a header auger and a feeder when conveying crop material through a combine feeding system comprising: conveying crop material, via a conveyor assembly, through a feeding system by: driving a drive shaft coupled to a feeder housing and proximate to a rear end of the feeder housing, causing the drive shaft to rotate about a drive shaft axis, rotating a lower conveyor roller coupled to the feeder housing and proximate to a front end of the feeder housing about a lower conveyor roller axis, rotating an upper conveyor roller spaced from the lower conveyor roller and located above the lower conveyor roller about an upper conveyor roller axis; moving at least one chain over the drive shaft, the lower conveyor roller and the upper conveyor roller; and pivoting at least one lower support arm coupled to the drive shaft and the lower conveyor roller about the drive shaft axis; applying a force, by a force mechanism, to the at least one chain, in both a first direction and in a second direction that is substantially opposite the first direction; and regulating a tension in the at least one chain without reducing a predetermined distance between an auger associated with the feeder housing and a front surface of the at least one chain. 10. The method of claim 9 , further comprising: conveying the crop material, by a header auger, to the feeding system, and controlling a distance between a rear surface of the header auger and a front surface of the at least one