Method(s) to apply tension to increase drivetrain jump torque capacity

What is claimed is: 1. A chain system within a drivetrain transfer case of an engine comprising: a drive sprocket; a driven sprocket; a chain connecting the drive sprocket to the driven sprocket, the chain having a slack strand between the driven sprocket and the drive sprocket and a tight strand between the driven sprocket and the drive sprocket; a first tensioner mounted within the drivetrain transfer case to interact with the slack strand of the chain at a first mounting position closer to the driven sprocket than the drive sprocket applying tension asymmetrically towards the driven sprocket, such that slack of the chain accumulates adjacent the drive sprocket, increasing a jump torque of the chain; and a second tensioner mounted within the drivetrain transfer case to interact with the tight strand of the chain at a second mounting position closer to the driven sprocket than the drive sprocket; wherein the first tensioner comprises: a first tensioner mounting bracket mounted to the drivetrain transfer case having a pivot axle extending perpendicular therefrom; a first tensioner arm comprising a body with a first tensioner arm end, the first tensioner arm comprising: a first plate defining a first hole at a first end of the first plate for receiving the pivot axle and a second hole at a second end of the first plate; a second plate defining a first hole at a first end of the second plate for receiving the pivot axle and a second hole at a second end of the second plate; a pivot pin received within second hole of the first plate and the second hole of the second plate; a first tensioning arm tensioning foot received between the first plate and the second plate comprising a body defining a pivot hole for receiving the pivot pin and having a chain sliding surface adapted to interact with the slack strand of the chain, the pivot hole opposite the chain sliding surface; and a torsion spring mounted between the first tensioner arm mounting bracket and the first tensioner arm biasing the first tensioner arm end of the first tensioner arm on the pivot axle towards the slack strand of the chain; wherein the second tensioner comprises: a second tensioner mounting bracket mounted to the drivetrain transfer case having a pivot axle extending perpendicular therefrom; a second tensioner arm comprising a body comprising: a first plate defining a first hole at a first end of the first plate for receiving the pivot axle of the second tensioner mounting bracket and a second hole at a second end of the first plate; a second plate defining a first hole at a first end of the second plate for receiving the pivot axle of the second tensioner mounting bracket and a second hole at a second end of the second plate; a pivot pin received within second hole of the first plate of the second tensioner arm and the second hole of the second plate of the second tensioner arm; a second tensioner arm tensioning foot received between the first plate and the second plate of the second tensioner arm comprising a body defining a pivot hole for receiving the pivot pin of the second tensioner arm and having a chain sliding surface adapted to interact with the tight strand of the chain, the pivot hole opposite the chain sliding surface; and a torsion spring mounted between the second tensioner arm mounting bracket and the second tensioner arm biasing a first end of the second tensioner arm on the corresponding pivot axle towards the tight strand of the chain. 2. The chain system of claim 1 , wherein a first end of the torsion spring of the first tensioner is grounded to the first tensioner arm mounting bracket and a second end of the torsion spring of the first tensioner contacts the first end of the first tensioner arm. 3. The chain system of claim 1 , further comprising a first tensioner arm stop mounted to the first tensioner arm tensioning foot adapted to prevent tensioner device damage from a tooth jump event by limiting rotation of the first tensioner arm tensioning foot through an interface between the drivetrain transfer case and the first tensioner arm stop and a second tensioner arm stop mounted to the second tensioner arm tensioning foot adapted to prevent tensioner device damage from a tooth jump event by limiting rotation of the second tensioner arm tensioning foot through an interface between the drivetrain transfer case and the second tensioner arm stop. 4. The chain system of claim 1 , wherein the chain has a width between 12.70 mm to 50.8 mm.