Inboard spring arrangement for a clutch actuated differential

What is claimed is: 1. A differential comprising: a differential case adapted to be rotated about an axis of rotation; a cross-shaft operatively coupled to the differential case such that the cross-shaft and the differential case rotate together about the axis of rotation; left and right clutch actuators having opposing inboard sides between which the cross-shaft is positioned; left and right axle hubs positioned on opposite sides of the cross-shaft; a left clutch pack that prevents relative rotation between the left clutch actuator and the left axle hub about the axis of rotation when a left clutch engagement pressure is applied to the left clutch pack; a right clutch pack that prevents relative rotation between the right clutch actuator and the right axle hub about the axis of rotation when a right clutch engagement pressure is applied to the right clutch pack; a clutch pre-load spring that applies pressure to both the left and right clutch packs without applying pressure to the left and right clutch actuators, the clutch pre-load spring being positioned inboard of the left and right clutch packs; and wherein contact between the cross-shaft and a ramp surface at the inboard side of the left clutch actuator causes the left clutch engagement pressure to be applied to the left clutch pack, and wherein contact between the cross-shaft and a ramp surface at the inboard side of the right clutch actuator causes the right clutch engagement pressure to be applied to the right clutch pack. 2. The differential of claim 1 , wherein a central reference plane extends along an interface between the inboard sides of the left and right clutch actuators, wherein the central reference plane is perpendicular with respect to the axis of rotation, and wherein the clutch pre-load spring extends across the central reference plane. 3. The differential of claim 2 , wherein a limited range of rotational movement about the axis of rotation is permitted between the left and right clutch actuators, and wherein the clutch pre-load spring flexes in response to relative rotation between the left and right clutch actuators about the axis of rotation. 4. The differential of claim 3 , wherein the clutch pre-load spring is a coil spring. 5. The differential of claim 4 , wherein the inboard sides of the left and right clutch actuators define pockets that cooperate to define a shaft receptacle that receives the cross-shaft, and wherein each pocket includes first and second ramp surfaces separated by a neutral position, wherein the left engagement pressure is not applied to the left clutch pack when the cross-shaft aligns with the neutral position of the left clutch actuator, and wherein the right engagement pressure is not applied to the right clutch pack when the cross-shaft aligns with the neutral position of the right clutch actuator. 6. The differential of claim 5 , further comprising a plurality of the clutch pre-load springs that cooperate to apply left and right clutch pre-loads respectively to the left and right clutch packs, wherein each of the clutch pre-load springs applies a portion of the left clutch pre-load and a portion of the right clutch pre-load, and wherein none of the clutch pre-load springs apply pressure to the left and right actuators. 7. The differential of claim 6 , wherein the clutch pre-load springs are spaced uniformly about the axis of rotation. 8. The differential of claim 6 , wherein the left and right clutch actuators define a plurality of spring holes each having open inboard and outboard ends, and wherein each of the clutch pre-load springs extends though one of the spring holes of the left clutch actuator and a corresponding one of the spring bores of the right clutch actuator. 9. The differential of claim 1 , further comprising a plurality of the clutch pre-load springs that cooperate to apply left and right clutch pre-loads respectively to the left and right clutch packs, wherein each of the clutch pre-load springs applies a portion of the left clutch pre-load and a portion of the right clutch pre-load without applying the pre-loads through the left and right clutch actuators. 10. The differential of claim 9 , wherein the clutch pre-load springs are spaced uniformly about the axis of rotation. 11. The differential of claim 1 , wherein the left and right clutch actuators define through-holes that receive the clutch pre-load springs. 12. The differential of claim 11 , wherein the through-holes each include cylindrical portions and tapered portions, wherein the tapered portions define diameters that increase in size as the tapered portions extend in an inboard direction, and wherein major diameters of the tapered portions are positioned at the inboard sides of the left and right clutch actuators. 13. The differential of claim 9 , wherein the left and right clutch actuators respectively house the left and right clutch packs, wherein the clutch pre-load springs extend through the left and right clutch actuators and across an interface between the left and right clutch actuators, and wherein each of the clutch pre-load springs includes opposite ends that abut against inboard thrust washers of the left and right clutch packs. 14. The differential of claim 1 , further comprising outboard springs that bias the left and right clutch actuators toward one another without applying spring load through the left and right clutch packs. 15. A differential comprising: a differential case adapted to be rotated about an axis of rotation; a cross-shaft operatively coupled to the differential case such that the cross-shaft and the differential case rotate together about the axis of rotation, the cross-shaft being transversely aligned relative to the axis of rotation; left and right clutch actuators having opposing inboard sides between which the cross-shaft is positioned, the inboard sides of the left and right clutch actuators defining pockets that cooperate to define a shaft receptacle that receives the cross-shaft, each pocket including first and second ramp surfaces separated by a neutral position, the left and right clutch actuators defining spring through-holes each having open inboard and outboard ends; left and right axle hubs positioned on opposite sides of the cross-shaft; a left clutch pack that prevents relative rotation between the left clutch actuator and the left axle hub about the axis of rotation when a left clutch engagement pressure is applied to the left clutch pack; a right clutch pack that prevents relative rotation between the right clutch actuator and the right axle hub about the axis of rotation when a right clutch engagement pressure is applied to the right clutch pack; clutch pre-load springs that each apply pre-load pressure to both the left and right clutch packs, the clutch pre-load springs being positioned inboard of the left and right clutch packs and having a left portions positioned in the spring through-holes of the left clutch actuator and right portions positioned in the spring through holes of the right clutch actuator, the clutch pre-load springs extending across an interface between the left and right clutch actuators; and wherein contact between the cross-shaft and one of the first and second ramp surfaces of the left clutch actuator causes the left clutch engagement pressure to be applied to the left clutch pack, wherein contact between the cross-shaft and one of the first and second ramp surfaces of the right clutch actuator causes the right clutch engagement pressure to be applied to the right clutch pack, wherein the left engagement pressure is not applied to the left clutch pack when the cros