Controlled variable delivery external gear machine

The invention claimed is: 1. A controlled variable delivery external gear machine (VD-EGM), comprising: a housing; an inlet formed in the housing and configured to receive fluid from a supply; a drive gear disposed in the housing having a plurality of teeth; a driven gear disposed in the housing having a plurality of teeth and configured to be driven by the drive gear, the drive gear configured to engage the driven gear in an angular mesh zone, tooth space volumes defined by tooth spaces between each two consecutive teeth of the drive gear and each two consecutive teeth of the driven gear configured to receive volumes of fluid from the inlet as the corresponding teeth rotate about the inlet; an outlet formed in the housing and configured to receive at least some of the volume of fluid when the corresponding tooth space volumes in the angular mesh zone decrease as the corresponding teeth of the drive gear and driven gear come into contact with each other; a first slider disposed in the housing comprising a first longitudinal portion connected to a second longitudinal portion receiving longitudinal forces from fluid pressure applied to the first and second longitudinal portions substantially cancel each other thereby requiring between about 0 N to about 20 N to longitudinally moving the first slider, selective configured to vary net operational volumes of fluid communication between the inlet and the outlet, for a given rotational speed of the drive gear; and a first drive mechanism coupled to the first slider and configured to cause the first slider to slide in a longitudinal direction. 2. The VD-EGM of claim 1 , wherein the first longitudinal portion of the first slider is connected to the second longitudinal portion at a distal end of the second longitudinal portion, and further comprising a foot connected to a proximal end of the second longitudinal portion, the foot having a cross-section such that when the foot of the first slider is coupled to a first lateral side of the drive gear and a first lateral side the driven gear, a high-pressure zone fluidly coupled to the outlet and a low-pressure fluidly coupled to the inlet are generated about the first and second longitudinal portions of the first slider. 3. The VD-EGM of claim 2 , wherein the first drive mechanism includes one or more of a stepper motor, a solenoid, a lever, a cam, a hydraulic activation mechanism, and a pneumatic activation mechanism. 4. The VD-EGM of claim 3 , wherein the longitudinal forces required to longitudinally move the first slider is governed by: F net1 =P 2 ·(A 11 −A 21 )+P 1 ·(A 31 +A 21 ), wherein F net1 is the net longitudinal force needed to move the first slider longitudinally, P 2 is the pressure at the outlet, P 1 is the pressure at the inlet, A 11 is a cross-sectional of the first longitudinal portion of the first slider, A 21 is a cross-sectional area of the second longitudinal portion of the first slider, and A 31 is a cross-sectional area of the foot of the first slider. 5. The VD-EGM of claim 4 , wherein the first and second longitudinal portions of the first slider are cylindrical in shape and cross-section of the foot of the first slider is rectangular. 6. The VD-EGM of claim 5 , wherein F net1 is further governed by: F net1 =P 2 ·((d 11 2 −d 21 2 )·π/4−L 1 ·W 1 )+P 1 ·(L 1 ·W 1 +d 21 2 ·π/4), wherein d 11 is the diameter of the first longitudinal portion of the first slider, d 21 is the diameter of the second longitudinal portion of the first slider, L 1 is the length of the foot of the first slider, and W 1 is the width of the foot of the first slider. 7. The VD-EGM of claim 4 , wherein the cross section of the first and second longitudinal portions of the first slider are elliptical in shape. 8. The VD-EGM of claim 7 , wherein the cross-section of the foot of the first slider includes grooves. 9. The VD-EGM of claim 7 , wherein the foot of the first slider has an elliptical cross-section. 10. The VD-EGM of claim 4 , further comprising a second slider disposed in the housing separated from the first slider by the drive gear and the driven gear, comprising a first longitudinal portion connected to a second longitudinal portion such that longitudinal forces applied to the first and second longitudinal portions of the second slider substantially cancel each other thereby requiring between about 0 N to about 20 N to longitudinally move the second slider, selective positioning of the second slider configured to vary net operational volumes of fluid communication between the inlet and the outlet, for a given rotational speed of the drive gear and to balance lateral pressure forces acting on the drive gear and the driven gear; and a second drive mechanism coupled to the second slider and configured to cause the second slider to slide in a longitudinal direction. 11. The VD-EGM of claim 10 , wherein the first longitudinal portion of the second slider is connected to the second longitudinal portion at a distal end of the second longitudinal portion, and further comprising a foot connected to a proximal end of the second longitudinal portion, the foot having a cross-section such that when the foot of the second slider is coupled to a second lateral side of the drive gear and a second lateral side the driven gear, the high-pressure zone and the low-pressure fluidly are formed about the first and second longitudinal portions of the second slider. 12. The VD-EGM of claim 11 , wherein the second drive mechanism includes one or more of a stepper motor, a solenoid, a lever, a cam, a hydraulic activation mechanism, and a pneumatic activation mechanism. 13. The VD-EGM of claim 12 , wherein the longitudinal forces required to longitudinally move the second slider is governed by: F net2 =P 2 ·(A 12 −A 22 )+P 1 ·(A 32 +A 22 ), wherein F net2 is the net longitudinal force needed to move the first slider longitudinally, P 2 is the pressure at the outlet, P 1 is the pressure at the inlet, A 12 is a cross-sectional of the first longitudinal portion of the second slider, A 22 is a cross-sectional area of the second longitudinal portion of the second slider, and A 32 is a cross-sectional area of the foot of the second slider. 14. The VD-EGM of claim 12 , wherein the first and second longitudinal portions of the second slider are cylindrical in shape and cross-section of the foot of the second slider is rectangular. 15. The VD-EGM of claim 14 , wherein F net2 is further governed by: F net2 =P 2 ·((d 12 2 −d 22 2 )·π/4−L 2 ·W 2 )+P 1 ·(L·W 2 +d 22 2 ·π/4), wherein F net2 is the net longitudinal force needed to move the second slider downward, P 2 is the pressure at the outlet, P 1 is the pressure at the inlet, d 12 is the diameter of the first longitudinal portion of the second slider, d 22 is the diameter of the second longitudinal portion of the second slider, L 2 is the length of the foot of the second slider, and W 2 is the width of the foot of the second slider. 16. The VD-EGM of claim 12 , wherein the cross section of the first and second longitudinal portions of the first slider are elliptical in shape. 17. The VD-EGM of claim 16 , wherein the cross-section of the foot of the first slider includes grooves. 18. The VD-EGM of claim 16 , wherein the foot of the first slider has an elliptical cross-section. 19. The VD-EGM of claim 10 , where the first drive mechanism and the second drive mechanism are the same drive mechanism. 20. The VD-EGM of claim 1 , wherei