Force amplifying driver system, jetting dispenser, and method of dispensing fluid

What is claimed is: 1. A method of jetting a droplet of hot melt adhesive using a dispenser including an actuator, and a valve including a valve member with a tip and a valve seat located in a fluid chamber, the method comprising: moving the actuator along an axis and under power through a gap existing between the actuator and the valve member, wherein said power is selectively applied to move the actuator toward the valve member; mechanically contacting the actuator with the valve member at the end of the gap to provide an amplifying force to the valve member; and moving the actuator and the valve member together along a working distance along the axis using the amplifying force, such that the tip of the valve member moves through the fluid chamber along the axis to abruptly engage with the valve seat at the end of the working distance causing the droplet of the hot melt adhesive to dispense from the valve. 2. The method of claim 1 , wherein moving the actuator further comprises moving the actuator under pneumatic power. 3. The method of claim 1 , wherein moving the actuator further comprises moving the actuator under electric power. 4. The method of claim 1 , further comprising removing said power applied to the actuator, wherein, responsive to removing said power and using, at least in part, a spring bias, the valve member returns to a starting position, and wherein the tip of the valve member is disengaged from the valve seat in the starting position. 5. The method of claim 4 , wherein the dispenser includes a stop coupled to the valve member within the fluid chamber, and the method further comprises: stopping the valve member at the starting position with the stop. 6. The method of claim 4 , wherein returning the valve member to a starting position further comprises: disengaging the actuator and the valve member. 7. A jetting valve, comprising: a housing including a fluid chamber adapted to contain hot melt adhesive, said fluid chamber further including a valve seat; and a valve member mounted for movement within the housing, said valve member including a first portion extending outwardly from the housing and configured to be operated by an actuator traveling, under selectively applied power, toward said first portion and through a gap between said actuator and said first portion prior to abruptly engaging said first portion, and a second portion within said fluid chamber and including a tip engageable with said valve seat to cause a discharge of a droplet of the hot melt adhesive. 8. The jetting valve of claim 7 , further comprising a biased return mechanism operable to cause, at least in part, the valve member to return to a starting position upon removal of said power applied to the actuator, and a stop for stopping the valve member at the starting position, wherein the tip of the second portion of the valve member is disengaged from the valve seat in the starting position. 9. The method of claim 1 , wherein the moving the actuator along an axis and under power through a gap existing between the actuator and the valve member comprises accelerating the actuator in a downward direction toward the valve member. 10. The jetting valve of claim 7 , wherein said first portion of said valve member is further configured to be operated by said actuator accelerating in a downward direction toward said valve member. 11. The method of claim 1 , wherein the hot melt adhesive is heated. 12. The method of claim 11 , wherein the hot melt adhesive is heated to a temperature above 250° F. 13. The jetting valve of claim 7 , wherein the hot melt adhesive is heated. 14. The jetting valve of claim 13 , wherein the hot melt adhesive is heated to a temperature above 250° F. 15. The method of claim 1 , wherein the axis corresponds to a longitudinal axis of the actuator. 16. The method of claim 15 , wherein the axis further corresponds to a longitudinal axis of the valve member. 17. The method of claim 1 , wherein the actuator contacts the valve member with a flat surface of the actuator. 18. The method of claim 17 , wherein the flat surface is a flat end surface of the actuator. 19. The jetting valve of claim 7 , wherein a direction of travel of the actuator through the gap corresponds to a longitudinal axis of the actuator. 20. The jetting valve of claim 7 , wherein the first portion of the valve member is further configured to be abruptly engaged by a flat surface of the actuator.