Droplet forming device and droplet forming method

The invention claimed is: 1. A droplet forming device for discharging a droplet in a flying fashion from a discharge port, the device comprising: a liquid chamber that is communicated with the discharge port and is supplied with a liquid material; a valve seat having a communication hole for communicating the liquid chamber and the discharge port; a plunger rod having a tip that is moved to advance and retreat within the liquid chamber; a spring that biases the plunger rod in an advancing direction; a pressurization chamber that is supplied with a pressurized gas acting to retreat the plunger rod; a pressure source that supplies the pressurized gas to the pressurization chamber; a controller; and a magnetic field generating mechanism that generates a magnetic attraction force to act in the advancing direction when the plunger rod approaches a most advanced position thereof, wherein the device does not include a spring that biases the plunger rod in a retreating direction, wherein the magnetic field generating mechanism is constituted by a magnetic member disposed on the plunger rod, and a solenoid disposed to face the magnetic member, in a vertical direction along an axis of the plunger rod, and wherein the controller energizes the solenoid to generate the magnetic attraction force when the plunger rod is operated to advance toward the valve seat, thereby transferring an advancing force to the liquid material so as to discharge the liquid material in a droplet state, and wherein the controller stops power supply to the solenoid when the plunger rod is operated to retreat. 2. The droplet forming device according to claim 1 , wherein the controller energizes the solenoid in a time zone that includes a period spanning from start of an advance operation of the plunger rod to end of the advance operation of the plunger rod. 3. The droplet forming device according to claim 2 , wherein the solenoid includes a recess that allows the magnetic member to come into the recess when the plunger rod advances in the advancing direction, and that acts as a guide for movement of the magnetic member. 4. The droplet forming device according to claim 2 , further comprising a selector valve that controls a flow rate of the pressurized gas flowing into the pressurization chamber and a flow rate of the pressurized gas flowing out from the pressurization chamber. 5. The droplet forming device according to claim 2 , further comprising a height adjustment mechanism that adjusts a fixed position of the magnetic member or the solenoid, wherein the most advanced position of the plunger rod is specified by abutment between the magnetic member and the solenoid. 6. The droplet forming device according to claim 2 , further comprising a height adjustment mechanism that adjusts a fixed position of the solenoid, wherein the height adjustment mechanism comprises a spacer arranged below the solenoid, and wherein the most advanced position of the plunger rod is specified by abutment between the magnetic member and the solenoid. 7. The droplet forming device according to claim 1 , wherein the solenoid includes a recess that allows the magnetic member to come into the recess when the plunger rod advances in the advancing direction, and that acts as a guide for movement of the magnetic member. 8. The droplet forming device according to claim 1 , further comprising a selector valve that controls a flow rate of the pressurized gas flowing into the pressurization chamber and a flow rate of the pressurized gas flowing out from the pressurization chamber. 9. The droplet forming device according to claim 1 , further comprising a height adjustment mechanism that adjusts a fixed position of the magnetic member or the solenoid, wherein the most advanced position of the plunger rod is specified by abutment between the magnetic member and the solenoid. 10. The droplet forming device according to claim 1 , further comprising a height adjustment mechanism that adjusts a fixed position of the solenoid, wherein the height adjustment mechanism comprises a spacer arranged below the solenoid, and wherein the most advanced position of the plunger rod is specified by abutment between the magnetic member and the solenoid. 11. A droplet forming method using a droplet forming device for discharging a droplet in a flying fashion from a discharge port, comprising: a filling step of supplying a pressurized gas to flow into a pressurization chamber of the droplet forming device, to thereby retreat a plunger rod of the droplet forming device, and supplying a liquid material to flow into a liquid chamber of the droplet forming device; and a discharging step of releasing the pressurized gas in the pressurization chamber to advance the plunger rod toward the valve seat, and generating a magnetic attraction force by a magnetic field generating mechanism of the droplet forming device to act in an advancing direction of the plunger rod, thereby transferring an advancing force to the liquid material so as to discharge the liquid material in a droplet state, wherein the droplet forming device comprises the liquid chamber that is communicated with the discharge port and is supplied with a liquid material; the valve seat having a communication hole for communicating the liquid chamber and the discharge portion; the plunger rod having a tip that is moved to advance and retreat within the liquid chamber; a spring that biases the plunger rod in the advancing direction; a pressurization chamber that is supplied with a pressurized gas acting to retreat the plunger rod; a pressure source that supplies the pressurized gas to the pressurization chamber; a controller, and the magnetic field generating mechanism that generates the magnetic attraction force to act in the advancing direction when the plunger rod approaches a most advanced position thereof, wherein the droplet forming device does not include a spring that biases the plunger rod in a retreating direction, wherein the magnetic field generating mechanism is constituted by a magnetic member disposed on the plunger rod, and a solenoid disposed to face the magnetic member, in a vertical direction along an axis of the plunger rod, wherein, in the discharging step, the controller energizes the solenoid to generate the magnetic attraction force when the plunger rod is operated to advance, and wherein, in the filling step, the controller stops power supply to the solenoid when the plunger rod is operated to retreat. 12. The droplet forming method according to claim 11 , wherein the controller energizes the solenoid in a time zone that includes a period spanning from start of an advance operation of the plunger rod to end of the advance operation of the plunger rod. 13. The droplet forming method according to claim 12 , wherein the solenoid includes a recess that allows the magnetic member to come into the recess when the plunger rod advances in the advancing direction, and that acts as a guide for movement of the magnetic member, and in the discharging step, the magnetic member comes into the solenoid while being guided by the recess. 14. The droplet forming method according to claim 12 , wherein the droplet forming device further comprises a selector valve that controls a flow rate of the pressurized gas flowing into the pressurization chamber and a flow rate of the pressurized gas flowing out from the pressurization chamber, and wherein in the filling step, the selector valve is brought into a first position at which the pressurized gas flows into the pressurization chamber, and in the discharging step, the selector valve i