Device and method of vibro-spot welding

What is claimed is: 1. A device of vibro-spot welding comprising: a vibration cylinder housing formed of first and second piston chambers divided by a dividing wall; a first piston rod being an annular rod, integrally connected with a first piston disposed in the first piston chamber, and having one end penetrating a side of the vibration cylinder housing; a second piston rod being a circular rod penetrating the annular rod, integrally connected to a second piston disposed in the second piston chamber, and having one end penetrating the side of the vibration cylinder housing; a leading-in housing wrapping an exterior surface of the vibration cylinder housing and receiving current from a power source; an electrode supporter threaded with one end of the leading-in housing; a heating electrode threaded with one end of the electrode supporter; a first vibration electrode threaded with the one end of the first piston rod and penetrating the electrode supporter and the heating electrode; and a second vibration electrode threaded with the one end of the second piston rod and penetrating the first vibration electrode. 2. The device of claim 1 , wherein the vibration cylinder housing is formed of the first and second piston chambers by the dividing wall, and the first and second piston chambers are divided into two hydraulic chambers by first and second pistons respectively. 3. The device of claim 1 , wherein an other end portion of the first piston rod is integrally formed with the first piston, the second piston rod is inserted in the first piston and the first piston rod so as to be slidable therein, and an other end portion of the second piston rod is integrally formed with the second piston. 4. The device of claim 1 , wherein a stopper is engaged with one end portion of the first piston rod disposed at an exterior of the vibration cylinder housing. 5. The device of claim 1 , wherein another stopper is engaged with an other end portion of the second piston rod disposed at an exterior of the vibration cylinder housing. 6. The device of claim 1 , wherein the first vibration electrode is threaded with an exterior circumference of the one end portion of the first piston rod protruded to an exterior of the vibration cylinder housing in the electrode supporter. 7. The device of claim 1 , wherein the second vibration electrode is threaded with an engaging hole formed at the one end of the second piston rod protruded to an exterior of the vibration cylinder housing in the first vibration electrode. 8. The device of claim 1 , wherein the electrode supporter is threaded to an interior circumference of an end portion of the leading-in housing so as to apply the current to the heating electrode applied from the power source through the leading-in housing. 9. The device of claim 1 , wherein the first and second pistons are individually controlled by hydraulic pressure supplied to the first and second piston chambers of the vibration cylinder housing. 10. A method of vibro-spot welding overlapped upper and lower plates using a pair of welding devices of vibro-spot welding where overlapped upper and lower plates are disposed between the pair of welding devices and the pair of welding devices respectively contacts an upper surface and a lower surface of overlapped upper and lower metal plates, each welding device including a vibration cylinder housing formed of first and second piston chambers divided by a dividing wall, a first piston rod being an annular rod, integrally connected with a first piston disposed in the first piston chamber, and having one end penetrating a side of the vibration cylinder housing, a second piston rod being a circular rod penetrating the annular rod, integrally connected to a second piston disposed in the second piston chamber, and having one end penetrating the side of the vibration cylinder housing, a leading-in housing wrapping an exterior surface of the vibration cylinder housing and receiving current from a power source, an electrode supporter threaded with one end of the leading-in housing, a heating electrode threaded with one end of the electrode supporter, a first vibration electrode threaded with the one end of the first piston rod and penetrating the electrode supporter and the heating electrode, and a second vibration electrode threaded with the one end of the second piston rod and penetrating the first vibration electrode, the method comprising: a pressurizing step where pressure is applied to the upper surface and the lower surface of the overlapped upper and lower metal plates through the heating electrodes and the first and second vibration electrodes of both welding devices; a heating step where current is supplied through the heating electrodes vertically contacting with welding portions of the overlapped upper and lower metal plates such that the welding portions of the upper and lower metal plates are heated by heat generated due to electrical resistance; and a forward extruding step where vibration load is applied to the welding portions such that one second vibration electrode and confronting first vibration electrode with respect to the welding portions of the heated upper and lower metal plates iteratively cross and forward extrusion of liquid metal due to plastic flow is iteratively performed. 11. The method of claim 10 , wherein the forward extruding step comprises: a first process where one second vibration electrode moves forward and the confronting first vibration electrode moves rearward with respect to the welding portions of the heated upper and lower metal plates such that the liquid metal in the welding portions is extruded radially outwardly toward a space generated by rearward movement of the first vibration electrode; a second process where the first vibration electrode moves forward and the confronting second vibration electrode moves rearward with respect to the welding portions of the upper and lower metal plates such that the liquid metal in the welding portions is extruded radially inwardly toward a space generated by rearward movement of the second vibration electrode; and a third process where the second vibration electrode and the confronting first vibration electrode return to initial positions thereof with respect to the welding portions of the upper and lower metal plates such that the stirred liquid metal in the welding portions due to plastic flow is solid-phase welded and forms a spot welding portion. 12. The method of claim 10 , wherein vibration stroke in the forward extruding step is controlled individually according to physical characteristics of the upper and lower metal plates. 13. A method of vibro-spot welding overlapped upper and lower plates using a pair of welding devices of vibro-spot welding where overlapped upper and lower plates are disposed between the pair of welding devices and the pair of welding devices respectively contacts an upper surface and a lower surface of overlapped upper and lower metal plates, each welding device including a vibration cylinder housing formed of first and second piston chambers divided by a dividing wall, a first piston rod being an annular rod, integrally connected with a first piston disposed in the first piston chamber, and having one end penetrating a side of the vibration cylinder housing, a second piston rod being a circular rod penetrating the annular rod, integrally connected to a second piston disposed in the second piston chamber, and having one end penetrating the side of the vibration cylinder housing, a leading-in housing wrapping an exterior surface of the vibration cylinder housing and receiving current from a power source, an electrode sup