Laser welding device and laser welding method

The invention claimed is: 1. A laser welding device comprising: a welding head configured to emit a laser beam to a working point; a shield gas supplying nozzle configured to supply shield gas to the working point; and a first air supplying nozzle configured to supply a first air stream between the shield gas supplying nozzle and the welding head, such that the first air stream has a flow rate that is larger than a flow rate of the shield gas, and is supplied in a horizontal direction directly above the shield gas supplied to the working point, or in a direction substantially orthogonal to an optical axis of the laser beam emitted in an emission direction of the laser beam, wherein: the first air supplying nozzle is disposed 80 mm to 200 mm above the working point, or in a range equal to or lower than a half of a working distance between an emission surface of the laser beam of the welding head and the working point, and the first air supplying nozzle supplies the first air stream in a belt shape that is elongated in the emission direction of the laser beam along the optical axis. 2. The laser welding device according to claim 1 , wherein an outlet of the first air supplying nozzle has a multi-layered or a single-layered belt shape. 3. The laser welding device according to claim 1 , further comprising an angle adjuster configured to adjust a discharge angle of each of the first air supplying nozzle and the shield gas supplying nozzle, wherein the angle adjuster adjusts a relative angle between the first air supplying nozzle and the shield gas supplying nozzle to have an angle of 20 to 70 degrees. 4. The laser welding device according to claim 1 , further comprising a nozzle-height adjuster that is equipped with the shield gas supplying nozzle and the first air supplying nozzle and that is configured to adjust a height of the shield gas supplying nozzle with respect to the working point. 5. The laser welding device according to claim 1 , wherein the shield gas supplying nozzle has a cylindrical shape, has an outlet for discharging the shield gas equipped with a mesh, and is formed of a material of which reflectance against a laser beam with a wavelength of 900 nm to 1100 nm is greater than 80%. 6. The laser welding device according to claim 3 , wherein the angle adjuster is included in the welding head. 7. The laser welding device according to claim 4 , wherein the nozzle-height adjuster is included in the welding head. 8. The laser welding device according to claim 3 , wherein the angle adjuster is included in a welding jig. 9. The laser welding device according to claim 4 , wherein the nozzle-height adjuster is included in a welding jig. 10. The laser welding device according to claim 1 , further comprising a second air supplying nozzle provided directly below the welding head and configured to supply a second air stream having a flow rate that is smaller than or equal to a flow rate of the first air stream so as to prevent fumes and spatters from being adhered to a protective glass provided on a surface of the welding head from which the laser beam is emitted, the second air stream being supplied in a direction that does not interfere with the shield gas discharged from the shield gas supplying nozzle, and is identical to a direction in which the first air stream is supplied from the first air supplying nozzle, wherein the first air supplying nozzle is disposed between the second air supplying nozzle and the shield gas supplying nozzle. 11. A method of laser welding, the method comprising: providing a laser welding device including: a welding head configured to emit a laser beam to a working point; a shield gas supplying nozzle configured to supply shield gas to the working point; and a first air supplying nozzle configured to supply a first air stream between the shield gas supplying nozzle and the welding head, such that the first air stream has a flow rate that is larger than a flow rate of the shield gas, and is supplied in a horizontal direction directly above the shield gas supplied to the working point, or in a direction substantially orthogonal to an optical axis of the laser beam emitted in an emission direction of the laser beam, wherein the first air supplying nozzle is 80 mm to 200 mm above the working point, or in a range equal to or lower than a half of a working distance between an emission surface of the laser beam of the welding head and the working point; and supplying the first air stream in a belt shape that is elongated in the emission direction of the laser beam along the optical axis. 12. The method of laser welding according to claim 11 , further comprising setting a relative angle between the first air supplying nozzle and the shield gas supplying nozzle to an angle of 20 to 70 degrees. 13. The method of laser welding according to claim 12 , further comprising adjusting, with an angle adjuster, a discharge angle of each of the first air supplying nozzle and the shield gas supplying nozzle, wherein the angle adjuster is included in the welding head. 14. The method of laser welding according to claim 12 , further comprising adjusting, with an angle adjuster, a discharge angle of each of the first air supplying nozzle and the shield gas supplying nozzle, wherein the angle adjuster is included in a welding jig. 15. The laser welding device according to claim 1 , wherein the shield gas supplying nozzle and the first air supplying nozzle are positioned ahead of the welding head relative to a traveling direction of the welding head. 16. The laser welding device according to claim 10 , wherein the welding head is movable in a welding direction, and the shield gas supplying nozzle, the first air supplying nozzle, and the second air supplying nozzle are positioned ahead of the welding head relative to the welding direction.