Laser-scribed grain-oriented silicon steel resistant to stress-relief annealing and manufacturing method therefor

The invention claimed is: 1. A laser-scribed grain-oriented silicon steel resistant to stress-relief annealing, wherein parallel linear grooves are formed on one or both sides of grain-oriented silicon steel by laser etching, wherein the linear grooves are perpendicular to, or at an angle to, the direction of rolling the silicon steel into a steel plate; a maximum height of edge protrusions of the linear grooves does not exceed 5 μm, and a maximum height of spatters in etch-free regions between adjacent linear grooves does not exceed 5 μm, and the proportion of spatters per unit area in the etch-free regions between adjacent linear grooves does not exceed 5%, wherein the line roughness R a of a center line in the bottom of the linear grooves is not more than 2.1 μm. 2. The laser-scribed grain-oriented silicon steel resistant to stress-relief annealing of claim 1 , wherein the heights of the spatters do not exceed 2 μm, and the proportion of spatters per unit area in the etch-free regions between adjacent linear grooves does not exceed 2.5%. 3. The laser-scribed grain-oriented silicon steel resistant to stress-relief annealing of claim 1 , wherein the line roughness Ra of a center line in the bottom of the linear grooves is not more than 0.52 μm. 4. The laser-scribed grain-oriented silicon steel resistant to stress-relief annealing of claim 1 , wherein the linear grooves are approximately triangular, trapezoidal, semi-circular or elliptical. 5. The laser-scribed grain-oriented silicon steel resistant to stress-relief annealing of claim 1 , wherein an angle between the linear grooves and the direction of rolling the silicon steel into a steel plate is 0 to 30°. 6. The laser-scribed grain-oriented silicon steel resistant to stress-relief annealing of claim 1 , wherein the linear grooves have a width of 5 to 300 μm and a depth of 5 to 60 μm, and a space between adjacent linear grooves is 1 to 10 mm. 7. A method for manufacturing the laser-scribed grain-oriented silicon steel resistant to stress-relief annealing of claim 1 , comprising steps of smelting, continuous casting, hot rolling, single cold rolling, or double cold rolling with intermediate annealing, decarburization annealing including applying MgO separator on a surface of the silicon steel, high-temperature annealing, and forming a finished grain-oriented silicon steel by hot stretching, temper rolling and annealing, wherein the method further comprises laser-etching, which is performed before the decarburization annealing, or before or after the hot stretching, temper rolling and annealing; the laser-etching comprises the following steps: 1) forming a protective film on a surface of the grain-oriented silicon steel; 2) laser-etching a surface of the grain-oriented silicon steel to form a series of linear grooves perpendicular to or at an angle to the direction of rolling the silicon steel into a steel plate; 3) brushing the surface of the grain-oriented silicon steel to remove the protective film, and drying, thereby producing the laser-scribed grain-oriented silicon steel resistant to stress-relief annealing of claim 1 . 8. The method for manufacturing the laser-scribed grain-oriented silicon steel resistant to stress-relief annealing of claim 7 , wherein the protective film is formed by a metal oxide powder, and has a moisture content of between 0.3 wt % and 5.5 wt %. 9. The method for manufacturing the laser-scribed grain-oriented silicon steel resistant to stress-relief annealing of claim 7 , wherein the protective film has a thickness of between 1.0 μm and 13.0 μm. 10. The method for manufacturing the laser-scribed grain-oriented silicon steel resistant to stress-relief annealing of claim 8 , wherein the metal oxide powder is water-insoluble, and is a single powder or a combination of several powders, and the proportion of particles having a particle diameter of 500 μm or more in the powder(s) is 10% by volume or less. 11. The method for manufacturing the laser-scribed grain-oriented silicon steel resistant to stress-relief annealing of claim 8 , wherein the metal oxide powder is one or more of an alkaline earth metal oxide, Al 2 O 3 , ZnO or ZrO. 12. The method for manufacturing the laser-scribed grain-oriented silicon steel resistant to stress-relief annealing of claim 7 , wherein the laser in the laser-etching step has a power density I of not less than 1.0×10 6 W/cm 2 , and an average energy density e 0 of between 0.8 J/mm 2 and 8.0 J/mm 2 , and a ratio of the average energy density to the thickness of the protective film of between 0.6 and 7.0. 13. A method for producing the laser-scribed grain-oriented silicon steel resistant to stress-relief annealing of claim 1 , comprising steps of smelting, continuous casting, hot rolling, single cold rolling, or double cold rolling with intermediate annealing, decarburization annealing, applying MgO separator on a surface of a steel plate produced above, high-temperature annealing, forming a finished oriented silicon steel by hot stretching, temper rolling, annealing and applying an insulating coating, wherein laser-etching is performed after the decarburization annealing to form a series of linear grooves perpendicular to or at an angle to the direction of rolling the silicon steel into a steel plate, on a surface of the grain-oriented silicon steel. 14. The method for manufacturing the laser-scribed grain-oriented silicon steel resistant to stress-relief annealing of claim 13 , wherein a laser-generating pump source used in the laser-etching step is one or more of a CO 2 laser, a solid laser, and a fiber-optic laser, and laser is continuous or pulsed. 15. The method for manufacturing the laser-scribed grain-oriented silicon steel resistant to stress-relief annealing of claim 7 , wherein a laser-generating pump source used in the laser-etching step is one or more of a CO 2 laser, a solid laser, and a fiber-optic laser, and laser is continuous or pulsed.