Polishing method for optical elements

What is claimed is: 1. A partially surface-contacted polishing method for spherical or planar optical elements, comprising steps of: 1) forming a polishing device ( 100 ) by pressing a polishing disc connecting rod ( 11 ) into a polishing disc fixing port ( 21 ) hollowed at a top of a cylinder polishing disc base ( 2 ), and fixing with screws ( 4 ), in such a manner that no interval exists; 2) sticking a polishing film ( 3 ) on an arc-portion at a bottom of the cylinder polishing disc base ( 2 ) with a binding agent, and trimming a curvature radius of the polishing film ( 3 ) after the binding agent is solidified; 3) during trimming, installing the polishing device ( 100 ) on a work piece shaft of a numerical-controlled device, and installing a trimming grinding wheel ( 5 ) on a tool shaft of the numerical-controlled device; trimming the polishing film ( 3 ) by point-contacting between the trimming grinding wheel ( 5 ) and the polishing film ( 3 ), in such a manner that the curvature radius of the polishing film ( 3 ) is identical to curvature radius of the spherical or the planar optical element in value; and 4) installing the polishing device ( 100 ) on the tool shaft of the numerical-controlled device, and installing an unprocessed optical element ( 6 ) on the work piece shaft of the numerical-controlled device during polishing, firstly inputting surface forming parameters of the unprocessed optical element ( 6 ) and size parameters of the polishing device ( 100 ) into a processing software, and generating a numerical-controlling file, so as to precisely position the polishing device ( 100 ) and the unprocessed optical element ( 6 ) by the numerical-controlled device, in such a manner that a curvature center of the polishing film ( 3 ) coincides with a curvature center of the unprocessed optical element ( 6 ) at any processing position; a surface of the polishing device ( 100 ) forms ring-surface-contact with a surface of the unprocessed optical element ( 6 ) for polishing. 2. The partially surface-contacted polishing method, as recited in claim 1 , wherein during utilization, the polishing device ( 100 ) is installed on the tool shaft of the numerical-controlled device; the polishing device ( 100 ) rotates around an axis of the tool shaft and swings around a swinging center B of the tool shaft; the polishing device ( 100 ) is also movable along a horizontal direction; the unprocessed optical element ( 6 ) is installed on the work piece shaft of the numerical-controlled device; the unprocessed optical element ( 6 ) rotates around an axis of the work piece shaft and is movable along a vertical direction; a moving speed of the cylinder polishing disc base ( 2 ) and a rotation speed of the unprocessed optical element ( 6 ) are controlled by the numerical-controlled device at each processing position: wherein a curvature radius of the bottom, which is arc-shaped, of the cylinder polishing disc base ( 2 ) is r 1 ; before utilization, the polishing film ( 3 ) stuck on the arc portion of the cylinder polishing disc base ( 2 ) is trimmed, in such a manner that a surface section curve thereof is a precise arc with a curvature radius of r 2 ; a height of the polishing film ( 3 ) is h, which satisfies r 2 =r 1 +h. 3. A line-contacted polishing method for spherical or planar optical elements, comprising steps of: 1) forming a polishing device ( 100 ) by pressing a polishing disc connecting rod ( 11 ) into a polishing disc fixing port ( 21 ) hollowed at a top of a profiling polishing disc base ( 7 ), and fixing with screws ( 4 ), in such a manner that no interval exists therebetween; 2) sticking a polishing film ( 3 ) on a bottom of the profiling polishing disc base ( 7 ) with a binding agent, and trimming a curvature radius of the polishing film ( 3 ) after the binding agent is solidified; wherein the polishing film ( 3 ) is stuck on a revolution surface of the profiling polishing disc base ( 7 ), and a sticking height ensures that the polishing film ( 3 ) is fixedly stuck and covers the whole revolution surface; 3) during trimming, installing the polishing device ( 100 ) on a work piece shaft of a numerical-controlled device, and installing a trimming grinding wheel ( 5 ) on a tool shaft of the numerical-controlled device; trimming the polishing film ( 3 ) by point-contacting between the trimming grinding wheel ( 5 ) and the polishing film ( 3 ); and 4) installing the polishing device ( 100 ) on the tool shaft of the numerical-controlled device, and installing an unprocessed optical element ( 6 ) on the work piece shaft of the numerical-controlled device; during polishing, firstly inputting surface forming parameters of an aspheric surface of the unprocessed optical element ( 6 ) and size parameters of the polishing device ( 100 ) into a processing software, and generating a numerical-controlling file, so as to control the polishing device ( 100 ) and the unprocessed optical element ( 6 ) by the numerical-controlled device, in such a manner that the polishing device ( 100 ) line-contacts with the unprocessed optical element ( 6 ) at any processing position. 4. The line-contacted polishing method, as recited in claim 3 , wherein during utilization, the polishing device ( 100 ) is installed on the tool shaft of the numerical-controlled device; the polishing device ( 100 ) rotates around an axis of the tool shaft and swings around a swinging center B of the tool shaft; the polishing device ( 100 ) is also movable along a horizontal direction; the unprocessed optical element ( 6 ) is installed on the work piece shaft of the numerical-controlled device; the unprocessed optical element ( 6 ) rotates around an axis of the work piece shaft and is movable along a vertical direction; a moving speed of the profiling polishing disc base ( 7 ) and a rotation speed of the unprocessed optical element ( 6 ) are controlled by the numerical-controlled device at each processing position. 5. The line-contacted polishing method, as recited in claim 3 , wherein the profiling polishing disc base ( 7 ) is a solid of revolution, a generating curve thereof is an arc with a curvature radius of r 1 ; a generating curve of the polishing film ( 3 ) after being precisely trimmed is an arc with an curvature radius of r 2 ; and a height of the polishing film ( 3 ) is h, which satisfies r 2 =r 1 +h. 6. A point-contacted polishing method for aspheric optical elements, comprising steps of: 1) forming a polishing device ( 100 ) by pressing a polishing disc connecting rod ( 11 ) into a polishing disc fixing port ( 21 ) hollowed at a top of a spherical polishing disc base ( 8 ), and fixing with screws ( 4 ), in such a manner that no interval exists; 2) sticking a polishing film ( 3 ) on an arc-portion at a bottom of the spherical polishing disc base ( 8 ) with binding agent, and trimming a curvature radius of the polishing film ( 3 ) after the binding agent is solidified; 3) during trimming, installing the polishing device ( 100 ) on a work piece shaft of a numerical-controlled device, and installing a trimming grinding wheel ( 5 ) on a tool shaft of the numerical-controlled device; trimming the polishing film ( 3 ) by point-contacting between the trimming grinding wheel ( 5 ) and the polishing film ( 3 ); and 4) during utilization, installing the polishing device ( 100 ) on the tool shaft of the numerical-controlled device, and installing an unprocessed optical element ( 6 ) on the work piece shaft of the numerical-controlled device; during polishing, firstly inputting surface forming parameters of an aspheric surface of the unprocessed optical element ( 6 ) and size parameters of the polishing device ( 100 ) into a processing software, and generating a numerical-controlling file, so as to control the polishing device ( 100 ) and the unprocessed optic