Method and system for dynamically following laser cutting with magnetic belt

The invention claimed is: 1. A system for enabling magnetic belts to follow laser-cutting dynamically, characterized in that, the system comprises: a processing station; two sets of magnetic belts arranged respectively on a feeding side and a discharging side of the processing station, with each magnetic belt of the sets being able to be stretched and retracted and the distance between magnetic belts being adjustable; a laser-cutting unit provided at the processing station and comprising at least one laser cutter and a laser cutting head; a feeding robot and a tooling of the feeding robot, which are arranged on an outer side of the set of magnetic belts on the feeding side of the processing station, with a pile of blocks being arranged on the opposite side and a block edge measuring device being installed at the tooling; a discharging robot and a tooling of the discharging robot, which are arranged on an outer side of the set of magnetic belts on the discharging side of the processing station, with a pile of sheets being arranged on the opposite side; a scrap conveyor device arranged on the side of the processing station perpendicular to the feeding direction; a dust treating device and a real-time measurement device for the cutting of the blocks, which are provided at the processing station; a position detecting device in front of the pile of sheets and a transfer location arranged at the position of the set of magnetic belts on the discharging side outside the processing station; and a cutting control system, which is respectively connected to the sets of magnetic belts, the laser-cutting unit, the feeding robot, the discharging robot, the scrap conveyor device, the dust treating device, the real-time measurement device and the position detecting device for the sheets, so that the units and devices communicate with each other to establish an associative operation control and the stretching and retraction of the magnetic belts follow the laser cutting head. 2. The system for enabling magnetic belts to follow laser-cutting dynamically according to claim 1 , characterized in that, the set of magnetic belts comprises: conveyor motors for respectively controlling the sets of magnetic belts on the feeding side and the discharging side, and a control module for the conveyor motors; a plurality of magnetic belts, each comprising: at least one independently controllable electromagnetic module; stretching and retraction motors for respectively controlling the stretching and retraction of the magnetic belts, and a control module for the stretching and retraction motors; and width motors for controlling the distance between the magnetic belts, and a control module for the width motors. 3. The system for enabling magnetic belts to follow laser-cutting dynamically according to claim 1 , characterized in that, the block edge measuring device comprises a range finder for detecting the position of the pile of blocks and two photoelectric switches. 4. The system for enabling magnetic belts to follow laser-cutting dynamically according to claim 1 , characterized in that, the real-time measurement device for the cutting of the blocks comprises: two cameras for measuring the coordinates of a workpiece; and two cameras for visual detection and identification of falling scraps and for visual detection and identification of separation after cutting. 5. The system for enabling magnetic belts to follow laser-cutting dynamically according to claim 1 , characterized in that, the position detecting device for the sheets in front of the pile of sheets comprises a camera installed above the transfer location for detecting the position of the sheets in the transfer location. 6. A laser-cutting method for the system for enabling magnetic belts to follow laser-cutting dynamically according to claim 1 , characterized in that, a) first blocks of a determined length and width are obtained according to the graphic design of sheets; b) the distance of the magnetic belts on the feeding side is pre-adjusted to a fixed distance and a fixed stretching/retraction position according to the width of the blocks and the cutting profile so as to form a feeding start position for the set of magnetic belts on the feeding side, and at the same time the magnetic belts on the discharging side is pre-adjusted to a fixed distance and a fixed stretching/retraction position according to the width of the blocks and the cutting profile so as to form a discharging start position for the set of magnetic belts on the discharging side; c) after obtaining the blocks of the determined length and width, the blocks are placed on the piles of blocks, the block edge measuring device measures the position of the blocks in the piles, then the tooling of the feeding robot picks up a piece of block and places same on the set of magnetic belts on the feeding side, and the set of magnetic belts on the feeding side takes the block to the processing station for laser cutting; d) the position of the block entering the laser-cutting area of the processing station is measured rapidly by the real-time measurement device, so as to correct the coordinates of the origin and the angle of a workpiece coordinate system in the control system before the cutting operation, and when the measurement is complete, the laser-cutting head cuts the block in a planned path according to a profile to be processed; during the cutting, the magnetic belts on the feeding side and the discharging side are adjusted synchronously dynamically according to the cutting path and the stretching/retraction adjustment amount is determined by the profile to be cut, wherein the synchronous dynamic adjustment is effected by sending a signal by the cutting control system to the control module for the stretching and retraction of the magnetic belt, and during the adjustment, the magnetic belts need to avoid a slit cut during the cutting procedure, in order to prevent the laser from penetrating the blocks and making contact with any of the magnetic belts; the magnetic belts on the feeding side and the discharging side at the position corresponding to a cut profile can be stretched or retracted for stabilising and supporting the sheets being processed while fulfilling the needs of material discharging and receiving on the discharging side; during the cutting procedure, as regards the scraps formed, a signal is generated in the cutting control system and transmitted to the real-time measurement device for detecting and identifying the falling of the scraps in real time; when the cutting procedure is complete, the cutting control system sends a signal for carrying out a detection of all the cut profile by the real-time measurement device for the cutting of the blocks, so as to determine the separation of the processed sheets and the blocks; e) when the sheets are processed, the set of magnetic belts on the feeding side is at a feeding end location and the set of magnetic belts on the discharging side is at a discharging end location; the processed sheets enter an outputting state at the discharging end location on the set of magnetic belts on the discharging side and is output to the transfer location, and at the same time, the sets of magnetic belts on the feeding side and the discharging side are stretched or retracted back to the start positions again, and a second piece of block is sent by means of the set of magnetic belts on the feeding side to the processing station for laser cutting so as to perform the cyclic processing of feeding, cutting and discharging; and f) before transferring the sheets, the camera of the position detecting device for the sheets detects the position of the sheets, feeds the position of the sheets back to the discharging robot for correcting its posture, and then the to