High intensity multi direction FDM 3D printing method for stereo vision monitoring

What is claimed is: 1. A high-intensity multi-directional fused-deposition-modeling (FDM) 3D printing method for stereo vision monitoring, comprising the following steps: dividing a model into several parts, each part has a different printing direction, and a latter printed part is supported by a previously printed part and a printing platform; printing the several parts in a predetermined order, wherein each part contains multiple layers and is printed layer by layer; after each part is printed, rotating the printed part to change the printing direction; after rotating the printed part, scanning, with a 3D scanner, a section of the printed part, on which section a next part is to be printed, based on the scanned images: calculating an error between a section center position obtained by the scanning and a section center position of the model, and correcting the error in real time to meet printing accuracy requirements; calculating an error between a section center position obtained by the scanning and a section center position of the model, and correcting the error in real time to meet printing accuracy requirements; determining a world coordinate system using three sticking mark points on the printing platform for marking positions of origin, X axis, and Y axis (OXY); calculating coordinate of the center position (x c , y c , z c ) after rotation based on the model; analyzing a shape of the section to obtain a minimum bounding rectangle of the section, and a size of the rectangle is x*y; analyzing point cloud data in the world coordinate system to select all points whose ordinate is within a height range of section deviation 10°, the points whose ordinates meet the condition z c −½×max(x,y)×sin 10°≤z≤z c +½×max(x,y)×sin 10° are recorded; applying K-means clustering to the selected points: the selected points are projected on a plane, and points with a distance less than 0.1 mm are clustered into one group according to a distance relationship between points; the group with most points is the section point cloud data corresponding to the section; after the section point cloud data is selected, the section point cloud data is fitted into a fitted plane where the section is located, and a normal vector of the section is obtained; performing angle error correction in response to a correction angle between the normal vector of the section and a vertical vector being greater than 0.5°, otherwise continuing to print; wherein, when calculating the correction angle, a current position of a rotation axis is calculated according to a relationship between the normal vector of the section and the rotation axis, and a new space rectangular coordinate system is established with the rotation axis as a coordinate axis; then coordinates of the normal vector of the section and the vertical vector in the new coordinate system are calculated, and a rotation angle is decomposed into a coordinate axis of the new coordinate system to calculate the correction angle; wherein, during printing first N layers of a part, a light spot is produced by a laser head for heating print material of the first N layers, a heating temperature is a glass transition temperature of the print material, a print extrusion head moves along a printing path and is aligned with the light spot which moves with the print extrusion head. 2. The method according to claim 1 , wherein, addition to a multi axis printing system, the method also works with a stereo vision system and a CO2 laser heating system. 3. The method according to claim 1 , wherein N is taken as 5 , so that a connection surface between adjacent parts can bear a tensile force greater than 1400N. 4. The method according to claim 1 , wherein two laser heads are used to produce two light spots, one light spot is positioned upstream of the print extrusion head, the other light spot is positioned downstream of the print extrusion head along the printing path, and the radius of the light spots is less than 5 mm. 5. The method according to claim 1 , wherein the printing accuracy requirements include that: position accuracy is 0.1 mm and a correction threshold setting in the angle error correction is less than 0.5°; wherein in response to calculated correction angle being less than 0.5°, no adjustment is made; in response to calculated correction angle being greater than 0.5°, make real time feedback and adjustment. 6. The method according to claim 1 , wherein a radius of the light spot is larger than 5 mm and one laser head is used to produce the light spot, the print extrusion head is aligned with a center of the light spot. 7. The method according to claim 1 , wherein a thickness of each of the multiple layers is 0.2 mm.