Year1
- 成型尺寸:
- 250*250*300mm
- 含氧量:
- 100ppm
- 精度:
- 0.05-0.2mm
- molding size ** laser power watts / watts focused spot / - micron suitable for various production needs and research and development needs.
The molding process is to first create the D data of the required target parts and use layering software to slice the D data into micron-thick slices. This is regarded as D data and converted into equipment galvanometer scanning data. The equipment uses this data. The target part is prepared by using a laser to melt the metal powder during galvanometer scanning and superimposing points into lines and surfaces into a body.
The specific parameters of the product are as follows:
Equipment model:
molding size**
laser power/
printing layer thickness
printing line width
line Scanning speed/
Linear forming speed
Oxygen concentration
Precision optical components: Planar focusing lens high-speed scanner
Printing powder materials: stainless steel, cobalt-chromium alloy, titanium, tool steel, copper Alloys, aluminum and some rare metals, etc. In the mold industry, the cooling system of injection molds has a great impact on production efficiency and product quality. The accompanying cooling can not only improve the cooling efficiency, but also allow the product to be cooled quickly and evenly, so that the temperature of the mold can be well controlled and the quality of the product can also be greatly improved. The design of traveling cooling needs to avoid the restrictions of ejector pins, etc. and arrange it more uniformly and closer to the mold wall. When the product is complex, it is difficult to achieve traveling cooling or only partial traveling cooling can be achieved by traditional manufacturing processes. Through metal 3D printing, the complexity requirements of the products to be printed are almost zero. It can print a perfect accompanying cooling system according to the design needs.
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