Spatter reduction laser scanning strategy in selective laser melting

The claims are: 1. A method of additive manufacturing for producing a product using a substrate, comprising: disposing a first layer of first heat-fusible particles on the substrate; implementing a first sintering run on said first heat-fusible powder particles that causes said first heat-fusible powder particles to adhere to each other, causes said first heat-fusible powder particles to build bridges between each other and hold them in place, and causes said first heat-fusible powder particles to adhere to said substrate, wherein said step of implementing a first sintering run produces first sintered heat-fusible powder particles; implementing a first melting run on said first sintered heat-fusible powder particles, wherein said step of implementing a first melting run results in said first sintered heat-fusible powder particles being melted and forming a first layer of the product; disposing a second layer of second heat-fusible particles on said first layer of the product; implementing a second sintering run on said second heat-fusible powder particles that causes said second heat-fusible powder particles to adhere to each other, causes said second heat-fusible powder particles to build bridges between each other and hold them in place, and causes said second heat-fusible powder particles to adhere to said first layer of the product, wherein said step of implementing a second sintering run produces second sintered heat-fusible powder particles; implementing a second melting run on said second heat-fusible powder particles, wherein said step of implementing a second melting run results in said second sintered heat-fusible powder particles being melted and forming a second layer of the product; disposing additional layers of additional heat-fusible particles on said second layer of the product; implementing additional sintering runs on said additional heat-fusible powder particles that causes said additional heat-fusible powder particles to adhere to each other, causes said additional heat-fusible powder particles to build bridges between each other and hold them in place, and causes said additional heat-fusible powder particles to adhere to said second layer of the product, wherein said step of implementing additional sintering runs produces additional sintered heat-fusible powder particles; and implementing additional melting runs on said sintered additional heat-fusible powder particles that results in said additional sintered heat-fusible powder particles being melted thereby forming additional layers of the product. 2. The method of additive manufacturing for producing a product using a substrate of claim 1 wherein said step of implementing a first sintering run on said first heat-fusible powder particles comprises implementing a first laser sintering run on said first heat-fusible powder particles. 3. The method of additive manufacturing for producing a product using a substrate of claim 1 wherein said step of implementing a first sintering run on said heat-fusible powder particles comprises implementing a first electron beam sintering run on said first heat-fusible powder particles. 4. The method of additive manufacturing for producing a product using a substrate of claim 1 wherein said step of implementing a first melting run on said first heat-fusible powder particles comprises implementing a first laser melting run on said first heat-fusible powder particles. 5. The method of additive manufacturing for producing a product using a substrate of claim 1 wherein said step of implementing a first melting run on said first heat-fusible powder particles comprises implementing a first electron beam melting run on said first heat-fusible powder particles.