Spatter reduction laser scanning strategy in selective laser melting

The invention claimed is: 1. An additive manufacturing apparatus for producing a product, comprising: a PC controller, computer aided design software in said PC controller, a computer aided design model of the product produced by said computer aided design software, a multiplicity of 2-dimensional data files with each 2-dimensional data file defining a planar cross section through the computer aided design model, an additive manufacturing device, a target surface in said additive manufacturing device, heat-fusible powder particles at said target surface, an energetic beam source in said additive manufacturing device, an energetic beam produced by said energetic beam source for producing a sintering run on said heat-fusible powder particles wherein said energetic beam source is adapted to control said energetic beam in said sintering run to cause said particles to build bridges between each other to hold them in place and to causes said heat-fusible powder particles to build bridges with said target surface, and an energetic beam produced by said energetic beam source for producing a melting run on said heat-fusible powder particles and melt said heat-fusible powder particles in place and form layers of the product. 2. The additive manufacturing apparatus of claim 1 wherein said energetic beam source for producing a sintering run on said heat-fusible powder particles causes said heat-fusible powder particles to adhere to each other but not deform. 3. The additive manufacturing apparatus of claim 1 wherein said energetic beam source for producing a sintering run on said heat-fusible powder particles causes said heat-fusible powder particles to adhere to said target surface. 4. The additive manufacturing apparatus of claim 1 wherein said energetic beam source for producing a sintering run on said heat-fusible powder particles is a laser. 5. The additive manufacturing apparatus of claim 1 wherein said energetic beam source for producing a sintering run on said heat-fusible powder particles is an electron beam. 6. The additive manufacturing apparatus of claim 1 wherein said energetic beam source for producing a melting run on said heat-fusible powder particles is a laser. 7. The additive manufacturing apparatus of claim 1 wherein said energetic beam source for producing a melting run on said heat-fusible powder particles is an electron beam. 8. An additive manufacturing apparatus for producing a product, comprising: a PC controller, computer aided design software in said PC controller, a computer aided design model of the product produced by said computer aided design software, a multiplicity of 2-dimensional data files with each 2-dimensional data file defining a planar cross section through the computer aided design model, an additive manufacturing device, a target surface in said additive manufacturing device; a first multiplicity of heat-fusible powder particles at said target surface; an energetic beam source in said additive manufacturing device; a first sintering energetic beam produced by said energetic beam source, said first sintering energetic beam directed to said first multiplicity of heat-fusible powder particles for producing a sintering run on said first multiplicity of heat-fusible powder particles wherein said energetic beam source is adapted to control said first sintering energetic beam in said sintering run to cause said first multiplicity of particles to build bridges between each other to hold them in place and to causes said first multiplicity of heat-fusible powder particles to build bridges with said target surface; a first melting energetic beam produced by said energetic beam source, said first melting energetic beam directed to said first multiplicity of heat-fusible powder particles for producing a melting run on said heat-fusible powder particles and melt said first multiplicity of heat-fusible powder particles and form a first layer of the product; a second multiplicity of heat-fusible powder particles at said target surface; a second sintering energetic beam produced by said energetic beam source, said second sintering energetic beam directed to said second multiplicity of heat-fusible powder particles for producing a sintering run on said second multiplicity of heat-fusible powder particles wherein said energetic beam source is adapted to control said second sintering energetic beam in said sintering run to cause said second multiplicity of particles to build bridges between each other to hold them in place and to causes said second multiplicity of heat-fusible powder particles to build bridges with said first layer of the product; a second melting energetic beam produced by said energetic beam source, said second melting energetic beam directed to said heat-fusible powder particles for producing a melting run on said second heat-fusible powder particles and form a second layer of the product; additional multiplicities of heat-fusible powder particles at said target surface; additional sintering energetic beams produced by said energetic beam source, said additional sintering energetic beams directed to said additional multiplicities of heat-fusible powder particles for producing a sintering run on said additional multiplicities of heat-fusible powder particles wherein said energetic beam source is adapted to control said additional sintering energetic beams in said sintering run to cause said additional multiplicities of particles to build bridges between each other to hold them in place and to causes said additional multiplicities of heat-fusible powder particles to build bridges with additional layer of the product; and additional melting energetic beams produced by said energetic beam source, said additional melting energetic beams directed to said additional multiplicities of heat-fusible powder particles for producing a melting run on said additional multiplicities of heat-fusible powder particles and melt said additional multiplicities of heat-fusible powder particles and form the product. 9. The additive manufacturing apparatus of claim 8 wherein said first sintering energetic beam produced by said energetic beam source causes said first multiplicity of heat-fusible powder particles to adhere to each other but not deform and causes said first multiplicity of heat-fusible powder particles to build bridges between each other. 10. The additive manufacturing apparatus of claim 8 wherein said first sintering energetic beam produced by said energetic beam source causes said heat-fusible powder particles to adhere to said target surface. 11. The additive manufacturing apparatus of claim 8 wherein said energetic beam source is a laser. 12. The additive manufacturing apparatus of claim 8 wherein said energetic beam source is a laser and wherein said first energetic beam produced by said energetic beam source is a laser beam. 13. The additive manufacturing apparatus of claim 8 wherein said energetic beam source is an electron beam gun. 14. The additive manufacturing apparatus of claim 8 wherein said energetic beam source is an electron beam gun and wherein said first energetic beam produced by said first energetic beam source is an electron beam.