Lattice Based Wing
Method of Manufacturing SLM
Material SS316L
Material Properties High Tensile Strength, Excellent Corrosion Resistance
Part Weight (g) Wing (Cut Section) 76g Wing (Exposed Structure Section) 326g
Part Density (g/cm3) 6.99 g/cm3 7.43 g/cm3
Cost (PKR) 24,500/- 90,000/-
Benefits of using 3D Printing/Additive Manufacturing Enables the manufacturing of lightweight and high strength to weight ratio components for aerospace applications.
PIAM 3D

PIAM 3D

Fuel Injector
Method of Manufacturing SLM
Material SS316L
Material Properties High Tensile Strength, Excellent Corrosion Resistance, High Toughness and Impact Resistance
Part Weight (g) 12g
Part Density (g/cm3) 7.4 g/cm3
Cost (PKR) 3,500/-
Benefits of using 3D Printing/Additive Manufacturing Component featuring an internal cavity which cannot be produced using conventional manufacturing method.
PIAM 3D

Turbine Blade with Inner Cooling Channels
Method of Manufacturing SLM
Material SS316L
Material Properties High Tensile Strength, Excellent Corrosion Resistance
Part Weight (g) 105g
Part Density (g/cm3) 7.55 g/cm3
Cost (PKR) Eye Implant
10,500/-
Benefits of using 3D Printing/Additive Manufacturing Fabrication of internal cooling channels of turbine blade, which cannot be manufactured with conventional machining.
PIAM 3D

Topology Optimized Aircraft Bracket
Method of Manufacturing FDM
Material ABS
Material Properties High Toughness and Impact Strength.
Part Weight (g) Solid 47g Optimized 27g
Part Density (g/cm3) 0.31 g/cm3 0.71 g/cm3
Cost (PKR) 4,500/- 2,500/-
Benefits of using 3D Printing/Additive Manufacturing Femoral implant manufactured using AM with porous structure for tissue ingrowth. AM enables customized fit, bone integration and improved healing.
PIAM 3D

Load Bearing Composite Part
Method of Manufacturing Composite-FDM
Material CF-Onyx
Material Properties High Strength
Part Weight (g) 8g
Part Density (g/cm3) 1.02 g/cm3
Cost (PKR) 10,000/-
Benefits of using 3D Printing/Additive Manufacturing Utilizing the composite FDM printer for the production of load-bearing components offer the advantage of lightweight high-performance parts with enhanced strength and durability due to fiber-reinforced materials.
PIAM 3D

Composite Mold
Method of Manufacturing FDM
Material PC
Material Properties High Tensile Strength, Excellent Corrosion Resistance
Part Weight (g) 552g
Part Density (g/cm3) 0.21 g/cm3
Cost (PKR) 71,000/-
Benefits of using 3D Printing/Additive Manufacturing AM enables manufacturing of precise, durable and lightweight molds for parts with complex geometry, reducing both manufacturing cost and time.
Time Made quickly through 3D printing within a day, unlike conventional methods that could take weeks.
PIAM 3D

PIAM 3D

Shoe Insole
Method of Manufacturing SLM
Material IN718
Material Properties High Tensile Strength, High Fatigue Resistance, Excellent Corrosion Resistance
Part Weight (g) 810g
Part Density (g/cm3) 8.06 g/cm3
Cost (PKR) 205,000/-
Benefits of using 3D Printing/Additive Manufacturing Machining a part with intricate blade design in IN718 requiring high accuracy is extremely challenging, but additive manufacturing provided near-net shape fabrication of NGV with reduced material wastage and lead time while maintaining high dimensional accuracy.
PIAM 3D