Metal matrix composite material for additive manufacturing of downhole tools

What is claimed is: 1. A downhole cutting tool, comprising: a tool body including a cutting element or cutting element pocket thereon, at least a portion of the tool body including a metal matrix composite formed from spherical cast carbide particles dispersed in a continuous metal matrix formed from a metal binder, wherein: a density ratio of spherical cast carbide particles to the metal binder is between 1.7 and 2.1; the spherical cast carbide particles compose between 30 wt % and 40 wt % of the metal matrix composite; a particle size of the spherical cast carbide particles is between 20 and 150 microns; and the metal binder makes up at least 75 vol % of the metal matrix composite, wherein the metal matrix composite has a transverse rupture strength greater than 150 ksi and a fracture toughness over 22 ksi*in 0.5 . 2. The downhole cutting tool of claim 1 , the metal binder consisting essentially of transition metals or transition metal alloys. 3. The downhole cutting tool of claim 2 , the metal binder consisting essentially of iron, nickel, copper, or alloys thereof. 4. The downhole cutting tool of claim 1 , the at least a portion of the tool body including an attached tool body segment. 5. The downhole cutting tool of claim 1 , the at least a portion of the tool body including the metal matrix composite being formed using a high energy fusion additive manufacturing process. 6. The downhole cutting tool of claim 1 , the metal matrix composite having an erosion rate of less than 0.1 g/lb. sand. 7. The downhole cutting tool of claim 1 , the metal matrix composite having a transverse rupture strength greater than 180 ksi and a fracture toughness over 25 ksi*in 0.5 . 8. A downhole cutting tool, comprising: a tool body including a cutting element or cutting element pocket thereon, at least a portion of the tool body including a metal matrix composite formed from hard particles dispersed in a continuous metal matrix formed from a metal binder, wherein: a density ratio of the hard particles to the metal binder is between 0.5 and 1.2; a particle size of the hard particles is between 20 to 150 microns; and the hard particles make up between 26 vol % and 54 vol % of the metal matrix composite, wherein the metal matrix composite has a transverse rupture strength greater than 150 ksi and a fracture toughness over 22 ksi*in 0.5 . 9. The downhole cutting tool of claim 8 , the hard particles having a density of less than 5 g/cm 3 . 10. The downhole cutting tool of claim 9 , the metal binder consisting essentially of transition metals or transition metal alloys. 11. The downhole cutting tool of claim 10 , the metal binder consisting essentially of iron, nickel, copper, or alloys thereof. 12. The downhole cutting tool of claim 11 , the metal binder consisting essentially of copper alloys. 13. The downhole cutting tool of claim 8 , the metal binder including titanium, and the density ratio being between 0.85 and 1.15. 14. The downhole cutting tool of claim 8 , the at least a portion of the tool body including the metal matrix composite being formed using a high energy fusion additive manufacturing process. 15. A downhole cutting tool, comprising: a tool body including a cutting element or cutting element pocket thereon, at least a portion of the tool body including a metal matrix composite formed from hard particles dispersed in a continuous metal matrix formed from a metal binder, wherein: a density ratio of hard particles to the metal binder is between 0.9 and 1.1; the hard particles make up between 30 wt % and 40 wt % of the metal matrix composite; a particle size of the hard particles is between 20 to 150 microns; the hard particles are a transition metal carbide or boride including SiC, TiB 2 , or other borides; and the metal binder consists essentially of Al, Ni, Si, Ti, B, or alloys thereof, wherein the metal matrix composite has a transverse rupture strength greater than 150 ksi and a fracture toughness over 22 ksi*in 0.5 . 16. The downhole cutting tool of claim 15 , the continuous metal matrix consisting essentially of transition metals or transition metal alloys. 17. The downhole cutting tool of claim 16 , the continuous metal matrix consisting essentially of titanium, iron, nickel, copper, or alloys thereof. 18. The downhole tool of claim 15 , the continuous metal matrix consisting essentially of iron or nickel base alloys containing an alloying component that reduces the melting temperature of the metal binder. 19. The downhole cutting tool of claim 15 , the continuous metal matrix having a melting point below 1,200° C. 20. The downhole cutting tool of claim 15 , the at least a portion of the tool body including the metal matrix composite being formed using a high energy fusion additive manufacturing process. 21. A downhole cutting tool, comprising: a tool body including a cutting element or cutting element pocket thereon, at least a portion of the tool body including a metal matrix composite formed from metallic hard particles dispersed in a continuous metal matrix formed from a metal binder, wherein: a density ratio of the metallic hard particles to the metal binder is between 0.5 and 1.2; the metallic hard particles make up between 26 vol % and 54 vol % of the metal matrix composite; the metallic hard particles have a hardness between 500 and 800 VHN, and a density that is less than 9 g/cm 3 ; a particle size of the metallic hard particles is 20 and 150 microns; and the continuous metal matrix surrounding the metallic hard particles has a hardness that is less than 500 VHN, wherein the metal matrix composite has a transverse rupture strength greater than 150 ksi and a fracture toughness over 22 ksi*in 0.5 . 22. The downhole cutting tool of claim 21 , the at least a portion of the tool body including the metal matrix composite being formed using a high energy fusion additive manufacturing process. 23. The downhole cutting tool of claim 21 , the metallic hard particles having a melting point below 1,700° C.