If you are looking for high-quality products, please feel free to contact us and send an inquiry, email: brad@ihpa.net
Metal 3D Printing is a 3D technology that uses metal powders to directly print metal parts. This technology is also called Selective Laser Melting. 3D printed metal powders need to have good plasticity.
Metal powders are used in 3D printers for stainless steel, cobalt chrome alloy, copper alloys, titanium alloys, nickel alloys, and cobalt chromium alloy. Iron base alloy is the largest and most important metal material in engineering technology. It is widely used for the creation of complex structures.
The performance of the final product will depend on the type of metal powder and 3D printing method used.
Stainless-steel powder
Low-cost metal printing materials can be quickly and economically used for small batches of complex industrial components manufacturing.
Aluminium alloy powder
AlSi12Mg is the most commonly used aluminum alloy in metal 3D printers. Aluminosilicate 12 (lightweight additive) is used to create metal powders with excellent thermal properties. Combining silicon and magnesium gives aluminum alloys greater strength and stiffness. They are suitable for thin walls, complex geometry, and applications with high thermal properties. Aluminum alloy is an industry staple due to its low density, high specific strengths, close to or greater than high-quality steel and good plasticity. 3D printing of aluminum alloy has been shown to produce compact parts with small structures, similar to casting, or even better than cast molding parts. The cost of 3D printing can be reduced up to 30%, while the mass can be reduced 22%.
Cobalt chrome alloy powder
It is used for printing all kinds of artificial joints, plastic surgery implants and other dental procedures.
Copper alloy Powder
Copper has excellent thermal conductivity as well as electrical conductivity. It can be used in thermal management applications to combine design degrees for complex internal structures and conformal cool channels.
Titanium alloy powder
It is widely used within the aerospace industry. 3D printing offers many benefits. One example is the ability to replace a solid body with a complex, reasonable structure. The result is a product that is lighter and has better mechanical properties. This will not only reduce costs but also allow for lighter production.
Nickel alloy pulver
Nickel alloy’s oxidation and corrosion resistance make it ideal for harsh environments such as high temperatures and high levels of pressure. To protect the internal nickel alloy from corrosion, the nickel alloy’s surface will undergo heat passivation. Nickel alloys have good mechanical properties across a wide range temperature ranges.
Can powdered materials be used in 3D printing?
3D data can be used to control laser beams of high energy to melt metal matrix locally and then sinter it to form solid parts.
How do you make 3D printing metal powder?
Solid-state reduction, electrolysis and chemical are the most common methods to produce metal powders.
Many manufacturers employ electrolysis or reduction methods to make elemental metal particles. However, they are not suitable in making alloy powders.
Alloy powder can be made using the atomization method.
Another way to make powdered metals is by electrolysis. Different metals can either be made spongy, or powdered by selecting the right electrolyte composition and temperature, concentration, as well as current density. These can then be washed or dried and reduced to annealed, or crushed. This process is used to produce extremely pure metal powder. This method is used to make highly conductive copper powder.
Atomization is a mechanical method of pulverizing the molten steel into pieces smaller than 150mm. According to the classification for crushing metal melt, the atomization process includes the second flow, centrifugal and ultrasonic atomizations, as well as vacuum atomization. These atomization techniques have their own unique characteristics and have been used successfully in industrial production. Water-gas atomization is one of the most preferred industrial methods for making metal powder. It has simple equipment and processes, as well as low energy consumption.
Performance requirements of metal powder for 3D printing
1. Purity
Ceramic inclusions can adversely affect the performance of final products. They also have a high melting points, which makes it difficult to sinter. Powders must not contain ceramic inclusions. You must also control the nitrogen and oxygen levels. Powder preparation is done mainly using the atomization method. The powder is easily oxidized due to its large surface area. This index is required by customers for special applications such as aerospace. The superalloy and titanium alloy powder oxygen contents are 0.007%-0.013% respectively. The oxygen content of stainless steel powder is 0.010%-0.025%.
2. Powder fluidity, loose density
The powder’s fluidity directly influences the uniformity of powder spreading as well as the stability of powder feeding. Powder morphology, bulk density and particle size distribution are all factors that affect the fluidity. The fluidity of powder is determined by how regular and small the particles are. Fluidity of powder increases as a function of particle density and relative density. The fluidity of powder is also reduced by the adsorption gas and water on its surface.
3. Powder particle size distribution
Different 3D printing equipments and forming processes have different requirements for powder size distribution. The most commonly used powder particle sizes in metal 3D printing are between 15-53mm (fine) and 53-105mm (“coarse”). The different energy sources used by metal printers can affect the choice of powder size for 3D printing. Because of the fine focal spot of the laser, printers can melt 15-53mm powder. Layer-by-layer powder is the preferred method for replenishment. However, the powder-laying printer using electron beam as an energy source has a more coarse focal point, making it suitable for melting coarse dust. It can be used for coarse powder between 53 and105mm. As consumables for coaxial powder feeders, powders with particle sizes between 105 to 150mm are possible.
4. Powder morphology
The powder preparation method has a direct impact on the morphology. The shape of powder particles when metal gas or liquid is turned into powder is spherical. Powder particles that are made by aqueous electrolysis are dendritic. Generally speaking, higher sphericity means better fluidity for powder particles. This makes it easier to feed and lay powder during 3D printing.
3D printing metal powder supplier
Technology Co. Ltd. is a trusted global supplier and manufacturer of chemical materials. We have more than 12 years experience in producing super high-quality chemicals.
Send us an inquiry if you’re looking for high-quality 3D printing metal powder. (brad@ihpa.net)
Metal powders are used in 3D printers for stainless steel, cobalt chrome alloy, copper alloys, titanium alloys, nickel alloys, and cobalt chromium alloy. Iron base alloy is the largest and most important metal material in engineering technology. It is widely used for the creation of complex structures.
The performance of the final product will depend on the type of metal powder and 3D printing method used.
Stainless-steel powder
Low-cost metal printing materials can be quickly and economically used for small batches of complex industrial components manufacturing.
Aluminium alloy powder
AlSi12Mg is the most commonly used aluminum alloy in metal 3D printers. Aluminosilicate 12 (lightweight additive) is used to create metal powders with excellent thermal properties. Combining silicon and magnesium gives aluminum alloys greater strength and stiffness. They are suitable for thin walls, complex geometry, and applications with high thermal properties. Aluminum alloy is an industry staple due to its low density, high specific strengths, close to or greater than high-quality steel and good plasticity. 3D printing of aluminum alloy has been shown to produce compact parts with small structures, similar to casting, or even better than cast molding parts. The cost of 3D printing can be reduced up to 30%, while the mass can be reduced 22%.
Cobalt chrome alloy powder
It is used for printing all kinds of artificial joints, plastic surgery implants and other dental procedures.
Copper alloy Powder
Copper has excellent thermal conductivity as well as electrical conductivity. It can be used in thermal management applications to combine design degrees for complex internal structures and conformal cool channels.
Titanium alloy powder
It is widely used within the aerospace industry. 3D printing offers many benefits. One example is the ability to replace a solid body with a complex, reasonable structure. The result is a product that is lighter and has better mechanical properties. This will not only reduce costs but also allow for lighter production.
Nickel alloy pulver
Nickel alloy’s oxidation and corrosion resistance make it ideal for harsh environments such as high temperatures and high levels of pressure. To protect the internal nickel alloy from corrosion, the nickel alloy’s surface will undergo heat passivation. Nickel alloys have good mechanical properties across a wide range temperature ranges.
Can powdered materials be used in 3D printing?
3D data can be used to control laser beams of high energy to melt metal matrix locally and then sinter it to form solid parts.
How do you make 3D printing metal powder?
Solid-state reduction, electrolysis and chemical are the most common methods to produce metal powders.
Many manufacturers employ electrolysis or reduction methods to make elemental metal particles. However, they are not suitable in making alloy powders.
Alloy powder can be made using the atomization method.
Another way to make powdered metals is by electrolysis. Different metals can either be made spongy, or powdered by selecting the right electrolyte composition and temperature, concentration, as well as current density. These can then be washed or dried and reduced to annealed, or crushed. This process is used to produce extremely pure metal powder. This method is used to make highly conductive copper powder.
Atomization is a mechanical method of pulverizing the molten steel into pieces smaller than 150mm. According to the classification for crushing metal melt, the atomization process includes the second flow, centrifugal and ultrasonic atomizations, as well as vacuum atomization. These atomization techniques have their own unique characteristics and have been used successfully in industrial production. Water-gas atomization is one of the most preferred industrial methods for making metal powder. It has simple equipment and processes, as well as low energy consumption.
Performance requirements of metal powder for 3D printing
1. Purity
Ceramic inclusions can adversely affect the performance of final products. They also have a high melting points, which makes it difficult to sinter. Powders must not contain ceramic inclusions. You must also control the nitrogen and oxygen levels. Powder preparation is done mainly using the atomization method. The powder is easily oxidized due to its large surface area. This index is required by customers for special applications such as aerospace. The superalloy and titanium alloy powder oxygen contents are 0.007%-0.013% respectively. The oxygen content of stainless steel powder is 0.010%-0.025%.
2. Powder fluidity, loose density
The powder’s fluidity directly influences the uniformity of powder spreading as well as the stability of powder feeding. Powder morphology, bulk density and particle size distribution are all factors that affect the fluidity. The fluidity of powder is determined by how regular and small the particles are. Fluidity of powder increases as a function of particle density and relative density. The fluidity of powder is also reduced by the adsorption gas and water on its surface.
3. Powder particle size distribution
Different 3D printing equipments and forming processes have different requirements for powder size distribution. The most commonly used powder particle sizes in metal 3D printing are between 15-53mm (fine) and 53-105mm (“coarse”). The different energy sources used by metal printers can affect the choice of powder size for 3D printing. Because of the fine focal spot of the laser, printers can melt 15-53mm powder. Layer-by-layer powder is the preferred method for replenishment. However, the powder-laying printer using electron beam as an energy source has a more coarse focal point, making it suitable for melting coarse dust. It can be used for coarse powder between 53 and105mm. As consumables for coaxial powder feeders, powders with particle sizes between 105 to 150mm are possible.
4. Powder morphology
The powder preparation method has a direct impact on the morphology. The shape of powder particles when metal gas or liquid is turned into powder is spherical. Powder particles that are made by aqueous electrolysis are dendritic. Generally speaking, higher sphericity means better fluidity for powder particles. This makes it easier to feed and lay powder during 3D printing.
3D printing metal powder supplier
Technology Co. Ltd. is a trusted global supplier and manufacturer of chemical materials. We have more than 12 years experience in producing super high-quality chemicals.
Send us an inquiry if you’re looking for high-quality 3D printing metal powder. (brad@ihpa.net)