Hastelloy X/ Gh3536 Nickel-Base Superalloy in 3D Printing/ Laser Cladding

Overview Of 3D Printing Alloy Metal Materials GH3536 Hastelloy X Powder

GH3536 is a high-temperature alloy mainly composed of chromium and molybdenum and containing a high iron content. This alloy powder is particularly suitable for 3D printing because it has excellent oxidation and corrosion resistance, moderate durability, and creep below 900 ℃. These characteristics make GH3536 an ideal choice for manufacturing high-temperature components such as aviation engine combustion chambers, which can operate at 900 ℃ for a long time and even reach 1080 ℃ for a short period.

(3D Printing Alloy Metal Materials GH3536 Hastelloy X Powder)

 

3D Printing Alloy Metal Materials GH3536 Hastelloy X Powder

Features of 3D Printing Alloy Metal Materials GH3536 Hastelloy X Powder

3D Printing Alloy Metal Materials GH3536 Hastelloy X Powder Properties
Other Names	GH3536 Powder
CAS No.	N/A
Compound Formula	N/A
Molecular Weight	N/A
Appearance	Gray metallic solid in various forms (ingot, tubing, pieces, powder)
Melting Point	N/A
Solubility in water	N/A
Density	NA
Purity	N/A
Particle Size	0-20μm, 15-45μm, 15-53μm, 53-105μm, 53-150μm, 105-250μm
Boling point	N/A
Specific Heat	N/A
Thermal Conductivity	N/A
Thermal Expansion	N/A
Young’s Modulus	N/A
Exact Mass	N/A
Monoisotopic Mass	N/A
3D Printing Alloy Metal Materials GH3536 Hastelloy X Powder Metal Health & Safety Information
Safety Warning	N/A
Hazard Statements	N/A
Flashing point	N/A
Hazard Codes	N/A
Risk Codes	N/A
Safety Statements	N/A
RTECS Number	N/A
Transport Information	N/A
WGK Germany	N/A

 Parameter table of 3D Printing Alloy Metal Materials GH3536 Hastelloy X Powder

Chemical composition(weight %)

Type

C

Si

Mn

Ni

Cr

Co

Mo

W

Al

Cu

Ti

P

S

Fe

GH3536

0.05-0.15

≤1.0

≤1.0

Bal.

20.5-23.0

0.5-2.5

8.0-10.0

0.2-1.0

≤0.5

≤0.5

≤0.15

≤0.025

≤0.015

17.0-22.0

 Powder oxygen and nitrogen content

Particle size	O/ppm	N/ppm
15-53 μm	≤400	≤300
45-105 μm	≤300	≤200

Applications Of 3D Printing Alloy Metal Materials GH3536 Hastelloy X Powder

GH3536 (Hastelloy X) high-temperature alloy powder has a wide range of applications in lots of fields when it needs to withstand high temperatures and intense corrosive environments. The following are some of the main application areas of this material:
 Aerospace industry: Due to its excellent high-temperature strength and corrosion resistance, GH3536 is widely used in manufacturing combustion chamber components, gas turbine blades, and other high-temperature components in aircraft engines. These components can maintain stable performance in extremely high temperature and oxidation environments, operating at 900 ℃ for a long time and even reaching 1080 ℃ for a short period. In addition, GH3536 is also used to manufacture structural components for aerospace vehicles, such as rectifiers, structural covers, etc.

 Applications of 3D Printing Alloy Metal Materials GH3536 Hastelloy X Powder

 
Oil and Gas Industry: GH3536 also plays a vital role in the oil and gas industry. Due to its excellent corrosion resistance and high-temperature strength, it is used in manufacturing petroleum extraction equipment, chemical reactors, high-temperature heat exchangers, and pipelines and valves on deepwater drilling platforms.
 Chemical Industry:In the chemical industry, GH3536 can withstand the erosion of various strong acids, alkalis, and salt solutions, including sulfuric acid, hydrochloric acid, and hydrofluoric acid. Therefore, it manufactures chemical reactors, evaporators, extractors, and storage tanks.
 Industrial furnace components:GH3536 is also used to manufacture industrial furnace components such as support rollers, grid plates, ribbons, and radiation tubes.
 Other high-temperature applications: In other fields, GH3536 is also used to manufacture spiral tubes in petrochemical furnaces, high-temperature gas-cooled nuclear reactors, and components that must withstand high temperatures, such as automotive exhaust pipes, exhaust gas treatment devices, and turbochargers.

 

Production Method of 3D Printing Alloy Metal Materials GH3536 Hastelloy X Powder

Gas Atomization

Principle: The molten GH3536 alloy is atomized by high-pressure gas jets. The high-speed gas breaks the molten metal stream into fine droplets, which solidify rapidly to form a metal powder.

Advantages: It can produce powder with a relatively uniform particle size distribution and good sphericity, which is beneficial for 3D printing.

Plasma Atomization

Principle: Plasma technology is used to heat and melt the GH3536 alloy. The molten metal is then atomized by plasma jets. The high temperature and energy of the plasma can ensure complete melting of the alloy and precise control of the atomization process.

Advantages: It can produce powder with high purity and fine particle size, suitable for high-performance 3D printing applications.

Mechanical Alloying

Advantages: It allows for the precise control of the chemical composition and can introduce fine precipitates to improve the powder’s properties. However, it may have issues such as impurity introduction and non-uniformity.terials GH3536 Hastelloy X Powder, please feel free to contact us or click on the needed products to send an inquiry. 

Principle: Elemental powders of the components of GH3536 are mixed and milled in a high-energy

Company Profile

RBOSCHCO is a trusted global chemical material supplier & manufacturer with over 12-year-experience in providing super high-quality chemicals and nanomaterials, including boride powder, nitride powder, graphite powder, sulfide powder, 3D printing powder, etc.The company has a professional technical department and Quality Supervision Department, a well-equipped laboratory, and equipped with advanced testing equipment and after-sales customer service center.If you are looking for high-quality 3D Printing Alloy Metal Ma

ball mill. Through repeated collisions and deformation, the elements are alloyed to form Hastelloy X powder.

 Storage Condition of 3D Printing Alloy Metal Materials GH3536 Hastelloy X Powder

1) Store in a dry environment at room temperature.

2) Avoid damp and high temperature.

3) Use immediately after opening the inner packing bag.

Payment Term

L/C, T/T, Western Union, Paypal, Credit Card etc.

 

 Shipment Term

By sea, by air, by express, as customers request.

 

5 FAQs of 3D Printing Alloy Metal Materials GH3536 Hastelloy X Powder

Q1

Why choose GH3536 Hastelloy X powder for 3D printing?

Answer:GH3536 Hastelloy X powder has been selected as an ideal material for 3D printing due to its excellent high-temperature strength, oxidation resistance, corrosion resistance, and hot working formability. It is particularly suitable for producing components which withstand high temperatures and corrosive environments.

 

Q2

What 3D printing processes are suitable for GH3536 Hastelloy X powder?

Answer:GH3536 is a high-temperature alloy mainly composed of chromium and molybdenum and containing a high iron content. This alloy powder is particularly suitable for 3D printing because it has excellent oxidation and corrosion resistance, moderate durability, and creep below 900 ℃.

 

Q3

What are the performance characteristics of components printed using GH3536 Hastelloy X powder?

Answer:The components printed with GH3536 Hastelloy X powder have excellent high-temperature endurance strength, creep performance, oxidation, and corrosion resistance. These components can maintain stable performance in high temperatures and harsh environments.

 

Q4

Do the GH3536 Hastelloy X powder-printed components require post-processing?

Answer:GH3536 Hastelloy X powder printed components typically require post-processing to optimize their performance and appearance. Post-treatment may include heat treatment, grinding, polishing, etc., to eliminate residual stress, improve material properties, and improve surface quality.

 

Q5

What are the application areas of GH3536 Hastelloy X powder printed components?

Answer:GH3536 Hastelloy X powder printed components are widely used in aerospace, petroleum and natural gas, chemical industries, and other fields. They are used to manufacture high-temperature components, corrosion-resistant equipment, heat exchangers, etc., and must maintain stable performance in high temperatures and harsh environments.