T15 Powder

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T15 Powder

Product	T15 Powder
CAS No.	14807-96-6
Appearance	Grayish or Metallic Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	WC-Co
Density	8.0-8.2g/cm3
Molecular Weight	N/A
Product Codes	NCZ-DCY-358/25

T15 Description:

T15 Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing.

T15 Powder Related Information :

Storage Conditions:

Airtight sealed, avoid light and keep dry at room temperature.

Please contact us for customization and price inquiry

Email: contact@nanochemazone.com

Note: We supply different size ranges of Nano and micron as per the client’s requirements and also accept customization in various parameters.

T15 Powder

T15 powder is a tungsten carbide-cobalt cemented carbide powder that provides an exceptional combination of hardness, strength, and toughness. It contains a high percentage of tungsten carbide along with 15% cobalt as the binder phase.

Overview of T15 Powder

Key properties and advantages of T15 powder:

T15 Powder Properties and Characteristics

Properties	Details
Composition	85% WC with 15% Co binder
Density	13.0-14.5 g/cc
Particle shape	Rounded, multi-faceted
Size range	0.5-15 microns
Hardness	88-93 HRA when sintered
Transverse rupture strength	550-650 MPa

The ultrahard tungsten carbide particles held together in a cobalt matrix make T15 ideal for the most extreme wear and abrasion conditions across industrial, mining, and construction sectors.

T15 Powder Composition

Component	Weight %
Tungsten carbide (WC)	84-86%
Cobalt (Co)	14-16%
Carbon (C)	0.8% max
Oxygen (O)	0.5% max
Iron (Fe)	0.3% max
Nickel (Ni)	0.3% max

Tungsten carbide provides extreme hardness and wear resistance

Cobalt acts as tough and ductile binder holding WC particles together

Carbon and oxygen present as impurities

Trace iron, nickel from raw materials

The optimized WC-Co ratio provides the best combination of hardness, fracture toughness and impact strength needed in wearing applications.

T15 Powder Physical Properties

Property	Values
Density	13.0-14.5 g/cc
Melting point	2870°C (WC) and 1495°C (Co)
Thermal conductivity	60-100 W/mK
Electrical resistivity	25-35 μΩ-cm
Coefficient of thermal expansion	4.5-6.0 x 10^-6 /K
Maximum service temperature	500°C in air

Very high density enables use in compact, miniaturized components

Very low CTE reduces thermal stresses and distortion

Can withstand continuous service up to 500°C

Good thermal conductivity reduces temperature gradients

These properties make T15 suited for severe abrasion and repeated impact force conditions experienced in mining, drilling, and construction environments.

T15 Powder Mechanical Properties

Property	Values
Hardness	88-93 HRA
Transverse rupture strength	550-650 MPa
Compressive strength	5500-6200 MPa
Fracture toughness	10-12 MPa.m^1/2
Young’s modulus	550-650 GPa
Impact strength	350-900 kJ/m2

Extreme hardness provides wear and abrasion resistance

Very high compressive strength withstands crushing forces

Reasonable fracture toughness and impact strength

Hardness and strength determined by WC particle size and distribution

This exceptional combination of hardness, strength and toughness makes T15 suitable for the most severe impaction, abrasion and gouging wear conditions.

T15 Powder Applications

Industry	Example Uses
Mining	Rock drill bits, grit blasting nozzles
Construction	Demolition tools, rock crushers
Manufacturing	Forming dies, metal drawing parts
Oil and gas	Stabilizers, downhole motors
General	Cutting and machining tools

Some specific product uses:

Percussive rock drilling bits, mine boring tools

Highly abrasive slurry pump parts like shafts, impellers

Extrusion dies for brick and ceramic manufacturing

Wear-resistant components in sandblasting equipment

Cutting blades, knives, saw teeth needing extreme hardness

T15’s unparalleled hardness and wear performance make it the top choice for equipment used in the most severe impaction-abrasion conditions across industrial sectors.

T15 Powder Standards

Standard	Description
ISO 513	Classification and application of cemented carbides
ASTM B276	Cobalt-tungsten carbide powders and hard metals
JIS G 4053	Sintered hard metals
GB/T 4661-2006	Chinese standard for cemented carbides

These define:

Chemical composition – Co and WC content

Carbide grain size and powder particle size distribution

Required mechanical properties

Acceptable impurities

Approved production methods like carburization and reduction-diffusion

Meeting these specifications ensures optimal combination of hardness, strength and toughness for maximum wear performance.

T15 Powder Particle Size Distribution

Particle Size	Characteristics
0.5-2 microns	Ultrafine grade provides superfinish
0.5-5 microns	Submicron range enhances toughness
3-15 microns	Most commonly used size for optimal properties

Finer powders increase hardness and finish

Coarser powders improve fracture strength and impact resistance

Particle size distribution is optimized based on service conditions

Both crushed and sintered carbide powders used

Controlling particle size distribution and morphology optimizes final component properties and performance.

T15 Powder Production Method

Method	Details
Carburization and reduction-diffusion	Produces fine spherical powders
Crushing sintered material	Lower cost, irregular angular particles
Milling	Ball milling used for particle size reduction
Spray drying	Granulation and spheroidization process
Degassing	Removes gaseous impurities

Spherical powder morphology provides high packing density

Crushed powders have lower production cost

Milling, spray drying used for particle size control

Degassing optimizes powder purity and sintered microstructure

Automated, high volume production processes result in consistent feedstock optimized for part performance.

T15 Powder Handling and Storage

Recommendation	Reason
Use PPE and ventilation	Prevent exposure to fine particles
Avoid ignition sources	Powder can combust if overheated in air
Follow safe protocols	Reduce health and fire hazards
Use inert atmosphere	Prevent oxidation during powder processing
Store sealed containers	Prevent contamination or absorption

Storage Recommendations

Store in stable containers and ambient temperatures

Limit exposure to moisture, acids, chlorine

Avoid cross-contamination from other powders

Proper precautions preserve powder purity and prevent safety issues during handling and storage.

T15 Powder Testing

Test	Details
Chemical analysis	Verifies composition using ICP, EDX, or XRF
Particle size distribution	Laser diffraction or sedimentation analysis
Powder morphology	SEM imaging of particle shape
Apparent density	Measured as per ASTM B212 standard
Tap density	Density measured after mechanical tapping
Hall flow rate	Determines powder flowability

Testing ensures powder meets required chemical composition, particle characteristics, morphology, density specifications, and flowability per relevant standards.

T15 Powder Pros and Cons

Advantages of T15 Powder

Exceptional hardness, wear resistance, and strength

Withstands high compression without fracturing

Good fracture toughness and impact resistance

Dimensional stability under heavy loads

Resists deformation at elevated temperatures

Enables smaller, lighter components

Limitations of T15 Powder

Difficult to machine after sintering

Not suitable for dynamic bearing applications

Relatively brittle behavior

Oxidation at high temperatures without resistance coatings

Higher raw material costs than steel powders

Requires specialized experience for optimal use

Comparison With Tungsten Carbide-Titanium Carbide-Tantalum Carbide

T15 vs WC-TiC-TaC

Parameter	T15	WC-TiC-TaC
Hardness	88-93 HRA	92-96 HRA
Fracture toughness	10-12 MPa.m^1/2	8-9 MPa.m^1/2
Strength	Very high	Extremely high
Cost	Moderate	Very high
Corrosion resistance	Fair	Excellent
Applications	General wear parts	Extreme abrasion and corrosion

WC-TiC-TaC has slightly higher hardness and strength

T15 provides significantly better fracture toughness

WC-TiC-TaC offers excellent corrosion resistance

T15 is more cost effective

WC-TiC-TaC for more critical, expensive applications

T15 Powder FAQs

Q: What are the main applications of T15 tungsten carbide cobalt powder?

A: Main applications include mining tools like drill bits, rock crushers, and dredging equipment; construction tools like demolition and pulverizing equipment; dies, drawing parts, extrusion tooling; abrasion resistant components; and general cutting and machining tools.

Q: Why is cobalt used as the binder in tungsten carbide grades?

A: Cobalt provides good corrosion resistance, high strength and toughness, and facilitates liquid phase sintering of the tungsten carbide particles during densification to achieve full density and optimal properties.

Q: What heat treatment is used for T15 tungsten carbide cobalt parts?

A: T15 does not require post-sintering heat treatment. The liquid phase sintering process allows achieving full density and the desired properties during powder consolidation itself.

Q: How is T15 tungsten carbide cobalt powder produced?

A: Main production methods include carburization and reduction-diffusion to make spherical powders or crushing and milling sintered tungsten carbide material into irregular particles. These powders are then blended with cobalt powder in the desired ratio.

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Category: Iron Based Alloy Powder

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Note: For pricing & ordering information, please get in touch with us at sales@nanochemazone.com
Please contact us for quotes on Larger Quantities and customization. E-mail: contact@nanochemazone.com

Customization:
If you are planning to order large quantities for your industrial and academic needs, please note that customization of parameters (such as size, length, purity, functionalities, etc.) is available upon request.

NOTE:
Images, pictures, colors, particle sizes, purity, packing, descriptions, and specifications for the real and actual goods may differ. These are only used on the website for the purposes of reference, advertising, and portrayal. Please contact us via email at sales@nanochemazone.com or by phone at (+1 780 612 4177) if you have any

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17-4PH Stainless Steel Powder

Product	17-4PH Stainless Steel Powder
CAS No.	7439-89-6
Appearance	Gray Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	Fe-Cr-Ni-Cu-Nb
Density	7.75g/cm3
Molecular Weight	N/A
Product Codes	NCZ-DCY-347/25

17-4PH Stainless Steel Description:

17-4PH Stainless Steel Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing.

17-4PH Stainless Steel Powder Related Information :

Element	Weight %	Purpose
Iron	Balance	Principal matrix element
Chromium	15 – 17.5	Oxidation resistance
Copper	3 – 5	Precipitation hardening
Nickel	3 – 5	Austenite stabilizer
Niobium	0.15 – 0.45	Carbide former
Manganese	1 max	Deoxidizer
Silicon	1 max	Deoxidizer
Carbon	0.07 max	Strengthener and carbide former

The copper provides precipitation hardening while chromium imparts corrosion resistance. Properties of 17-4PH Powder 17-4PH possesses a versatile combination of properties:

Property	Description
High strength	Tensile strength up to 1310 MPa in aged condition
Hardness	Up to 40 HRC when aged
Corrosion resistance	Comparable to 316L stainless in many environments
Toughness	Superior to martensitic stainless steels
Wear resistance	Better than 300 series stainless steels
High temperature stability	Strength maintained up to 300°C

3D Printing Parameters for 17-4PH Powder Typical parameters for printing 17-4PH include:

Parameter	Typical value	Purpose
Layer height	20-100 μm	Balance speed and resolution
Laser power	150-400 W	Sufficient melting without evaporation
Scan speed	400-1000 mm/s	Productivity vs density
Hatch spacing	100-200 μm	Density and properties
Support structure	Minimal	Easy removal
Hot isostatic pressing	1120°C, 100 MPa, 3h	Eliminate porosity

Parameters are optimized for properties, time, and post-processing requirements. Applications of 3D Printed 17-4PH Parts Additively manufactured 17-4PH components are used in:

Industry	Applications
Aerospace	Structural brackets, fixtures, actuators
Medical	Dental implants, surgical instruments
Automotive	High strength fasteners, gears
Consumer	Watch cases, sporting equipment
Industrial	End-use metal tooling, jigs, fixtures

Benefits of AM include complex geometries, customization, reduced lead time and machining. Specifications of 17-4PH Powder for 3D Printing 17-4PH powder must meet strict specifications:

Parameter	Specification
Particle size range	15-45 μm typical
Particle shape	Spherical morphology
Apparent density	> 4 g/cc
Tap density	> 6 g/cc
Hall flow rate	> 23 sec for 50 g
Purity	>99.9%
Oxygen content	<100 ppm

Handling and Storage of 17-4PH Powder As a reactive material, 17-4PH powder requires controlled handling: Store in cool, dry, inert environments away from moisture Prevent oxidation and contamination during handling Use conductive containers grounded to prevent static buildup Avoid dust accumulation to minimize explosion risk Local exhaust ventilation recommended Wear PPE and avoid inhalation Careful storage and handling ensures optimal powder condition. Inspection and Testing of 17-4PH Powder Quality testing methods include:

Method	Parameters Checked
Sieve analysis	Particle size distribution
SEM imaging	Particle morphology
EDX	Chemistry and composition
XRD	Phases present
Pycnometry	Density
Hall flow rate	Powder flowability

Testing per ASTM standards verifies powder quality and batch consistency. Comparing 17-4PH to Alternative Powders 17-4PH compares to other alloys as:

Alloy	Strength	Corrosion Resistance	Cost	Weldability
17-4PH	Excellent	Good	Medium	Fair
316L	Medium	Excellent	Medium	Excellent
IN718	Good	Good	High	Fair
CoCr	Medium	Fair	Medium	Excellent

With balanced properties, 17-4PH provides the best combination of strength, corrosion resistance, and cost for many applications. Pros and Cons of 17-4PH Powder for 3D Printing

Pros	Cons
High strength-to-weight ratio	Lower oxidation resistance than austenitic stainless steels
Good combination of strength and corrosion resistance	Required post-processing like HIP and heat treatment
Lower cost than exotic alloys	Controlled atmosphere storage needed
Established credentials in AM	Difficult to weld and machine
Comparable properties to wrought material	Susceptible to pitting and crevice corrosion

17-4PH enables high-performance printed parts across industries, though not suited for extreme environments. Frequently Asked Questions about 17-4PH Powder for 3D Printing Q: What particle size range works best for printing 17-4PH alloy? A: A range of 15-45 microns provides optimal powder flow while enabling high resolution and density in the printed parts. Q: What post-processing is required after printing with 17-4PH? A: Hot isostatic pressing and heat treatment are usually necessary to eliminate internal voids, relieve stresses, and achieve optimal properties. Q: What material is 17-4PH most comparable to for AM applications? A: It is closest to 316L in corrosion resistance but much stronger. 17-4PH provides the best overall combination for many high-strength applications above 300 series stainless. Q: Does 17-4PH require supports when 3D printing? A: Minimal supports are recommended on overhangs and complex inner channels to prevent deformation during printing and allow easy removal. Q: What industries use additively manufactured 17-4PH components? A: Aerospace, medical, automotive, industrial tooling, and consumer products are the major application areas benefitting from 3D printed 17-4PH parts. Q: What accuracy and finish is achievable with 17-4PH AM parts? A: After post-processing, 17-4PH printed components can achieve dimensional tolerances and surface finish comparable to CNC machined parts. Q: What density can be expected with optimized 17-4PH prints? A: Densities exceeding 99% are routinely achieved with 17-4PH using ideal parameters tailored for the alloy, matching wrought properties. Q: Is 17-4PH compatible with powder bed fusion processes? A: Yes, it can be processed using selective laser melting (SLM), direct metal laser sintering (DMLS), and electron beam melting (EBM). Q: What defects can occur when printing 17-4PH components? A: Potential defects are cracking, distortion, porosity, incomplete fusion, and surface roughness. They can be minimized through optimized print parameters. Q: Can support structures be removed easily from 17-4PH printed parts? A: Properly designed minimal supports are easy to detach given the excellent mechanical properties of the alloy in the aged condition.

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304l Stainless Steel Powder

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304l Stainless Steel Powder

Product	304l Stainless Steel Powder
CAS No.	11143-21-4
Appearance	Metallic Gray or Silver Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	Fe-Cr-Ni
Density	7.9g/cm3
Molecular Weight	N/A
Product Codes	NCZ-DCY-338/25

304l Stainless Steel Description:

304l Stainless Steel Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing.

304l Stainless Steel Powder Related Information :

Element	Weight %
Chromium (Cr)	18-20
Nickel (Ni)	8-10.5
Manganese (Mn)	<2
Silicon (Si)	<1
Carbon (C)	<0.03
Sulfur (S)	<0.03
Phosphorus (P)	<0.045
Nitrogen (N)	<0.1
Iron (Fe)	Balance

Chromium and nickel are the main alloying elements. Chromium provides corrosion and oxidation resistance. Nickel enhances ductility, toughness, and weldability. Manganese and silicon increase strength. Carbon is kept very low for optimum corrosion resistance. Sulfur, phosphorus, and nitrogen are impurities that are minimized. Properties Key properties of 304L stainless steel powder in the annealed condition are provided below: Table: Properties of 304L stainless steel powder

Property	Value
Density	7.9-8.1 g/cm3
Ultimate Tensile Strength	505-620 MPa
Yield Strength	205-275 MPa
Elongation	≥40%
Hardness	≤92 HRB
Modulus of Elasticity	190-210 GPa
Melting Point	1400-1450°C
Thermal Conductivity	16 W/m-K
Electrical Resistivity	0.072 μΩ-cm

The combination of properties make 304L highly useful for a wide range of applications. The austenitic microstructure provides ductility, toughness, and non-magnetic behavior. 304L has excellent corrosion resistance comparable to 316L stainless steel. By selecting ultra-low carbon powder, carbide precipitation can be avoided to maximize corrosion resistance in critical applications. Strength and hardness can be increased through cold working. Applications Typical applications for 304L stainless steel powder include: Food processing equipment Pharmaceutical tooling Chemical plant components Architectural panels, railings Medical instruments and implants Marine hardware, fittings, fasteners Consumer products, appliances Powder metallurgy mechanical parts 3D printing powders 304L provides cost-effective corrosion resistance versus 316L when molybdenum alloying is not needed for highly corrosive environments. The excellent polishability and non-magnetic properties also suits 304L for architectural cladding and hardware components. Powder metallurgy is commonly used to produce small precision parts from 304L at high volumes versus machining. Additive manufacturing utilizes 304L powder for prototypes, tooling, and end-use components across industries. Powder Manufacturing 304L stainless steel powder is commercially manufactured via gas atomization or water atomization processes. In gas atomization, a high pressure inert gas stream disintegrates the molten metal into fine droplets, producing spherical powders ideal for additive manufacturing and MIM. Particle size distribution is controlled through process parameters. Water atomization uses high pressure water jets to break up the metal stream into fine particles. This generates irregular, satellite particle shapes. The powder requires post-treatment for additive manufacturing. Plasma atomization is sometimes used to produce very spherical, clean powders from a metal plasma stream in a controlled inert atmosphere. This ensures high purity and flowability. Powder Specifications 304L stainless steel powder is commercially available in various size ranges, morphologies, and quality levels. Some typical powder specifications are below: Table: 304L stainless steel powder specifications

Attribute	Details
Particles sizes	15-45 μm, 10-100 μm
Morphology	Spherical, irregular
Apparent density	2.5-4.5 g/cm3
Tap density	4-5 g/cm3
Hall flow rate	<30 s/50g
Purity	>99.5%
Oxygen content	<2000 ppm
Moisture content	<0.2%

Smaller particle sizes below 45 μm are preferred for capturing fine features in additive manufacturing. Spherical particles provide good flowability. Apparent density correlates with powder packing efficiency. High purity, low oxygen, and controlled moisture levels ensure quality sintered properties. Gas atomized powder offers the best specifications for critical applications. Standards and Grades 304L stainless steel powder complies with the following standards: ASTM A240 – Standard for chromium and chromium-nickel stainless steel plate, sheet, and strip ASTM A313 – Standard for stainless steel spring wire ASTM A314 – Standard for stainless steel bent wire AMS 5501 – Stainless steel bars, wire, forgings, tubing with low carbon AMS 5647 – Stainless steel powder, atomized, 304L Equivalent grades include: UNS S30403 Werkstoff No. 1.4306 SUS 304L SS2348 Powder Storage and Handling To prevent contamination and maintain powder properties, 304L stainless steel powder should be stored and handled as follows: Store in sealed containers in a cool, dry environment Use inert gas purging or vacuum to prevent moisture pickup Keep away from sparks, flames, and ignition sources Ground all powder handling and transfer equipment Avoid contact with contaminants like oil, grease, paints, etc. Use PPE – mask, gloves, eye protection when handling powder Powder spills should be promptly cleaned using non-sparking tools and HEPA vacuuming. Powders are moderately sensitive to moisture and air exposure. Proper storage is key. Metal Injection Molding 304L is widely used for metal injection molding of small, complex parts leveraging powder metallurgy. Key considerations include: Feedstock: 60-68% powder loading with multi-component binder system Molding: High shot size, fast injection speed, high holding pressure Debinding: Solvent debinding followed by thermal debinding Sintering: 1350-1400°C in hydrogen or vacuum atmosphere Secondary Operations: Machining, laser marking, passivation, electropolishing MIM service bureaus have established best practices for high-performance 304L parts with as-sintered properties approaching wrought material. Design for AM For additive manufacturing using 304L stainless steel powder, key design guidelines include: Maintain wall thicknesses above 1 mm Use self-supporting geometries with angles above 45° Include drain holes to remove unfused powder Observe build orientation effects on properties Account for 20-25% shrinkage when designing mating parts Include machining allowances of 0.5-1 mm for critical fits Reduce overhangs, bridges, fine details that require supports Quality Control Quality control testing performed on 304L stainless steel powder includes: Chemical analysis – ICP and OES to verify composition Particle size analysis – Laser diffraction particle size analyzer Powder morphology – SEM imaging at high magnifications Apparent density and tap density – Hall flowmeter method Powder flow rate – Hall flowmeter funnel method Loss on ignition – ASTM E sin gravity furnace Moisture analysis – Karl Fischer titration, LECO analysis For sintered MIM parts, testing includes: Dimensional tolerances – CMM inspection Density – Archimedes method Microstructure – Optical microscopy, image analysis Mechanical testing – Hardness, tensile, fatigue, Charpy impact Health and Safety Like most stainless steel powders and parts, 304L poses little health risk with proper handling: Wear PPE when handling powder – mask, gloves, goggles Avoid skin contact to prevent sensitization Use HEPA-filtered vacuum for clean-up of dust and powder Avoid breathing any welding or melting fumes Dispose according to local environmental regulations Ensure adequate ventilation and respiratory protection if grinding or machining sintered parts No special disposal precautions are needed for 304L. With sound procedures, it poses minimal hazard for workers and the environment. FAQ 1.What is the difference between 304 and 304L stainless steel powder? 304L has lower carbon content (<0.03%) than 304 (<0.08%) for better corrosion resistance,especially for welding. 304 is more common. 2.Does 304L powder require a controlled atmosphere? Not necessarily, but storage in sealed containers with inert gas prevents oxidation and contamination. 3.What particle size is best for AM? 15-45 microns is typical for powder bed fusion AM to provide good flow and high resolution. Larger sizes from 45-100 microns are also used. 4.Is 304L used for metal 3D printing? Yes, 304L is widely used for powder bed and directed energy deposition 3D printing to make prototypes, tooling, and end-use parts. 5.What causes powder to oxidize and lose reusability? Exposure to air/moisture causes surface oxidation. Proper sealed storage with desiccant and oxygen absorbers prevents this. 6.Does 304L require solution annealing after laser sintering? Yes, stress relieving at 1050-1150°C and rapid cooling helps restore ductility and toughnessafterthe rapid solidification. 7.What finish can be expected on as-sintered MIM 304L parts? Around Ra 3-6 microns initially. Polishing and etching can achieve under 0.5 micron. Plating also gives a smooth finish. 8.What tolerance can be achieved with 304L MIM parts?±0.1-0.3% is typical but tolerances under ±0.1% are possible for high precision components. 9.Why is 304L preferred over 304 stainless steel? The lower carbon gives 304L better corrosion resistance, especially for weldments, reducing sensitization. It has become the dominant grade. 10.What is the cost premium for 304L vs. 304 powder? Typically 10-30% higher cost for 304L due to the lower carbon composition. Price also depends on quantities ordered.

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310 Powder

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310 Powder

Product	310 Powder
CAS No.	N/A
Appearance	Metallic Gray Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	Fe-25Cr-20Ni
Density	7.7-8.0g/cm3
Molecular Weight	N/A
Product Codes	NCZ-DCY-338/25

310 Description:

310 Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing.

310 Powder Related Information :

Properties	Details
Composition	Fe-25Cr-20Ni-0.25N alloy
Density	8.1 g/cc
Particle shape	Irregular, angular
Size range	10-150 microns
Apparent density	Up to 50% of true density
Flowability	Moderate
Strength	Very high for a 300 series powder
Wear resistance	Excellent due to work hardening

310 powder is widely used in applications requiring hardness, wear resistance, and corrosion resistance like valve parts, shafts, bearing cages, fasteners, surgical instruments etc. 310 Powder Composition Typical composition of 310 stainless steel powder: 310 Powder Composition

Element	Weight %
Iron (Fe)	Balance
Chromium (Cr)	24-26%
Nickel (Ni)	19-22%
Nitrogen (N)	0.2-0.4%
Carbon (C)	0.25% max
Silicon (Si)	1.5% max
Manganese (Mn)	2% max
Sulfur (S)	0.03% max
Phosphorus (P)	0.045% max

Iron provides the ferritic matrix and ductility Chromium and nickel enhance corrosion resistance Nitrogen provides solid solution strengthening Carbon, silicon, manganese controlled as tramp elements 310 Powder Physical Properties

Property	Values
Density	8.1 g/cc
Melting point	1370-1400°C
Electrical resistivity	0.8 μΩ-m
Thermal conductivity	12 W/mK
Thermal expansion	11 x 10^-6 /K
Maximum service temperature	1150°C

High density compared to ferritic stainless steels Maintains excellent strength at elevated temperatures Resistivity higher than pure iron or carbon steels Lower thermal conductivity than carbon steel Can withstand continuous service up to 1150°C The physical properties make 310 suitable for high temperature applications requiring hardness, strength and corrosion resistance. 310 Powder Mechanical Properties

Property	Values
Tensile strength	760-900 MPa
Yield strength	450-550 MPa
Elongation	35-40%
Hardness	32-38 HRC
Impact strength	50-100 J
Modulus of elasticity	190-210 GPa

Very high strength for 300 series stainless steel Excellent hardness and wear resistance High toughness and impact strength Strength can be further increased through cold working Cold working also significantly enhances hardness The properties provide an excellent combination of strength, hardness and toughness required in many wear resistant applications. 310 Powder Applications Typical applications of 310 stainless steel powder include: 310 Powder Applications

Industry	Example Uses
Petrochemical	Valves, pumps, shafts
Food processing	Extruder screws, blades
Automotive	Gears, shafts, fasteners
Manufacturing	Press tooling, bearing cages
Medical	Surgical instruments, implants

Some specific product uses: High strength fasteners, bolts, nuts Pump and valve components like seals, shafts Food processing extruder screws and blades High hardness press tooling and molds Mixing equipment, impellers requiring wear resistance Its excellent combination of properties make 310 widely used for specialized applications across industries. 310 Powder Specifications Relevant specifications and standards: 310 Powder Standards

Standard	Description
ASTM A276	Standard specification for stainless steel bars and shapes
ASTM A314	Standard for stainless steel bent pipe and tubing
ASME SA-479	Specification for stainless steel tubing
AMS 5517	Annealed corrosion resistant steel bar, wire, forgings
AMS 5903	Precipitation hardening stainless steel bar, wire, forgings

These standards define: Chemical composition limits of 310 alloy Permissible impurity levels like S, P Required mechanical properties Approved production methods Compliance testing protocols Proper packaging, labeling and documentation Meeting certification requirements ensures suitability of the powder. 310 Powder Particle Sizes 310 Powder Particle Size Distribution

Particle Size	Characteristics
10-45 microns	Ultrafine grade for high density and surface finish
45-150 microns	Coarse grade provides good flowability
15-150 microns	Standard grade for pressing and sintering

Finer particles allow greater densification during sintering Coarser powder flows better and fills die cavities uniformly Size range is tailored based on final part properties needed Both gas and water atomized powders are available Controlling particle size distribution allows optimizing processing behavior and final part performance. 310 Powder Apparent Density

Apparent Density	Details
Up to 50% of true density	For irregular powder morphology
4.5-5.5 g/cc typical	Improves with greater packing density

Higher apparent density improves powder flow and compressibility Irregular morphology limits maximum packing density Values up to 60% are possible with spherical powders High apparent density improves press filling efficiency Higher apparent density leads to better manufacturing productivity and part quality. 310 Powder Production Method

Method	Details
Gas atomization	High pressure inert gas breaks molten metal stream into fine droplets
Water atomization	High pressure water jet breaks metal into fine particles
Vacuum induction melting	High purity input materials melted under vacuum
Multiple remelting	Improves chemical homogenization
Sieving	Classifies powder into different particle size ranges

Gas atomization provides clean, spherical powder morphology Water atomization is a lower cost process with irregular particles Vacuum melting and remelting minimizes gaseous impurities Post-processing allows customization of particle sizes Automated production and stringent quality control result in consistent powder suitable for critical applications. 310 Powder Handling and Storage

Recommendation	Reason
Use PPE and ventilation	Avoid exposure to fine metallic particles
Ensure proper grounding	Prevent static discharge while handling
Avoid ignition sources	Powder can combust in oxygen atmosphere
Use non-sparking tools	Prevent possibility of ignition
Follow safety protocols	Reduce risk of burns, inhalation, ingestion
Store in stable containers	Prevent contamination or oxidation

As 310 powder is flammable, ignition and explosion risks should be controlled during handling and storage. Otherwise it is relatively safe with proper precautions. 310 Powder Inspection and Testing

Test	Details
Chemical analysis	ICP and XRF verify composition
Particle size distribution	Laser diffraction determines size distribution
Apparent density	Hall flowmeter test per ASTM B212 standard
Powder morphology	SEM imaging shows particle shape
Flow rate analysis	Gravity flow rate through specified nozzle
Loss on ignition	Determines residual moisture content

Stringent testing ensures the powder meets the required chemical purity, particle characteristics, density, morphology, and flowability per applicable specifications. 310 Powder Pros and Cons Advantages of 310 Powder Excellent strength and hardness for stainless steel powder High temperature strength and corrosion resistance Good ductility, toughness and weldability Excellent wear and abrasion resistance Readily work hardens significantly More cost-effective than high nickel or exotic alloys Disadvantages of 310 Powder Lower ductility than austenitic grades in annealed state Lower pitting corrosion resistance than 316 grade Requires care during welding to avoid sensitization Limited cold heading and forming capability Susceptible to sigma phase embrittlement at high temperatures Surface discoloration over time in some environments Comparison With 316L Powder 310 vs 316L Stainless Steel Powder

Parameter	310	316L
Density	8.1 g/cc	8.0 g/cc
Strength	760-900 MPa	485-550 MPa
Hardness	32-38 HRC	79-95 HRB
Corrosion resistance	Very good	Excellent
Cost	Low	High
Uses	Wear parts, tools	Chemical plants, marine

310 has far higher strength and hardness 316L provides better overall corrosion resistance 310 is more cost-effective than 316L 310 suited for applications needing hardness and wear resistance 316L preferred where corrosion is the primary concern 310 Powder FAQs Q: What are the main applications of 310 stainless steel powder? A: Main applications include high-strength fasteners, pump and valve components, extruder screws, press tooling, bearing cages, shafts, and surgical instruments requiring hardness, strength and wear resistance. Q: What is nitrogen’s role in 310 stainless steel? A: Nitrogen provides substantial solid solution strengthening which significantly increases the strength and hardness of 310 stainless steel. Q: What precautions are needed when working with 310 powder? A: Recommended precautions include ventilation, inert atmosphere, grounding, avoiding ignition sources, protective gear, using non-sparking tools, and safe storage in stable containers. Q: How does 310 stainless steel differ from 304 and 316 grades? A: 310 has much higher strength and hardness than 304 or 316 due to its high nitrogen content. It offers better wear resistance but lower corrosion resistance than 316.

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316L Stainless Steel Powder

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316L Stainless Steel Powder

Product	316L Stainless Steel Powder
CAS No.	12597-68-1
Appearance	Metallic Gray Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	Fe-16-18Cr-10-14Ni-2-3-Mo
Density	7.99g/cm3
Molecular Weight	N/A
Product Codes	NCZ-DCY-340/25

316L Stainless Steel Description:

316L Stainless Steel Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing.

316L Stainless Steel Powder Related Information :

Element	Weight %	Purpose
Iron	Balance	Principal matrix element
Chromium	16-18	Corrosion resistance
Nickel	10-14	Austenite stabilizer
Molybdenum	2-3	Corrosion resistance
Manganese	<2	Deoxidizer
Silicon	<1	Deoxidizer
Carbon	<0.03	Avoid carbide precipitation

The high chromium and nickel content provide corrosion resistance while the low carbon minimizes carbide precipitation. Properties of 316L Stainless Steel Powder

Property	Description
Corrosion resistance	Excellent resistance to pitting and crevice corrosion
Strength	Tensile strength up to 620 MPa
Weldability	Readily weldable and less prone to sensitization
Fabricability	Easily formed into complex shapes
Biocompatibility	Safe for contact with human body
Temperature resistance	Resistant up to 900°C in oxidizing environments

The properties make 316L suitable for harsh, corrosive environments. AM Process Parameters for 316L Powder Typical parameters for printing 316L powder include:

Parameter	Typical value	Purpose
Layer height	20-100 μm	Balance speed and resolution
Laser power	150-350 W	Melting condition without vaporization
Scan speed	200-1200 mm/s	Density versus build rate
Hatch spacing	100-200 μm	Mechanical properties
Supports	Minimal tree/lattice	Overhangs, internal channels
Hot isostatic pressing	1150°C, 100 MPa, 3 hrs	Eliminate porosity

Parameters tailored for density, microstructure, production rate and post-processing needs. Applications of 3D Printed 316L Parts AM 316L components are used in:

Industry	Applications
Aerospace	Structural brackets, panels, housings
Automotive	Turbine housings, impellers, valves
Chemical	Pumps, valves, reaction vessels
Oil and gas	Downhole tools, manifolds, flanges
Biomedical	Dental, orthopedic implants, surgical tools

Benefits versus wrought 316L include complex geometries, reduced part count, and accelerated product development. Specifications of 316L Powder for AM 316L powder must meet strict specifications:

Parameter	Specification
Particle size range	15-45 μm typical
Particle shape	Spherical morphology
Apparent density	> 4 g/cc
Tap density	> 6 g/cc
Hall flow rate	> 23 sec for 50 g
Purity	>99.9%
Oxygen content	<1000 ppm

Handling and Storage of 316L Powder As a reactive material, careful 316L powder handling is essential: Store sealed containers away from moisture, acids, ignition sources Use inert gas padding during transportation and storage Ground equipment to dissipate static charges Avoid dust accumulation through extraction and ventilation Follow safety data sheet precautions Proper techniques ensure optimal powder condition. Inspection and Testing of 316L Powder

Method	Parameters Tested
Sieve analysis	Particle size distribution
SEM imaging	Particle morphology
EDX	Chemistry and composition
XRD	Phases present
Pycnometry	Density
Hall flow rate	Powder flowability

Testing per ASTM standards verifies powder quality and batch consistency. Comparing 316L to Alternative Alloy Powders 316L compares to other alloys as:

Alloy	Corrosion Resistance	Strength	Cost	Printability
316L	Excellent	Medium	Medium	Excellent
17-4PH	Good	High	Medium	Good
IN718	Good	Very high	High	Fair
CoCr	Fair	Medium	Medium	Good

With its balanced properties, 316L is very versatile for small to medium sized AM components needing corrosion resistance. Pros and Cons of 316L Powder for AM

Pros	Cons
Excellent corrosion resistance and biocompatibility	Lower high temperature strength than alloys
Readily weldable and machinable	Susceptible to porosity during printing
Cost advantage over exotic alloys	Prone to thermal cracking
Can match wrought material properties	Required post-processing like HIP
Range of suppliers available	Lower hardness than precipitation hardening alloys

316L provides versatile performance at moderate cost, albeit with controlled processing requirements. Frequently Asked Questions about 316L Stainless Steel Powder Q: What particle size range works best for printing 316L alloy? A: A typical range is 15-45 microns. It provides good powder flowability combined with high resolution and density. Q: What post-processing methods are used on 316L AM parts? A: Hot isostatic pressing, heat treatment, surface machining, and electropolishing are common methods for achieving full densification and surface finish. Q: Which metal 3D printing process is ideal for 316L alloy? A: All major powder bed fusion processes including selective laser melting (SLM), direct metal laser sintering (DMLS) and electron beam melting (EBM) are regularly used. Q: What industries use additively manufactured 316L components? A: Aerospace, automotive, biomedical, marine hardware, chemical processing, and oil and gas industries benefit from 3D printed 316L parts. Q: Does 316L require support structures during 3D printing? A: Yes, support structures are essential on overhangs and bridged sections to prevent deformation and allow easy removal after printing. Q: What defects can occur when printing 316L powder? A: Potential defects are porosity, cracking, distortion, lack of fusion, and surface roughness. Most can be prevented with optimized parameters. Q: What is the key difference between 316 and 316L alloys? A: 316L has lower carbon content (0.03% max) which improves corrosion resistance and eliminates harmful carbide precipitation during welding. Q: How are the properties of printed 316L compared to wrought alloy? A: With optimized parameters, AM 316L components can achieve mechanical properties on par or exceeding conventionally processed wrought counterparts. Q: What density can be expected with 3D printed 316L parts? A: Density above 99% is achievable for 316L with ideal parameters tailored for the alloy, matching wrought material properties. Q: What finishing is typically applied to 316L AM parts? A: Abrasive flow machining, CNC machining, and electropolishing are common finishing processes for removing surface roughness and achieving the required tolerances.

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317L Powder

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317L Powder

Product	317L Powder
CAS No.	12597-68-1
Appearance	Metallic Gray Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	Fe-18Cr-12Ni-3Mo
Density	7.9g/cm3
Molecular Weight	N/A
Product Codes	NCZ-DCY-341/25

317L Description:

317L Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing.

317L Powder Related Information:

Properties	Details
Composition	Fe-18Cr-3Mo-0.08C alloy
Density	8.0 g/cc
Particle shape	Irregular, angular
Size range	10-150 microns
Apparent density	Up to 50% of true density
Flowability	Moderate
Corrosion resistance	Excellent in many environments
Strengthening	Cold working and solid solution strengthening

317L powder is widely used in chemical processing, marine applications, pulp and paper industry, nuclear power generation, and architectural features needing weathering resistance. 317L Powder Composition

Element	Weight %
Iron (Fe)	Balance
Chromium (Cr)	17-19%
Nickel (Ni)	11-15%
Molybdenum (Mo)	2.5-3.5%
Manganese (Mn)	<2%
Carbon (C)	0.08% max
Silicon (Si)	1% max
Nitrogen (N)	0.10% max
Sulfur (S)	0.03% max

Iron provides the ferritic matrix and ductility Chromium enhances corrosion and oxidation resistance Nickel stabilizes the austenitic structure Molybdenum further improves pitting resistance Carbon, nitrogen and sulfur controlled as tramp elements 317L Powder Physical Properties

Property	Values
Density	8.0 g/cc
Melting point	1370-1400°C
Electrical resistivity	0.8 μΩ-m
Thermal conductivity	16 W/mK
Thermal expansion	16 x 10^-6 /K
Maximum service temperature	900°C

High density compared to ferritic stainless steels Maintains strength and corrosion resistance at elevated temperatures Resistivity higher than pure iron or carbon steels Lower thermal conductivity than carbon steel Can withstand continuous service up to 900°C The physical properties make 317L suitable for high temperature applications requiring corrosion resistance. 317L Powder Mechanical Properties

Property	Values
Tensile strength	515-620 MPa
Yield strength	205-275 MPa
Elongation	40-50%
Hardness	88-95 HRB
Impact strength	100-150 J
Modulus of elasticity	190-210 GPa

Excellent combination of strength and ductility Can be work hardened significantly to increase strength Very high toughness and impact strength Strength can be further improved through cold working Hardness is relatively low in annealed condition The properties provide an excellent balance of strength, ductility and toughness required for many corrosive environments. 317L Powder Applications

Industry	Example Uses
Chemical	Tanks, valves, pipes, pumps
Petrochemical	Process equipment, tubing, valves
Marine	Propeller shafts, fasteners, deck hardware
Nuclear	Reactor vessels, fuel element cladding
Architectural	Railings, wall panels, roofing

Some specific product uses: Pollution control equipment handling hot acids Nuclear reactor internal structures Marine propeller shafts, deck fittings Pulp and paper industry piping, valves Architectural paneling, roofing, cladding Its excellent corrosion resistance combined with good manufacturability make 317L widely used across demanding industries. 317L Powder Standards

Standard	Description
ASTM A276	Standard for stainless steel bars and shapes
ASTM A479	Standard for stainless steel tubing
AMS 5524	Annealed stainless steel bar, wire, forgings
ASME SA-276	Specification for stainless steel bars and shapes
AISI 630	Standard for 17Cr-4Ni precipitation hardening stainless steel

These standards define: Chemical composition limits of 317L alloy Permissible impurity levels like S, P Required mechanical properties Approved production methods Compliance testing protocols Proper packaging, labeling and documentation Meeting certification requirements ensures suitability of the powder for the intended applications. 317L Powder Particle Sizes

Particle Size	Characteristics
10-45 microns	Ultrafine grade for high density and surface finish
45-150 microns	Coarse grade provides good flowability
15-150 microns	Standard grade for pressing and sintering

Apparent Density	Details
Up to 50% of true density	For irregular powder morphology
4.5-5.5 g/cc typical	Improves with greater packing density

Higher apparent density improves powder flow and compressibility Irregular morphology limits maximum packing density Values up to 60% are possible with spherical powder High apparent density improves press filling efficiency Higher apparent density leads to better manufacturing productivity and part quality. 317L Powder Production Method

Method	Details
Gas atomization	High pressure inert gas breaks molten metal stream into fine droplets
Water atomization	High pressure water jet breaks metal into fine particles
Vacuum induction melting	High purity input materials melted under vacuum
Multiple remelting	Improves chemical homogenization
Sieving	Classifies powder into different particle size ranges

Recommendation	Reason
Use PPE and ventilation	Avoid exposure to fine metallic particles
Ensure proper grounding	Prevent static discharge while handling
Avoid ignition sources	Powder can combust in oxygen atmosphere
Use non-sparking tools	Prevent possibility of ignition
Follow safety protocols	Reduce risk of burns, inhalation, ingestion
Store in stable containers	Prevent contamination or oxidation

As 317L powder is flammable, ignition and explosion risks should be controlled during handling and storage. Otherwise it is relatively safe with proper precautions. 317L Powder Inspection and Testing

Test	Details
Chemical analysis	ICP and XRF verify composition
Particle size distribution	Laser diffraction determines size distribution
Apparent density	Hall flowmeter test per ASTM B212 standard
Powder morphology	SEM imaging shows particle shape
Flow rate analysis	Gravity flow rate through specified nozzle
Loss on ignition	Determines residual moisture content

Stringent testing ensures the powder meets the required chemical purity, particle characteristics, density, morphology, and flowability per applicable specifications. 317L Powder Pros and Cons Advantages of 317L Powder Excellent corrosion resistance in many environments High temperature strength and oxidation resistance Good ductility, toughness and weldability More cost-effective than high nickel austenitic grades Readily formable using conventional techniques Can be work hardened through cold/warm working Disadvantages of 317L Powder Lower high temperature creep strength than some ferritic grades Lower hardness and wear resistance than martensitic grades Susceptible to chloride stress corrosion cracking Requires post weld annealing to prevent sensitization Limited cold heading and forming capability Surface discoloration over time in outdoor exposure Comparison With 316L Powder 317L vs 316L Stainless Steel Powder

Parameter	317L	316L
Density	8.0 g/cc	8.0 g/cc
Strength	515-620 MPa	485-550 MPa
Corrosion resistance	Excellent	Outstanding
Pitting resistance	Very good	Excellent
Cost	Low	High
Uses	Process industry, marine	Chemical, pharmaceutical

317L provides higher strength at lower cost 316L offers better pitting corrosion resistance 317L has good chloride stress corrosion resistance 316L preferred for ultra-corrosive environments 317L suited for marine applications and nuclear industry 317L Powder FAQs Q: What are the main applications of 317L stainless steel powder? A: Main applications include chemical processing, petrochemical, marine, nuclear, pulp & paper, and architectural. It is used for equipment like tanks, valves, pipes, pumps, shafts, and cladding. Q: What precautions should be taken when handling 317L powder? A: Recommended precautions include ventilation, grounding, avoiding ignition sources, using non-sparking tools, protective gear, safe storage, and controlling dust exposure. Q: How does molybdenum improve the corrosion resistance of 317L? A: Molybdenum enhances pitting and crevice corrosion resistance in chloride environments. It stabilizes the passive film protecting the surface. Q: What is the main difference between 304L and 317L stainless steel powder? A: 317L contains 3% molybdenum giving it significantly better corrosion resistance compared to 304L, especially in marine and other chloride environments.

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AerMet100 Stainless Steel Powder

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AerMet100 Stainless Steel Powder

Product	AerMet100 Stainless Steel Powder
CAS No.	N/A
Appearance	Gray to Dark Gray Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	Fe-13Cr-3Ni-1Mo-0.25C
Density	7.93g/cm3
Molecular Weight	N/A
Product Codes	NCZ-DCY-346/25

AerMet100 Stainless Steel Description:

AerMet100 Stainless Steel Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing.

AerMet100 Stainless Steel Powder Related Information :

Storage Conditions: Airtight sealed, avoid light and keep dry at room temperature. Please contact us for customization and price inquiry Email: contact@nanochemazone.com Note: We supply different size ranges of Nano and micron as per the client’s requirements and also accept customization in various parameters. AerMet100 Stainless Steel Powder AerMet100 stainless steel powder is an advanced high strength and corrosion resistant alloy powder designed for additive manufacturing applications. With its unique composition and properties, AerMet100 enables production of high performance parts using 3D printing processes like laser powder bed fusion and binder jetting. This article provides a comprehensive overview of AerMet100 stainless steel powder covering its composition, properties, applications, specifications, pricing, handling, inspection methods and other technical details AerMet100 stainless steel powder is a high-performance alloy powder designed for additive manufacturing applications requiring high strength and fatigue resistance. Some key features of this material include: High strength and hardness – AerMet100 has excellent strength with tensile strength over 200 ksi and hardness ranging from 30-36 HRC. Good ductility – Despite the high strength, AerMet100 still retains decent ductility and impact resistance. Elongation values are over 10%. Excellent fatigue resistance – The fatigue limit of AerMet100 is very high at around 50% of tensile strength. This allows durable components exposed to cyclic stresses. Resistance to creep – AerMet100 resists deformation under load at high temperatures up to 700°C making it suitable for elevated temperature service. Corrosion resistance – The stainless steel composition provides corrosion and oxidation resistance for use in harsh environments. Weldability – The low carbon content allows for good weldability using standard fusion welding methods. Cost-effectiveness – AerMet100 is more affordable than other exotic alloys with similar properties. This exceptional balance of properties makes AerMet100 suitable for demanding applications in aerospace, oil & gas, automotive, and industrial sectors. Parts made from AerMet100 powder demonstrate high strength-to-weight ratio, durability, and reliability under operating loads. AerMet100 Stainless Steel Powder Composition AerMet100 has a martensitic stainless steel composition with additions of cobalt, nickel, and molybdenum for strength and hardness. The nominal composition is given below:

Element	Weight %
Iron (Fe)	Balance
Chromium (Cr)	15.0 – 17.0
Nickel (Ni)	7.0 – 10.0
Cobalt (Co)	8.0 – 10.0
Molybdenum (Mo)	4.0 – 5.0
Manganese (Mn)	< 1.0
Silicon (Si)	< 1.0
Carbon (C)	< 0.03

The key alloying elements and their effects are: Chromium – Provides corrosion and oxidation resistance Nickel – Increases toughness and ductility Cobalt – Solid solution strengthener, increases strength Molybdenum – Solid solution strengthener, increases strength and creep resistance Manganese & Silicon – Deoxidizers to improve powder manufacturability Carbon – Kept low for better weldability The combination of these elements gives AerMet100 stainless steel its unique set of properties. AerMet100 Stainless Steel Powder Properties AerMet100 exhibits the following physical and mechanical properties in as-built AM and heat treated conditions:

Property	As-Built	Heat Treated
Density	7.9 g/cc	7.9 g/cc
Porosity	< 1%	< 1%
Surface Roughness (Ra)	15-25 μm	15-25 μm
Hardness	30-35 HRC	34-38 HRC
Tensile Strength	170-190 ksi	190-220 ksi
Yield Strength (0.2% Offset)	160-180 ksi	180-210 ksi
Elongation	8-13%	10-15%
Reduction of Area	15-25%	15-25%
Modulus of Elasticity	27-30 Msi	29-32 Msi
CTE (70-400°C)	11-12 μm/m°C	11-12 μm/m°C
Conductivity	25-30% IACS	25-30% IACS

The properties make AerMet100 suitable for high-strength structural components, aerospace fasteners, downhole tools, valves and pumps, and other critical parts where fatigue resistance is paramount. AerMet100 Stainless Steel Powder Applications The unique properties of AerMet100 make it an excellent choice for the following applications: Aerospace Structural brackets, braces, fuselage components Landing gear parts, wing components, empennage Engine mounts, exhaust components Turbine blades, impellers, compressor parts High-strength fasteners, bolts, nuts, rivets Oil & Gas Downhole drill tools and components Wellhead parts, valves, pumps Pressure vessels, pipe fittings Subsea/offshore structural parts Automotive Power generation components Drive systems parts like gears, shafts Structural braces, chassis components High-performance racing components Industrial Robotics parts subject to wear and impact Dies, molds, tooling Fluid handling parts like valves and pumps Other high-cycle loaded components The excellent fatigue strength of AerMet100 makes it an ideal replacement for components traditionally made from titanium or nickel alloys. The high hardness provides good wear resistance as well. AerMet100 Stainless Steel Powder Specifications AerMet100 powder products meet the following specifications:

Specification	Grade/Alloy
AMS 7245	AerMet100
ASTM F3056	AlloySpec 23A
DIN 17224	X3NiCoMoAl 15-7-3

Typical size distributions for AM processing are:

Particle Size	Distribution
15-53 μm	98%
<106 μm	99%

Chemical composition must conform to the permissible ranges for elements like Cr, Ni, Co, Mo, C, etc. as outlined in AMS 7245 specification for AerMet100 alloy. Mechanical properties should meet or exceed the minimum values for hardness, tensile strength, yield strength, elongation, and reduction of area stated in AMS 7245. Non-destructive testing like dye penetrant or magnetic particle inspection should show no critical flaws or defects. Powder should have good flowability and exhibit no clumping. Storage and Handling To maintain quality of AerMet100 powder for AM use, the following storage and handling guidelines apply: Store sealed containers in a cool, dry place away from moisture and sources of contamination Avoid exposing powder to high humidity (>60% RH) for prolonged time Allow powder to equilibrate to room temperature prior to unsealing container to prevent condensation Pour and transfer powder in inert environments with low oxygen content if possible Use powder handling equipment and accessories made from compatible materials to prevent contamination Limit reuse of powder to 2-3 cycles maximum to prevent degradation of properties Conduct testing of used powder to ensure it still meets all specifications for reuse Proper storage and careful handling is key to preventing powder oxidation, contamination, or changes in flowability. Safety Information Wear PPE when handling powder – gloves, respirator mask, goggles Avoid skin contact to prevent possible allergic reactions Prevent inhalation of fine powders over long periods Ensure adequate ventilation and dust collection when processing Use non-sparking tools to dispense and handle powder Inert gas blanketing is recommended for powder handling Follow all applicable safety data sheet (SDS) guidelines Dispose according to local regulations and ensure containment AerMet100 alloy powders are generally not hazardous materials but following basic safety practices during storage, handling, and processing is advised. Inspection and Testing To ensure AerMet100 powder meets specifications, the following inspection and testing procedures can be used:

Test Method	Property Validated
Visual inspection	Powder flowability, contamination
Scanning electron microscopy	Particle size distribution and morphology
Energy dispersive X-ray spectroscopy	Alloy chemistry, contamination
X-ray diffraction	Phases present, contamination
Hall flowmeter	Powder flow rate
Apparent density	Powder packing density
Tap density test	Powder flowability
Sieve analysis	Particle size distribution per ASTM B214
Chemical analysis	Composition per AMS 7245, oxides
Density measurement	Powder density vs AMS 7245

Mechanical testing of printed specimens per AMS 7245 validates final part properties meet requirements. Testing methods include hardness, tensile, charpy impact, high cycle fatigue, low cycle fatigue, creep rupture, fracture toughness, corrosion, etc. AerMet100 Stainless Steel Powder Comparison to Similar Materials AerMet100 compares to other high-strength martensitic stainless steels as follows:

Alloy	Strength	Ductility	Weldability	Cost
AerMet100	Very high	Moderate	Fair	Moderate
17-4PH	High	Low	Poor	Low
Custom 465	Very high	Low	Poor	High
316L	Moderate	High	Excellent	Low
Inconel 718	High	High	Moderate	Very high

Advantages of AerMet100: Higher strength than 17-4PH and 316L Better ductility than Custom 465 for higher impact resistance More weldable than precipitation hardening alloys Lower cost than Inconel 718 Limitations of AerMet100: Lower ductility/fracture toughness than austenitic 316L Inferior weldability compared to 316L Higher cost than 17-4PH or 316L Lower strength than Custom 465 in peak aged condition Overall, AerMet100 provides an optimal combination of strength, ductility, weldability, and cost for high-performance parts made by AM processes. FAQ Q: What are the key benefits of AerMet100 alloy? A: The main benefits of AerMet100 are its high strength and hardness coupled with good ductility, excellent fatigue resistance, creep resistance, corrosion resistance, and moderate cost. This makes it well suited for critical AM applications. Q: What heat treatment is used for AerMet100? A: A typical heat treatment is 1-2 hours solutionizing at 1040-1080°C followed by air or furnace cooling to room temperature, then age hardening at 480°C for 4 hours to achieve optimal strength and hardness. Q: What welding methods can be used to join AerMet100 parts? A: Fusion welding methods like GTAW, GMAW, and PAW are recommended for AerMet100 to avoid cracking and minimize distortion. Low heat input and peening of welds is also suggested. Brazing can also produce good joints. Q: How does AerMet100 compare to maraging steels for AM? A: AerMet100 has higher ductility but slightly lower strength than maraging steels like 18Ni300 or 18Ni350. Maraging steels have poor weldability. AerMet100 is a good lower-cost alternative to maraging. Q: Can AerMet100 be machined after AM processing? A: Yes, AerMet100 can be machined after AM but care must be taken to account for work hardening effects. Low cutting forces, carbide tooling, and adequate coolant is recommended. Annealing may be required after extensive machining. Q: What particle size range of AerMet100 powder is optimal for AM? A: The recommended particle size range for AM is 15-45 μm. Finer powders improve resolution but can negatively impact flowability. Coarser powders above 53 μm can cause print defects. The typical sweet spot is 25-35 μm

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D2 Powder

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D2 Powder

Product	D2 Powder
CAS No.	7782-39-0
Appearance	White-Off White Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	C28H44O2
Density	7.7g/cm3
Molecular Weight	N/A
Product Codes	NCZ-DCY-350/25

D2 Description:

D2 Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing.

D2 Powder Related Information :

Properties	Details
Composition	Fe-1.5Cr-0.3C-0.4V-1Mo alloy
Density	7.7 g/cc
Particle shape	Spherical or irregular
Size range	10-150 microns
Apparent density	Up to 60% of true density
Flowability	Good
Hardness	60-62 HRC when heat treated
Toughness	Very good

D2’s exceptional combination of hardness, strength, and impact resistance make it the top choice for cold work tooling needing extended service life. D2 Powder Composition

Element	Weight %
Iron (Fe)	Balance
Chromium (Cr)	11-13%
Carbon (C)	1.4-1.6%
Molybdenum (Mo)	0.75-1.2%
Vanadium (V)	0.7-1.2%
Manganese (Mn)	0.3-0.6%
Silicon (Si)	0.15-0.4%

Iron provides the ferritic matrix Chromium contributes to hardness and wear resistance Carbon enables high hardness in heat treated condition Molybdenum and vanadium form carbides enhancing wear resistance Manganese and silicon improve solid solution strengthening D2 Powder Physical Properties

Property	Value
Density	7.7 g/cc
Melting point	1460-1500°C
Thermal conductivity	21 W/mK
Electrical resistivity	0.7 μΩ-m
Curie temperature	1010°C
Maximum service temperature	180-200°C

High density provides component miniaturization capabilities Retains high hardness and strength at elevated temperatures Becomes paramagnetic above Curie point Relatively low service temperature due to tempering effect The properties allow D2 to be used in cold work tooling applications at high hardness levels. D2 Powder Mechanical Properties

Property	Value
Hardness	60-62 HRC
Transverse rupture strength	1900-2100 MPa
Tensile strength	2050-2200 MPa
Yield strength	1700-1900 MPa
Elongation	8-11%
Impact toughness	12-15 J/cm2

Exceptional hardness when heat treated Very high strength with reasonable ductility Excellent impact toughness for a tool steel High fatigue strength for extended tool life Strength and ductility values depend on heat treatment The properties make D2 suitable for the most demanding cold work tooling and die applications requiring extreme wear resistance. D2 Powder Applications

Industry	Example Uses
Manufacturing	Press tooling, punch and dies
Automotive	Blank, pierce, trim, and forming dies
Aerospace	Forming dies, fixtures
Consumer goods	Razors, knives, scissors
Industrial	Drawing dies, thread rolling dies

Some specific product uses: Cold heading dies for fastener manufacturing Coining dies for minting precise parts Thread rolling dies for bolt production Draw, punch, blanking dies across sectors Surgical tools and cutlery Pelletizing tooling D2 is the premier powder metal tool steel preferred for the longest lasting cold work tooling, metal forming dies, and precision components across all industries. D2 Powder Standards

Standard	Description
ASTM A681	Standard for tool steels alloys
DIN 1.2379	Equivalent to AISI D2
JIS G 4404	Cold work tool steels
ISO 4957	Tool steels
GOST 5950	Tool steel grades

These define: Chemical composition limits of D2 steel Required mechanical properties in heat treated condition Permissible impurities Approved production methods like gas atomization Compliance testing protocols Packaging, identification requirements D2 powder made to these specifications ensures suitability for tooling applications requiring maximum wear resistance, impact toughness and dimensional stability. D2 Powder Particle Sizes

Particle Size	Characteristics
10-22 microns	Ultrafine grade provides highest density
22-53 microns	Most commonly used size range
53-105 microns	Coarser size provides good flowability

Finer particles allow greater densification during sintering Coarser particles improve powder flow into die cavities Size is selected based on final part properties needed Both gas and water atomized particles used Controlling size distribution optimizes pressing behavior, sintered density, and final component performance. D2 Powder Apparent Density

Apparent Density	Details
Up to 60% of true density	For spherical powder morphology
4.5-5.5 g/cc typical	Higher density improves flow and compressibility

Spherical powder shape provides high apparent density Irregular powder has lower density around 50% Higher apparent density improves press fill efficiency Enables easier compaction into complex tool geometries Higher apparent density leads to better manufacturing productivity and component quality. D2 Powder Production Method

Method	Details
Gas atomization	High pressure inert gas breaks up molten alloy stream into fine droplets
Vacuum induction melting	High purity input materials melted under vacuum
Multiple remelting	Enhances chemical homogeneity
Sieving	Classifies powder into different particle size fractions

Gas atomization provides spherical powder shape Vacuum melting eliminates gaseous impurities Multiple remelting improves uniformity Post-processing allows particle size customization Fully automated processes combined with strict quality control ensures reliable and consistent properties of D2 powder critical for tooling performance. D2 Powder Handling and Storage

Recommendation	Reason
Ensure adequate ventilation	Prevent exposure to fine metal particles
Wear protective gear	Avoid accidental ingestion
Ground all equipment	Prevent static sparks
Avoid ignition sources	Flammable dust risk
Use non-sparking tools	Prevent ignition during handling
Follow safe protocols	Reduce fire, explosion, and health risks

Storage Recommendations Store sealed containers in a cool, dry area Limit exposure to moisture, acids, chlorides Maintain temperatures below 27°C Proper precautions during handling and storage help preserve purity and prevent health or fire hazards. D2 Powder Inspection and Testing

Test	Details
Chemical analysis	Verifies composition using optical or ICP spectroscopy
Particle size distribution	Determines sizes using laser diffraction or sieving
Apparent density	Measured using Hall flowmeter as per ASTM B212
Powder morphology	SEM imaging to determine particle shape
Flow rate analysis	Gravity flow rate through specified funnel
Tap density test	Density measured after mechanically tapping powder sample

Testing ensures the powder meets the required chemical composition, physical characteristics, particle size distribution, morphology, density, and flow rate specifications. D2 Powder Pros and Cons Advantages of D2 Powder Exceptional hardness when heat treated Excellent wear and abrasion resistance Very high strength combined with good impact toughness Dimensional stability in cold work service Good grindability compared to other tool steels Relatively cost-effective Limitations of D2 Powder Moderate corrosion resistance without surface treatment Limited high temperature strength and creep resistance Requires careful heat treatment by experienced providers Not weldable using conventional welding methods Large sections can experience embrittlement Brittle fracture mode limits cold formability Comparison With S7 Tool Steel Powder D2 vs S7 Tool Steel Powder

Parameter	D2	S7
Hardness	60-62 HRC	63-65 HRC
Toughness	Very good	Good
Wear resistance	Excellent	Outstanding
Corrosion resistance	Moderate	Low
Cold strength	Excellent	Very good
Cost	Low	High

D2 has slightly lower hardness but much better toughness S7 provides the maximum wear resistance D2 has better corrosion resistance uncoated S7 has higher hot hardness and hot strength D2 is more cost effective D2 Powder FAQs Q: What are the main applications of D2 tool steel powder? A: Main applications include cold pressing tooling, blanking and punching dies, coin minting dies, thread rolling dies, surgical tools, knives, industrial knives, and precision ground shafts and pins. Q: What heat treatment is used for D2 tool steel powder? A: D2 is typically heat treated by austenitizing at 1010-1040°C, quenching in oil or air, and tempering at 150-350°C to achieve a hardness of 60-62 HRC. Q: How does vanadium improve the properties of D2 steel? A: Vanadium forms fine carbides with iron and chromium that impart significant wear resistance and abrasion resistance while also enhancing impact toughness. Q: What precautions should be taken when working with D2 powder? A: Recommended precautions include ventilation, inert atmosphere, avoiding ignition sources, grounding equipment, using non-sparking tools, protective gear, and safe storage away from moisture or contamination.

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S2 Powder

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S2 Powder

Product	S2 Powder
CAS No.	77404-34-9
Appearance	Metallic Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	S-2
Density	7.8-8.1g/cm3
Molecular Weight	N/A
Product Codes	NCZ-DCY-355/25

S2 Description:

M2 Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing.

S2 Powder Related Information :

Properties	Details
Composition	Fe-1C-5Cr-2.35Mo-6.4W-1.4V-2Si alloy
Density	7.7 g/cc
Particle shape	Irregular, angular
Size range	10-150 microns
Apparent density	Up to 50% of true density
Flowability	Low to moderate
Hardness	62-64 HRC when heat treated
Toughness	Very good

S2 powder produces cutting tools, dies, and machine components with extended service life under continuous high temperature and intermittent shock loading conditions. S2 Powder Composition

Element	Weight %
Iron (Fe)	Balance
Carbon (C)	0.9-1.2%
Chromium (Cr)	3.8-4.5%
Tungsten (W)	6.4%
Molybdenum (Mo)	1.9-2.2%
Vanadium (V)	1.3-1.6%
Manganese (Mn)	0.2-0.5%
Silicon (Si)	0.9-1.4%

Iron provides the ferritic matrix Carbon, tungsten, and chromium form hard carbides Vanadium and molybdenum enhance wear resistance Manganese and silicon facilitate machining S2 Powder Physical Properties

Property	Values
Density	7.7 g/cc
Melting point	1320-1350°C
Thermal conductivity	37 W/mK
Electrical resistivity	0.6 μΩ-m
Maximum service temperature	600°C
Curie temperature	770°C

High density enables miniaturized components Retains hardness and strength at elevated temperatures Becomes paramagnetic above Curie point Can withstand prolonged service up to 600°C Good thermal conductivity reduces thermal expansion stresses These properties provide a balanced combination of hot hardness and thermal shock resistance required in high speed machining applications. S2 Powder Mechanical Properties

Property	Values
Hardness	62-64 HRC
Transverse rupture strength	4500-4800 MPa
Compressive strength	3800-4100 MPa
Tensile strength	2050-2250 MPa
Yield strength	1930-2050 MPa
Elongation	8-10%
Impact toughness	10-14 J/cm2

Exceptional hardness when heat treated High strength with reasonable ductility Very good compressive and transverse rupture strength Excellent red hardness at elevated temperatures Strength depends on heat treatment process S2 powder produces cutting tools and dies with hardness, strength, and thermal properties needed to machine challenging materials at high speeds and temperatures. S2 Powder Applications

Industry	Example Uses
Automotive	Cutting and milling tools
Aerospace	Drills, end mills
Manufacturing	Punches, forming dies
Oil and gas	Downhole tools, drill bits
General machining	Turning, boring, and planning tools

Some specific product uses: Cutting inserts, indexable tooling Broaches, reamers, taps, threading dies Metal slitting saws and industrial knives Extrusion tooling and drawing dies Cold heading and forging dies Gauges, wear-resistant components S2’s unique properties make it the top choice for reliable cutting tools and components used in demanding metalworking applications. S2 Powder Specifications Key specifications for S2 high speed steel powder: S2 Powder Standards

Standard	Description
ASTM A600	Specification for tool steels high speed steel
JIS G4403	High speed tool steels
DIN 1.2363	Equivalent to AISI S7 high speed steel
UNS T11302	Designation for AISI S2 grade
ISO 4957	Tool steels specification

These define: Chemical composition limits of S2 Required mechanical properties in heat treated condition Approved production methods like gas atomization Compliance testing protocols Quality assurance requirements Proper packaging and identification Powder produced to these standards ensures suitability for high wear resistance tooling applications under thermal fatigue conditions. S2 Powder Particle Sizes

Particle Size	Characteristics
10-22 microns	Ultrafine grade provides highest density
22-53 microns	Most commonly used size range
53-105 microns	Coarser size provides good flowability

Apparent Density	Details
Up to 50% of true density	For irregular powder morphology
4.0-5.0 g/cc	Higher for spherical, lower for irregular powder

Spherical powder shape provides high apparent density Irregular powder has lower density around 45-50% Higher apparent density improves die filling and part quality Allows complex tool geometry compaction Higher apparent density leads to better component production rate and performance. S2 Powder Production

Method	Details
Gas atomization	High pressure inert gas breaks up molten alloy stream into fine droplets
Vacuum induction melting	High purity input materials melted under vacuum
Multiple remelting	Enhances chemical homogeneity
Sieving	Classifies powder into different particle size fractions

Gas atomization provides spherical powder shape Vacuum melting eliminates gaseous impurities Multiple remelting improves uniformity Post-processing allows particle size customization Fully automated processes combined with strict quality control ensures reliable and consistent S2 powder properties critical for tooling performance. S2 Powder Handling and Storage

Recommendation	Reason
Ensure proper ventilation	Prevent exposure to fine metal particles
Use appropriate PPE	Avoid ingestion through nose/mouth
Ground equipment	Prevent static sparking
Avoid ignition sources	Flammable dust hazard
Use non-sparking tools	Prevent possibility of ignition
Follow safe protocols	Reduce fire, explosion, health risks

Storage Recommendations Store sealed containers away from moisture or contamination Maintain storage temperatures below 27°C Limit exposure to oxidizing acids and chlorine compounds Proper precautions during handling and storage help preserve purity and prevent safety hazards. S2 Powder Testing

Test	Details
Chemical analysis	Verifies composition using optical/ICP spectroscopy
Particle size analysis	Determines size distribution using laser diffraction or sieving
Apparent density	Measured as per ASTM B212 using Hall flowmeter
Powder morphology	SEM imaging to determine particle shape
Flow rate test	Gravity flow rate through specified funnel
Tap density test	Density measured after mechanically tapping powder sample

Testing ensures the powder meets the required chemical composition, physical characteristics, particle size distribution, morphology, density, and flow rate specifications. S2 Powder Pros and Cons Advantages of S2 Powder Exceptional hot hardness and red hardness High strength and wear resistance at elevated temperatures Good toughness and thermal shock resistance Resists softening and shape changes up to 600°C Dimensional stability under thermal cycling Cost-effective compared to exotic PM tool steel grades Limitations of S2 Powder Moderate corrosion resistance without surface treatment Limited cold formability and shear strength Requires careful heat treatment by experienced providers Not weldable using conventional fusion welding Large cross-sections can experience embrittlement Contains expensive alloying elements Comparison With H13 Tool Steel Powder S2 vs H13 Tool Steel Powder

Parameter	S2	H13
Hardness	62-64 HRC	54-57 HRC
Hot hardness	Excellent	Good
Toughness	Very good	Good
Thermal shock resistance	Excellent	Moderate
Cold strength	Good	Excellent
Cost	High	Low

S2 has much greater hot hardness and thermal shock resistance H13 provides better cold strength and toughness S2 is more expensive due to higher alloy content S2 preferred for high speed machining applications H13 suited for cold and warm pressing tooling S2 Powder FAQs Q: What are the main applications of S2 tool steel powder? A: Main applications include cutting tools like drills, mills, inserts, taps, dies, saws, planning tools, as well as extrusion tooling, forging dies, gauges, and components needing hot hardness and thermal shock resistance. Q: What heat treatment is used for S2 tool steel powder? A: S2 tool steel is typically heat treated by austenitizing between 1150-1200°C followed by air, oil, or polymer quenching, then tempering between 540-650°C to achieve hardness between 62-64 HRC. Q: How does tungsten improve the properties of S2 steel? A: Tungsten forms hard tungsten-iron-carbon complexes that provide exceptional hot hardness, strength and wear resistance at elevated temperatures needed for high speed machining applications. Q: What safety precautions should be used when working with S2 powder? A: Proper ventilation, protective gear, inert atmosphere, grounding, avoiding ignition sources, using non-sparking tools, and safe storage away from contamination or moisture.

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