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The Difference Between Boron Powder and Amorphous Boron powder

The Difference Between Boron Powder and Amorphous Boron

Both are composed of the same element, amorphous is more porous and is often used in coatings, paints as well as other products. It is also used in electronic devices. It’s also used as an ingredient in boron trioxide that is a substance which is used to create boron-containing compounds such as boron hailide.

XRD patterns

The study was conducted to study the XRD patterns of Boron powder. This study was conducted using powder containing boron from two distinct sources. The sources used were Sigma-Aldrich as well as Nanoshel. The XRD patterns of both sources showed different patterns. The peaks of the Nanoshel sample are smaller and have a crystalline look in comparison to the Sigma-Aldrich specimen, which has broader peaks, which more accurately reflect the Amorphous nature of boron particles.

The B13 site demonstrated significant temperature dependence as was the case for the B16-B20 site. The temperature at which the reaction occurred was about 1200degC.

The B2O3 layer is removed by a surface coating

Plasma treatment of material using Boron oxy-carbides reduces their cleaning rate. Surface boron oxy-carbides are formed due to the interaction between the plasma on the surface and the B2O3 phase. The resulting surface layer is an anti-corrosion barrier.

This layer is characterized by a large amount of oxygen which is mostly present in the form BC2O or BCO2. The coating is composed of fine crystal particles that are well integrated with the substrate. The coating B is much more dense and has more pores than coating C. This helps to form an insulation layer that is stronger. Coating C, on contrary, is comprised from SiO2 and has a large layers of pores.

Organoboron chemical compounds are employed in a range of different applications

Organoboron-based compounds are widely used in organic chemistry and have many industrial applications. They are versatile intermediates and Reagents that are simple to prepare. There are numerous chemical transformations that can be accomplished on them However, the most crucial is an oxidation. This is a solid foundation for the introduction of functional groups.

There are a variety of chemical reactions that are able to create organoboron compounds like the Suzuki reaction. Organoboron chemicals are typically planar and tetrahedral in their form however, they can be trimeric or dodecahedral as more than one boronatom reacts with one the other.

In the long run, exposure to boron could cause irritation of the nose, throat, and eyes

Studies have demonstrated that long-term exposure to boron powder could irritate the nose, throat and eyes. While it is an inert metal, it has been shown to cause irritation of the eye and nasal surfaces in animals. It also causes dry mouth, sore throat and cough.

It is unlikely that you will be exposed to boron via drinking water or through the air. However, it is possible to get exposure via consumer products. Boron can build up in plants and can be passed onto animals who eat them. Anorexia, confusion , and hair loss may be caused from prolonged exposure to large amounts of boron. Boron exposure is not harmful in small quantities, however prolonged exposure can cause damage to the skin and lead to severe illness.

Crystalline boron is described as amorphous and the boron powder

There are two forms of boron: amorphous as well as crystalline. Amorphous boron is dark brown in color, unlike crystalline boron which is a black, hard substance. Alongside its applications in smelting metals, boron is a useful deoxidizer, because it stops the metal from oxidizing at high temperatures. It is also employed in composite materials and alloys.

Amorphous boron is a brown powder that has a high tension force. There are two methods to make it. Both types of powder can comprise up to 98.5% of pure material. The most common way to create amorphous or amorphous boron by dispersing it into a mixture of potassium hydroxide and sodium hydroxide but amorphous is more easily obtained by mixing boron powder into NaCl, KCl, or MgCl2.

The Difference Between Boron Powder and Amorphous Boron Both are composed of the same element, amorphous is more porous and is often used in coatings, […]

3D Printing 316 Powder Stainless Steel Powder

About 3D Printing 316 Powder Stainless Steel Powder:
Stainless steel 316 is an iron-based alloy containing at least 10.5% chromium. They achieve their stainless steel properties by forming an invisible, attached chromium-rich oxide film.316 alloy is a kind of universal austenitic stainless steel with a face-centered cubic structure. It is essentially non-magnetic in the annealed state and can only be hardened by cold work. In order to improve the corrosion resistance of the alloy, especially in the environment containing chlorine, molybdenum is added, and the low carbon content of 316L alloy gives it better corrosion resistance in the welded tissue. Feel free to send an inquiry to get the latest price if you would like to buy 3D Printing 316 Powder Stainless Steel Powder in bulk.

3D printing powder Main elements of 316L stainless steel powder:

Cr	Ni	Mo	Mn	Fe
16.00-18.00	10.0-14.0	2.0-3.0	≤2.00	Bal

3D printing powder Impurity elements of 316L stainless steel powder

Si	P	S	C	O
≤1.00	≤0.04	≤0.03	≤0.03	≤0.05

3D printing powder Morphology: Spherical

3D printing powder Purity: 99.9%

3D printing powder powder Particle size: 0-20μm, 15-45μm, 15-53μm, 53-105μm, 53-150μm, 105-250μm

3D printing powder Appearance: grey powder

3D printing powder Package: Aluminum bag, Vacuum packing

3D printing powder Application: 3D printing metal powder

3D printing powder Other applications: powder metallurgy(PM), injection molding(MIM), spray painting(SP), etc.

How is 3D Printing 316 Powder Stainless Steel Powder produced?
316 alloy is a kind of universal austenitic stainless steel with a face-centered cubic structure. It is essentially non-magnetic in the annealed state and can only be hardened by cold work.

Applications of 3D Printing 316 Powder Stainless Steel Powder:
The application range of 316 alloy powder is as follows:
A) Aerospace, Construction, Automotive, Chemicals, Fasteners, Electronics, Food Processing, Furnaces and Fixtures, Hardware, Jewelry, Cryogenic Environment, Marine and Seawater Environment, Office Equipment, Pharmaceuticals, Welding, Pulp and Paper Manufacturing.
B) Special stainless steel powder with corrosion resistance, surface finish, wear resistance, machinability, oxidation resistance, electroplating free, high-temperature strength and low expansion coefficient.
C) Injection-molded metal parts.
D) Additives for manufacturing stainless steel powder are available.

Storage Condition of 316 Powder Stainless Steel Powder:
The damp reunion will affect 316 powder dispersion performance and using effects, therefore, 316 powder stainless steel powder should be sealed in vacuum packing and stored in cool and dry room, the 316 powder stainless steel powder can not be exposure to air. In addition, the 316 powder should be avoided under stress.

Packing & Shipping of 316 Powder Stainless Steel Powder:
We have many different kinds of packing which depend on the 316 powder stainless steel powder quantity.
316 powder stainless steel powder packing: vacuum packing, 100g, 500g or 1kg/bag, 25kg/barrel, or as your request.
316 powder stainless steel powder shipping: could be shipped out by sea, by air, by express, as soon as possible once payment receipt.
3D Printing 316 Powder Stainless Steel Powder插图

316 Stainless Steel Powder Properties
Other Names	316 powder, stainless steel powder, 316 stainless steel powder
CAS No.	N/A
Compound Formula	N/A
Molecular Weight	N/A
Appearance	Grey powder
Melting Point	N/A
Solubility in water	N/A
Density	N/A
Purity	99%
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


316 Stainless Steel Powder 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

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About 3D Printing 316 Powder Stainless Steel Powder:Stainless steel 316 is an iron-based alloy containing at least 10.5% chromium. They achieve their stainless steel properties […]

3D Printing Ti6Al4V Powder TC4 Powder

About 3D Printing Ti6Al4V Powder TC4 Powder:
Ti6Al4V referred to as TC4, is an α-β titanium alloy with a high strength-to-weight ratio and excellent corrosion resistance. It is one of the most commonly used titanium alloys and is widely used in low density and excellent corrosion resistance is necessary for such aerospace industry and biomechanical applications (implants and prostheses).Ti6Al4V is generally considered to be the “base” of the titanium industry because it is by far the most widely used titanium alloy, more than 50% of the total amount of titanium. It is an α+β alloy that can be heat treated to achieve moderate strength. Titanium 6 aluminum 4 vanadium is recommended for use at temperatures not exceeding 350℃/660℉.
The composition of TC4 titanium base powder is Ti6Al4V, which belongs to (α+β) type titanium alloy, and has good comprehensive mechanical properties.TC4 titanium alloy has excellent corrosion resistance. It has a series of advantages such as low density, high specific strength, good toughness, good weldability and so on. It has been used in aerospace, petrochemical, shipbuilding, automobile, pharmaceutical and other industries.
Compared with traditional stainless steel and cobalt-based alloys, titanium alloys are increasingly used as biomaterials due to their lower modulus, excellent biocompatibility and enhanced corrosion resistance. These attractive properties have been the driving force for the early introduction of (CpTi) and A # B (Ti6Al4V) alloys, as well as for the newer development of new titanium alloy compositions and orthopedic metastable B titanium alloys.Alloy.The latter has enhanced biocompatibility, reduced elastic modulus, and excellent strain control and notch fatigue strength. However, the poor shear strength and wear resistance of titanium alloys still limit their biomedical applications. Although some improvement has been shown in the wear resistance of B-Ti alloys compared to A # B alloys, the end-use of orthopedic titanium alloys as wear components will require a more complete basic understanding of the wear mechanisms involved. Feel free to send an inquiry to get the latest price if you would like to buy 3D Printing Ti6Al4V Powder TC4 Powder in bulk.

Main elements:

Al	V	Ti
5.50-6.75	3.50-4.50	Bal

Impurity elements:

Fe	C	N	H	O	Y
≤0.3	≤0.08	≤0.05	≤0.015	≤0.2	≤0.005

category	Alloy grades and characteristics
Alloy number:	TA0,TA1,TC4,TC4 ELI,TC11,TC17,TC18,TC21,TA7,TA12,TA15,TA17,TA19, Ti40,Ti60,TiAl(Ti36Al,Ti48Al2Cr2Nb),TiNi,TiNb,ZrTi
Particle size:	0-20μm, 15-45μm, 15-53μm, 53-105μm, 53-150μm, 105-250μm
Morphology:	Spherical or nearly spherical
Appearance:	Grey
Package:	Aluminum bag,Vacuum packing
Application:	3D printing metal powder
Other applications:	powder metallurgy(PM), injection molding(MIM), spray painting(SP) etc.

How is 3D Printing Ti6Al4V Powder TC4 Powder produced?
Ti6Al4V was heat-treated to change the content of Ti6Al4V and the phase in the microstructure of the alloy. The microstructure will vary greatly according to the exact heat treatment and processing method. Three common heat treatment processes are mill annealing, two-phase annealing, solution treatment and aging treatment.

Applications of 3D Printing Ti6Al4V Powder TC4 Powder:
Ti6Al4V has the characteristics of good hardness, lightweight, formability and corrosion resistance, and is widely used in the aviation industry.
Ti6Al4V can be used in low to medium temperature environments where high strength, lightweight and excellent corrosion resistance are required. Such as aircraft steam turbine engine parts, aircraft structural parts, aviation fasteners, high-performance automatic parts, ships, medical equipment and sports equipment.
Implant and prosthesis (forged, cast or made by solid free-forming (SFF)) additive manufacturing.
Parts and prototypes for the racing and aerospace industries.
It is widely used in the Boeing 787.
Marine applications.
The chemical industry.
Gas turbines.
The gun silencer.

Storage Condition of Ti6Al4V Powder TC4 Powder:
The damp reunion will affect Ti6Al4V powder dispersion performance and using effects, therefore, titanium aluminum carbide Ti6Al4V powder should be sealed in vacuum packing and stored in cool and dry room, the TC4 can not be exposure to air. In addition, the Ti6Al4V powder should be avoided under stress.

Packing & Shipping of Ti6Al4V Powder TC4 Powder:
We have many different kinds of packing which depend on the Ti6Al4V powder quantity.
TC4 powder packing:vacuum packing, 100g, 500g or 1kg/bag, 25kg/barrel, or as your request.
TC4 powder shipping: could be shipped out by sea, by air, by express, as soon as possible once payment receipt.
3D Printing Ti6Al4V Powder TC4 Powder插图

Ti6Al4V Powder TC4 Powder Properties
Other Names	Ti6Al4V Powder, TC4 Powder
CAS No.	N/A
Compound Formula	TA0,TA1,TC4,TC4 ELI,TC11,TC17,TC18,TC21,TA7,TA12,TA15,TA17,TA19, Ti40,Ti60,TiAl(Ti36Al,Ti48Al2Cr2Nb),TiNi,TiNb,ZrTi
Molecular Weight	N/A
Appearance	Grey powder
Melting Point	N/A
Solubility in water	N/A
Density	N/A
Purity	99%
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


Ti6Al4V Powder TC4 Powder 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

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About 3D Printing Ti6Al4V Powder TC4 Powder:Ti6Al4V referred to as TC4, is an α-β titanium alloy with a high strength-to-weight ratio and excellent corrosion resistance. […]

3D Printing Inconel Alloy In625 Powder

About 3D Printing Inconel Alloy In625 Powder:
Inconel 625 is a high-performance nickel-based superalloy known for its high level of strength, high temperature and corrosion resistance. This superalloy consists mainly of nickel (at least 58%), followed by chromium, molybdenum, niobium, iron, tantalum, cobalt, and trace amounts of manganese, silicon, aluminum, and titanium. It can withstand high pressures and a wide range of temperatures. Inconel 625 has a melting point of about 1300°C and a thermal expansion coefficient of 1.28 × 10-5 1/K(at 20°C). It can resist all kinds of extreme temperatures from low to very high.
Inconel625 has a density of 8.4 g/cm3 and a melting point of 1290-1350℃. It has excellent corrosion resistance to inorganic acid and various corrosive media in oxidation and reduction environments. Resistant to carbonation and oxidation in static or circulating environments, and to chlorine-containing gas corrosion
Inconel625 alloys exhibit excellent corrosion resistance in many media. Its excellent resistance to pitting, crevice, intergranular corrosion and erosion in chloride media, as well as its ability to resist corrosion in highly acidic environments, make it a suitable choice for nuclear and marine applications.
625 alloys exhibit excellent corrosion resistance in a wide range of media. Excellent resistance to pitting, crevice corrosion, intergranular corrosion and corrosion in chloride media. It has good corrosion resistance to inorganic acids, such as nitric acid, phosphoric acid, sulfuric acid, hydrochloric acid, etc. At the same time, it also has alkali and organic acid corrosion resistance in oxidation and reduction environments. Effective resistance to chloride ion reduction stress corrosion cracking. It is almost non-corrosive in seawater and industrial gas environments and has high corrosion resistance to seawater and salt solutions, as well as at high temperatures.No sensitivity during welding. Resistant to carbonation and oxidation in static or circulating environments, and to chlorine-containing gas corrosion. Feel free to send an inquiry to get the latest price if you would like to buy 3D Printing Inconel Alloy In625 Powder in bulk.

Composition for nickel based alloy powder In625 (percentage by mass):

Cr	Mo	Co	Nb	Al	S	Ni
20-23	8-10	1 max	3.15-4.15	0.4 max	0.015 max	Bal

Ti	C	Fe	Mn	Si	P	Cu
0.4 max	0.1 max	5 max	0.5 max	0.5 max	0.015 max	0.07 max

category	Alloy grades and characteristics
Alloy number:	Nickel-based alloy IN625 powder
Particle size:	15-45μm, 15-53μm, 53-120μm, 53-150μm
Morphology:	Spherical
Appearance:	Grey
Package:	Aluminum bag, Vacuum packing
Application:	3D printing metal powder
Other applications:	powder metallurgy(PM), injection molding(MIM), spraying coating(SP) etc.

How is 3D Printing Inconel Alloy In625 produced?
The production and composition of the Inconel 625 depend on the specifications required for the material.
In order to improve the toughness of the material, heat treatment of the alloy is necessary.In the case of Inconel 625, the following treatments can be used:
High solution annealing: Soak at 1095-1205 ° C (up to 1 hour), then the lower temperature in ambient air or cooling medium. The result is an alloy with superior creep resistance.
Low solubility annealing: This is similar to high solubility annealing but at a lower temperature of 925-1040°C.The alloys produced have good tensile strength and ductility.
Stress relief: This process involves soaking at 900°C for up to 4 hours, followed by cooling in the surrounding air. The final product has excellent integrity in low-temperature environments, as well as optimal strength and stress resistance.
Forging Inconel 625 requires a furnace temperature between 1010 °C and 1150°C. Anything below this range may cause hardness and require reheating of the material.

Applications of 3D Printing Inconel Alloy In625 Powder:
Inconel 625 applications
After softening annealing, low carbon alloy 625 is widely used in the chemical process industry. Its good corrosion resistance and high strength enable it to be used as a thinner structural component.625 alloy can be used in contact with seawater and subjected to high mechanical stress.
Marine application
Due to its high corrosion resistance, especially pitting and cracking resistance, the Inconel 625 is ideal for high-salt, subsea applications. The material is used as propeller blades for ships, mooring lines for fixing ships and similar ships, accessories and fixtures for submarines, and components for marine equipment.
Aerospace equipment
The superalloy has also found its way into the aircraft industry, especially for exhaust equipment, fuel pipes, heat exchanger casings and rocket parts.That’s because the Inconel 625 works well even at extreme temperatures and pressures.
Nuclear technology
Inconel 625’s strength and corrosion and stress resistance make it a suitable component for nuclear reactors, especially control rods and cores. Nuclear systems also typically involve temperatures in excess of 650°C, which Inconel 625’s strength can withstand.
Industrial processes
Because the alloy is easy to manufacture and resistant to high temperatures and corrosion, it is a useful component in the production of manufacturing equipment such as vessels, heat exchangers, valves and fluid distribution systems. Its excellent weldability also makes it a suitable component for pipes used in manufacturing plants.

Storage Condition of Inconel Alloy In625 Powder:
The damp reunion will affect In625 powder dispersion performance and using effects, therefore, Inconel alloy In625 powder should be sealed in vacuum packing and stored in a cool and dry room, the Inconel alloy In625 powder can not be exposure to air. In addition, the Inconel alloy In625 powder should be avoided under stress.

Packing & Shipping of Inconel Alloy In625 Powder:
We have many different kinds of packing which depend on the Inconel alloy In625 powder quantity.
Inconel alloy In625 powder packing:vacuum packing, 100g, 500g or 1kg/bag, 25kg/barrel, or as your request.
Inconel alloy In625 powder shipping: could be shipped out by sea, by air, by express, as soon as possible once payment receipt.
3D Printing Inconel Alloy In625 Powder插图

Tungstenmolybdenummetals Nano Technology Co. Ltd. (Tungstenmolybdenummetals) 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.
If you are looking for high-quality In625 powder, please feel free to contact us and send an inquiry. ([email protected])

Inconel Alloy In625 Powder Properties
Other Names	INCO 625
CAS No.	N/A
Compound Formula	Ni Cr Fe Mo Nb
Molecular Weight	N/A
Appearance	Metallic Powder
Melting Point	1290-1350 °C
Solubility in water	N/A
Density	N/A
Purity	99%
Particle Size	15-45μm, 15-53μm, 53-120μm, 53-150μm
Boling point	N/A
Specific Heat	N/A
Thermal Conductivity	9.8 W/m·°C (21 °C)
Thermal Expansion	N/A
Young’s Modulus	N/A
Exact Mass	N/A
Monoisotopic Mass	N/A


Inconel Alloy In625 Powder Health & Safety Information
Safety Warning	Danger
Hazard Statements	H317-H351-H372
Flashing point	N/A
Hazard Codes	Xn
Risk Codes	N/A
Safety Statements	N/A
RTECS Number	N/A
Transport Information	NONH for all modes of transport
WGK Germany	N/A

Inquiry us

About 3D Printing Inconel Alloy In625 Powder:Inconel 625 is a high-performance nickel-based superalloy known for its high level of strength, high temperature and corrosion resistance. […]

3D Printing Aluminum Based Alloy AlSi7Mg Powder

About 3D Printing Aluminum Based Alloy AlSi7Mg Powder:
AlSi7Mg is a heat-treatable aluminum alloy widely used in the manufacture of lightweight functional components in the automotive and aerospace industries. This material maintains a high mass strength ratio and has good corrosion resistance, making it an ideal application for aluminum alloys that require a combination of excellent thermal properties and low weight.AlSi7Mg is a cast aluminum alloy with good teachability, low density and good corrosion resistance. Therefore, its castings are widely used in aviation, instrument and general machinery, such as automobile engine cylinder head, intake manifold, piston, wheel hub, steering booster shell and so on.
AlSi7Mg powder is another 3D-printed powder for SLM to produce parts with good hardness, strength, lightweight and machinability. The chemical composition of AlSi7Mg is similar to that of F357 aluminum alloy. Tungstenmolybdenummetals is a trusted global 3D Printing Aluminum Based Alloy AlSi7Mg Powder supplier. Feel free to send an inquiry about the latest price of Aluminum Based Alloy AlSi7Mg at any time.

Product Performance of 3D Printing Aluminum Based Alloy Powder AlSi7Mg Powder :

The AlSi7Mg powder has high powder sphericity, smooth surface, less satellite balls, low oxygen content, uniform particle size distribution, good fluidity and high bulk density and tap density.

Technical Parameter of 3D Printing Aluminum Based Alloy Powder AlSi7Mg Powder :

Product Name	Si	Mn	Zn	Al	Mg	Cu	Ti
AlSi7Mg	6.5-6.7%	≤0.1%	≤0.1%	Bal.	0.5-0.8%	≤0.05%	≤0.2%

How is 3D Printing Aluminum Based Alloy AlSi7Mg Powder Produced?
A method of preparation of aluminum alloy powder material, including the following steps: providing a molten metal or alloy liquid steps, using the fast-moving way, with the impact of gas will be described in the molten metal or alloy liquid broken into metal droplet steps, will become a solid powder the metal droplet condensation step, among them, the metal droplet than described in the molten metal or alloy liquid tiny. The aluminum base alloy powder obtained by this preparation method has a uniform chemical composition, a high proportion of amorphous composition, fine particles, small particle distribution range, regular shape, low oxygen content and high powder forming rate. It is suitable for the industrial production of powder raw materials and provides powder raw materials for the preparation of bulk aluminum base alloy by powder metallurgy and the preparation of amorphous aluminum base alloy protective coating by cold spraying.

Applications of 3D Printing Aluminum Based Alloy AlSi7Mg Powder:
Aluminum alloys are widely used in engineering structures and components where lightweight or corrosion resistance is required. Alloys composed mainly of aluminum have played a very important role in aerospace manufacturing since the advent of metal-clad aircraft.
AlSi7Mg powder can be used to manufacture lightweight functional components in the automotive and aerospace industries.
AlSi7Mg powder can be used in laser/electron beam additive manufacturing (SLM/EBM), powder metallurgy (PM), spraying and other processes.AlSi7Mg powder is widely used in aerospace parts, automotive parts, profile surface spraying, powder metallurgy and other fields.

Storage Condition of Aluminum Based Alloy Powder AlSi7Mg Powder:
The damp reunion will affect AlSi7Mg powder dispersion performance and using effects, therefore, aluminum-based alloy powder AlSi7Mg powder should be sealed in vacuum packing and stored in cool and dry room, the aluminum-based alloy powder AlSi7Mg powder can not be exposure to air. In addition, the AlSi7Mg powder should be avoided under stress.

Packing & Shipping of Aluminum Based Alloy Powder AlSi7Mg Powder:
We have many different kinds of packing which depend on the aluminum based alloy powder AlSi7Mg powder quantity.
Aluminum based alloy powder AlSi7Mg powder packing: vacuum packing, 100g, 500g or 1kg/bag, 25kg/barrel, or as your request.
Aluminum based alloy powder AlSi7Mg powder shipping: could be shipped out by sea, by air, by express, as soon as possible once payment receipt.
3D Printing Aluminum Based Alloy AlSi7Mg Powder插图

Alloy AlSi7Mg Powder Properties
Other Names	3D printing powder, AlSi7Mg, AlSi7Mg Powder
CAS No.	N/A
Compound Formula	AlSi7Mg
Molecular Weight	N/A
Appearance	N/A
Melting Point	N/A
Solubility in water	N/A
Density	N/A
Purity	99.90%
Particle Size	0-45μm, 0-53μm,15-45μm, 15-53μm, 45-105μm
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


Alloy AlSi7Mg Powder 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

Inquiry us

About 3D Printing Aluminum Based Alloy AlSi7Mg Powder:AlSi7Mg is a heat-treatable aluminum alloy widely used in the manufacture of lightweight functional components in the automotive and […]

3D Printing Stainless Steel SS316L Powder

About 3D Printing Stainless Steel SS316L Powder:
316 stainless steel powder has more carbon in it than 316L. This is easy to remember, as the L stands for “low.” But even though it has less carbon, 316L is very similar to 316 in almost every way. Cost is very similar, and both are durable, corrosion-resistant, and a good choice for high-stress situations.

If you want to know 316l powder price, please send inquiry to sales1@rboschco.com

In addition to chromium and nickel, these alloys contain molybdenum, which also makes them more corrosion resistant. Even greater corrosion resistance is delivered by 317L, in which molybdenum content increases to 3 to 4% from the 2 to 3% found in 316 and 316L.
Iron-base alloys containing different sufficient CHROMIUM to form a stable passive film on the surface.
10.5% is the qualifying concentration of Cr for an alloy to be called Stainless Steel.

316L stainless steel powder has excellent resistance to corrosion; High toughness and good ductility; Moderate strength, hardenable by cold work; High resistance to oxidation at elevated temperature; Low thermal conductivity; High coefficient of thermal expansion; Non-magnetic Not heat treatable; 316L stainless steel is the molybdenum that enhances corrosion resistance in environments rich in salt air and chloride – giving 316L powder the moniker of “marine grade” stainless steel. As long as the invisible film – or passive layer – remains intact, the metal remains stain-less and corrosion-resistant. Feel free to send an inquiry to get the latest price if you would like to buy 3D Printing Stainless Steel SS316L Powder in bulk.

Supply 3D printing stainless steel powder SS 316L

Main elements of stainless steel powder 316L:

Cr	Ni	Mo	Mn	Fe
16.00-18.00	10.0-14.0	2.0-3.0	≤2.00	Bal

Impurity elements of stainless steel powder 316L:

Si	P	S	C	O
≤1.00	≤0.04	≤0.03	≤0.03	≤0.05

Stainless steel powder 316L Morphology: Spherical

Stainless steel powder 316L Purity: 99.9%

Stainless steel powder 316L Particle size: 0-20μm, 15-45μm, 15-53μm, 53-105μm, 53-150μm, 105-250μm

Stainless steel powder 316L Appearance: grey powder

Stainless steel powder 316L Package: Aluminum bag,Vacuum packing

Stainless steel powder 316L Application: 3D printing metal powder

Stainless steel powder 316L Other applications: powder metallurgy(PM), injection molding(MIM), spray painting(SP) etc.

How is 3D Printing Stainless Steel SS316L Powder produced?
Type 316 steel is an austenitic chromium-nickel stainless steel containing 2% to 3% molybdenum. The molybdenum content improves corrosion resistance, resistance to pitting in chloride ion solutions, and high-temperature strength.

Stainless steel3D printing is produced by melting or laser sintering. There are two possible technologies for this material: DMLS and SLM. At Sculpteo, we use DMLS (Direct Metal Laser Sintering) technology, which is a laser sintering technology on EOS M280 machines for printing stainless steel.

Applications of 3D Printing Stainless Steel SS316L Powder:
Like aluminum and titanium, stainless steel can be used to 3D print complex designs that are normally impossible to accomplish. It can also produce large objects, owing to its strength. Thanks to 3D printing technology, stainless steel is soon to be put into even more uses.

As with traditional stainless steel, 3D-printed stainless steels find applications in a wide range of areas include:
Jewelry.
Tools.
Construction applications.
Dental caps.
Metal implants.
Industrial applications – designing functional components.
Decorative models like statues, medals and keys.
Military applications.

Storage Condition of Stainless Steel SS316L Powder:
Damp reunion will affect SS316L powder dispersion performance and using effects, therefore, stainless steel SS316L powder should be sealed in vacuum packing and stored in cool and dry room, the stainless steel SS316L powder can not be exposure to air. In addition, the stainless steel SS316L powder should be avoided under stress.

Packing & Shipping of Stainless Steel SS316L Powder:
We have many different kinds of packing which depends on the stainless steel SS316L powder quantity.
Stainless steel SS316L powder packing:vacuum packing, 100g, 500g or 1kg/bag, 25kg/barrel, or as your request.
Stainless steel SS316L powder shipping:could be shipped out by sea , by air, by express?as soon as possible once payment receipt.
3D Printing Stainless Steel SS316L Powder插图

Tungstenmolybdenummetals Nano Technology Co. Ltd. (Tungstenmolybdenummetals) 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.
If you are looking for high-quality 316L powder, please feel free to contact us and send an inquiry. ([email protected])

Stainless Steel Powders SS316L Properties
Other Names	Stainless Steel Powders, SS316 powder, SS316L powder
CAS No.	52013-36-2
Compound Formula	SS316L
Molecular Weight	N/A
Appearance	Grey black powder
Melting Point	N/A
Solubility in water	N/A
Density	7.9g/cm3
Purity	99.90%
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


Stainless Steel Powders SS316L 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

Inquiry us

About 3D Printing Stainless Steel SS316L Powder:316 stainless steel powder has more carbon in it than 316L. This is easy to remember, as the L stands for “low.” But […]

3D Printing Alloy Spherical Tungsten Carbide-Cobalt Cemented Alloy Powder

About 3D Printing Alloy WC-Co Powder:

Product name: Spherical Tungsten Carbide Powder

Product Specifications: 5-25μm, 15-45μm, 15-53μm, 45-75μm, 45-105μm, 75-150μm. (Can be customized according to customer requirements)

Powder properties: high purity (≥99.9%), low oxygen (≤300ppm), high sphericity (≥95%), smooth surface, no satellite ball, uniform particle size distribution, excellent flow performance (≤10.0s/50g), high loose density (≥7.0g/cm3) and vibration density (≥7.5g/cm3).

Applicable technology: Laser/electron beam additive manufacturing (SLM/EBM), laser direct deposition (DLD), hot isostatic powder molding (HIP), metal injection molding (MIM), powder metallurgy (PM), laser deposition (LC) and other processes.

Powder application: Tungsten-cobalt carbide is a kind of tungsten carbide composed of WC and Co metal, according to the different cobalt content can be divided into high cobalt (≥20%), medium cobalt (≥10%), low cobalt (≥3%) three types, cobalt for bonding phase, tungsten carbide for hard phase. Rf plasma spheroidized TUNGSTEN carbide and cobalt hard alloy powder has the characteristics of uniform distribution of cobalt elements, high sphericity, good fluidity, large loose density, dense particles inside, less hollow powder and so on. It can be used in cemented carbide, diamond tools, die casting mold, welding materials, vacuum coating, thermal spraying and so on.

Composition(percentage by mass)：

Storage Condition of Spherical Tungsten Carbide-Cobalt Cemented Alloy Powder:

Damp reunion will affect spherical tungsten carbide-cobalt cemented alloy powder dispersion performance and using effects. Therefore, spherical tungsten carbide-cobalt cemented alloy powder should be sealed in vacuum packing and stored in cool and dry room, the spherical tungsten carbide-cobalt cemented alloy powder can not be exposed to air. In addition, the spherical tungsten carbide-cobalt cemented alloy powder should be avoided under stress.

Packing & Shipping of Spherical Tungsten Carbide-Cobalt Cemented Alloy Powder:

We have many different kinds of packing which depends on the spherical tungsten carbide-cobalt cemented alloy powder quantity.

spherical tungsten carbide-cobalt cemented alloy powder packing:vacuum packing, 100g, 500g or 1kg/bag, 25kg/barrel, or as your request.

spherical tungsten carbide-cobalt cemented alloy powder shipping:could be shipped out by sea , by air, by express as soon as possible once payment receipt.

3D Printing Alloy Spherical Tungsten Carbide-Cobalt Cemented Alloy Powder插图1

3D Printing Alloy Spherical Tungsten Carbide-Cobalt Powder Properties
Other Names	Tungsten Carbide-Cobalt Powder
CAS No.	N/A
Compound Formula	WC-Co
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 Spherical Tungsten Carbide-Cobalt 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

Inquiry us

About 3D Printing Alloy WC-Co Powder:Product name: Spherical Tungsten Carbide PowderProduct Specifications: 5-25μm, 15-45μm, 15-53μm, 45-75μm, 45-105μm, 75-150μm. (Can be customized according to customer requirements) Powder properties: […]

How to improve the electrochemical performance of nano-silicon anode materials

How do we improve the electrochemical performance of nano-silicon anode material?

Many countries around the world attach great importance to the direction of research that focuses on developing and utilizing new energy sources. The battery’s performance is crucial for the growth of the new energy sector. There are many kinds of batteries as energy storage elements. The most significant research area is lithium-ion batteries. They can be used as energy batteries or power storage batteries. There are many uses for them. The capacity, efficiency of the battery, its rate and cycle retention of lithium-ion batteries are crucial indicators, and its capacity is the most crucial.

The lithium-ion battery’s components comprise positive and negative electrodes along with separators electrolytes, packaging materials, and separators. The enhancement of lithium-ion battery performance is closely related to the creation of positive and negative materials. There are three kinds of cathode materials: lithium iron phosphate and cobalt dioxide. Their cycling capacity is not more than 200mAh/g. The materials for anodes available include silicon-carbon and graphite. They also have different cycling ratios. The capacity is typically below 420mAh/g. growing the specific capacity of the anode material is an important area of research acknowledged worldwide. The theoretical specific capacity of nano-silicon can be at least 4200mAh/g. The low efficiency of its primary function and low retention of the cycle are the two main reasons as to why it isn’t extensively used.

In the present, the three methods listed below are mostly used to enhance the electrochemical efficiency of silicon-based anode materials:

(1) Nano silicon materials:

Nanometerization at zero-dimension is a way to limit the absolute volume change in silicon. One-dimensional nanometerization reduces the size of the volume changes in the radial direction in the course of charging and discharge. Two-dimensional nanometerization reduces the volume change perpendicularly to the film.

(2) Silicon alloy materials:

One is inert metals (Cu Fe, Mn and Ti, etc.). that don’t react with lithium. The conductivity of the inert phase of the metal is high and it speeds up Li+’s diffusion. It also functions as buffer matrix. The other kind of phase can react with lithium. The active metals (Al. Mg. Sn. Sb. etc.).) of the deintercalation reaction, the lithium-intercalation potential platforms of the active metals and silicon are quite different, and the lithium compound generated by the active metal intercalation can be used as a buffer matrix.

(3) Silicon carbon anode material:

The high electrical conductivity of nano silicon anode material and the superior robustness of carbon materials can be completely utilized by Nano Silicon. However, the low cycle retention rate of nano silicon anode materials remains one of the major issues hindering its application. By coating the surface of silicon particles with carbon or the conversion of a certain amount silicon into silicon carbide, the rate of cycle retention can be improved to a certain extent. It is obvious that silicon anode materials should be utilized with graphite anodes. The percentage of silicon used to achieve this goal should not exceed 15 15%.

Nano silicon Supplier

Tungstenmolybdenummetals (aka. Tungstenmolybdenummetals Nano Technology Co. Ltd. is a world-wide supplier and producer of chemical substances. They have over 12 years of experience manufacturing super-high-quality chemicals as well in the field of Nanomaterials. The company is developing many different materials. Our Nano silicon powder produced by our company has high purity, tiny particle size, and low impurity content. Send us an email , or click on the needed products for an inquiry.

How do we improve the electrochemical performance of nano-silicon anode material? Many countries around the world attach great importance to the direction of research that […]

What is the Use of Nano Fe3O4 Powder

What is the Use of Nano Fe3O4 Powder?

Nano Fe3O4 Powder is an excellent additive to make concrete and cement. Nano-sized particles have a filling effect and are not active in the hydration process. It is an incredibly versatile additive that can be used in various applications. In this post, we’ll review its features and its applications.

Application of nano-sized Fe3O4 powder

The Nano Fe3O4 powder, a kind of magnetic material, has a wide range of applications. It is used in rubber, concrete ceramics, metals , and metals. The high density and magnetic properties make it suitable for the construction industry and a variety of industrial processes. Nano Fe3O4 is also referred to as nanomagnetite.

Four bacteria strains were examined using Fe3O4 nanoparticles. It was discovered that they are highly efficient against both gram-positive and negative bacteria. It is unclear why gram-negative bacteria is more sensitive Fe3O4, but a study has revealed that nanoparticles that contain Fe3O4 have strong antibacterial properties against both types.

Nanometer Fe3O4 powder can be prepared by a simple process involving a polytetrafluoroethylene autoclave. The iron then dissolving in a solution containing an ethyl alcohol solution, urea, as well as other ingredients. The solution is then calcined at 400 degrees Celsius for 1 hour. The final product is then taken for further characterization.

Nano Fe3O4 powder preparation

It is possible to make nano Fe3O4 powders using a variety procedures, such as electrolysis and chemicalvapor deposition and thermal processing. Nano Fe3O4 powders have high saturation magnetic strength and have a high magnetic response. These properties make them attractive options for magnetic separation. This material also has a high coercivity, and it is also conductive.

Making a solution from Fe3O4 (and DEG) is the first step to creating Nano Fe3O4 powder. As the solution temperature increases the iron solution starts to boil. The viscosity of the iron solution will increase as a result. After the solution is centrifuged for 12 minutes at 14,000 RPM it’s repeated three times. The precipitate is dried at 70°C.

XRD analysis has revealed that Fe3O4 nanosheets are hexagonal or triangular, having edges that range between 80 and 150 nm. A HRTEM image of this sample shows crystallinity good, with an interplanar space of 0.296 nanometers. SAED pattern displays arrays of diffraction lines along the direction.

Nano Fe3O4 powder

It has been studied how nano-Fe3O4 powder impacts cementitious composites. The powder had an effect of filling that decreased total porosity. However, it was not active in the process of hydration. The powder has the potential to be used to be utilized in cementitious processes.

The antibacterial capacity of Fe3O4 nanoparticles against four different strains of bacterial was good: E. coli (P. vulgaris), S. aureus and S. Tularensis. Gram-negative bacteria showed more antibacterial properties than gram positive bacteria. Moreover, Fe3O4 nanoparticles displayed a strong antibacterial capacity against Escheriche coli as well as Xanthomonas.

Nanometer Fe3O4 powder is made in the laboratory by the urea method. This method produces iron oxide particles of 50-100 nanometers in diameter. The distribution of particles’ sizes is managed. To determine whether the product is magnetite-free samples can be collected and examined to determine the magnetic properties.

Nano Fe3O4 powder is magnetic and has magnetic properties.

A new magnetic nanocomposite has been made using Fe3O4 nanoparticles that are dissolved in PANI. The powder exhibits excellent magnetic susceptibility and saturation magnetization and is a great choice for use in electronic devices. It also exhibits an excellent absorption of microwaves. This means it is a great option for broadband shielding materials.

Four aspects impact the magnetization of Fe3O4: size, geometry, magnetic anisotropy, and geometries. At at room temperature Fe3O4 is ferrimagnetic. However changes in temperature can alter its ferromagnetic alignment , as well as its strength. As temperatures increase the magnetic properties of Fe3O4 Powder change. This could lead to decreased magnetization and supermagnetic behavior.

An aqueous phase coprecipitation technique was employed to investigate the magnetic properties of Nano Fe3O4 Powder. The Fe 3 O 4 nanoparticles are about 228 nanometers in diameter . They also have a Polydispersity Index of (PdI) which is 0.402. The more homogeneous particle, the smaller the PdI.

Nano Fe3O4 powder may be reused

Nano Fe3O4 powder is an eco-friendly alternative to conventional pickle liquor. The process involves the use of low-grade iron oxide powder as the primary material and an alkaline Liq to act as an oxygenant. Once the waste liquor is prepared and stirred, it is then mixed using an emulsion machine that is high-speed. The alkaline liquid is then able to be added to the liquor. The mixture is then dried for four hours in a vacuum.

Hydrothermal reactions that took place in 0.1 M NaOH (AR) were used to produce the Fe3O4@Fritillaria NPPS. The particles were separated using magnets and replaced using a solution of Mg (NO3)2$6H2O or Al(NO3)3$9H2O and urea following the making.

The major supplier of nano Fe3O4 Powder

Tungstenmolybdenummetals material supplier (Tungstenmolybdenummetals) is a professional oxide powder supplier with more than 12 years experience in research and development. We accept payments through Credit Card, T/T, West Union, and Paypal. Trunnano is able to ship items out of the country through FedEx, DHL or by air to customers.

If you’re looking for top-quality nano Fe3O4 powder, please feel free to contact us , and we will send an inquiry.

What is the Use of Nano Fe3O4 Powder? Nano Fe3O4 Powder is an excellent additive to make concrete and cement. Nano-sized particles have a filling […]

Overview of Nano Fe3O4 Powder

A brief overview of Nano Fe3O4 powder

Iron oxide(II,III)(Fe3O4) is a highly insoluble and thermally stable source of iron that is suitable for optical, glass and ceramic applications. Oxide doesn’t conduct electricity. However, certain oxides that have perovskite’s structure conduct electricity through the cathodes of solid oxide fuel cells as well as oxygen generation systems. They are compounds containing at most one oxygen anion as well as one metal cation. They are usually insoluble with liquid solutions(water)and are extremely solid, making them suitable in ceramic structures. It is similar to making clay bowls to make advanced electronic equipment, as well as lightweight structural elements in aerospace and electrochemical applications. For example, fuel. They possess ionic conductivity. Metal oxides are alkaline and high-purity (99.999%) iron oxide (FeO) anhydrides, so they are able to undergo redox reactions using acids as well as strong reduction agents. Iron oxide can also be created into particles, blocks, powders, sputtering targets tablets and nano powders.In most cases,iron oxide is typically available immediately.High purity,submicron and nano powder varieties are possible. Include other technical, research and safety (MSDS) details. Fe3O4 is produced by Schikorr reaction.This reaction converts iron (II) hydroxide (Fe(OH)2)into iron (II,III) oxide (Fe3O4).Under anaerobic conditions, ferrous hydroxide (Fe(OH)2) is oxidized in water, resulting in magnetite as well as molecular hydrogen. Skicor’s reaction provides the background.

What are the uses of nano Fe3O4 powder?

Iron oxide Fe3O4 powder,usually called iron oxide black, magnetite and black iron oxide can be used in many different fields. For instance: iron oxide (II,III) is utilized as a dark pigment also called Martian black.

To act as a catalyst for the Haber process.

Effective in the water gas shift reaction.

For MRI scans, Fe3O4 nanoparticles can be employed in contrast.

It is a way to protect steel from rusting.

It is a component of aluminate used to cut steel.

The iron oxide Fe3O4 powder can be described as ferromagnetic.If the radius of the powder is at the nanometer level they are referred to as ferromagnetic particles.

1.Iron oxide Fe3O4 could be utilized to create magnetic recording materials and magnetic separators with high gradients.

2.Iron Fe3O4 is a powder that can be used for transporting various substances in pharmaceuticals in order to build a magnetic-targeted drug delivery system. It is also used for the separation of magnetic immune cells as well as nuclear magnetic resonance imaging, and other aspects.

3. Useful for precision instruments for gas seals, vacuum seals, etc.

The principal supplier of Nano Fe3O4 Powder

Tungstenmolybdenummetals material supplier. (Tungstenmolybdenummetals), is a professional supplier of oxide powders that has more than 12 years of of experience in chemical product development and research. We accept payment by Credit Card and Paypal. Trunnano will ship the products to customers in other countries via FedEx, DHL, by either by air or by sea.

We offer high-quality boron carbonide granules. Contact us to inquire.

A brief overview of Nano Fe3O4 powder Iron oxide(II,III)(Fe3O4) is a highly insoluble and thermally stable source of iron that is suitable for optical, glass […]

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