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Guangzhou Zhongli Technology Co., Ltd

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City:guangzhou

Country/Region:china

Contact Person:MrsAin Qiu

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China Low Carbon Iron Metal Powder Fe-C Sinter Ready For High Strength Components wholesale

Low Carbon Iron Metal Powder Fe-C Sinter Ready For High Strength Components

Name: Low Carbon Iron Metal Powder FeC Sinter Ready For High Strength Components
Brand: Zhongli
Price: 1 USD

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Brand Name :Zhongli

Model Number :SSP-01

Certification :ISO,CE,MSDS

Place of Origin :China

MOQ :1kg

Payment Terms :L/C,T/T,Western Union,MoneyGram

Supply Ability :15-20ton per month

Delivery Time :within 15 days

Packaging Details :plastic+drum

Fe-Ni-Cr (17-4PH, 316L) :3D Printing

Density (g/cm³) :7.4–7.9 (varies by alloy)

Hardness (HRC) :20–65 (depends on heat treatment)

Tensile Strength (MPa) :300–1,500+

Max Operating Temp. (°C) :500–1,200 (alloy-dependent)

Corrosion Resistance :Moderate (improves with Cr/Ni)

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Product Description

Unlocking the Potential of Low Carbon Iron Powder Fe-C: Sinter-Ready for High Strength Components

In the rapidly evolving world of manufacturing and metallurgy, the demand for high-strength components is continually growing. As industries strive for sustainable practices, the use of low carbon iron powder Fe-C sinter-ready materials has emerged as a game-changer.

Understanding Low Carbon Iron Powder Fe-C

Low carbon iron powder Fe-C is a specialized material designed for sintering applications. The sintering process involves compacting and forming a solid mass of material using heat, without melting it to the point of liquefaction. This method is integral in manufacturing high-strength components, especially in the automotive and aerospace sectors.

Key Characteristics

High Purity: Low carbon iron powder Fe-C is characterized by its high purity, ensuring minimal impurities that can affect the strength and durability of the final product.
Controlled Particle Size: The powder is engineered to have a consistent particle size, which is crucial for uniform sintering and achieving desired mechanical properties.
Low Carbon Content: As the name suggests, this powder has a reduced carbon content, which is pivotal in minimizing carbide formation that can compromise the toughness of the components.

Property	Iron-Based Alloy Powders	Stainless Steel (316L)	Nickel Alloys (Inconel 625)	Titanium (Ti-6Al-4V)
Density (g/cm³)	7.4–7.9 (varies by alloy)	7.9	8.4	4.4
Hardness (HRC)	20–65 (depends on heat treatment)	25–35	20–40 (annealed)	36–40
Tensile Strength (MPa)	300–1,500+	500–700	900–1,200	900–1,100
Corrosion Resistance	Moderate (improves with Cr/Ni)	Excellent	Excellent	Excellent
Max Operating Temp. (°C)	500–1,200 (alloy-dependent)	800	1,000+	600
Cost (vs. Pure Fe = 1x)	1x–5x (alloy-dependent)	3x–5x	10x–20x	20x–30x

Injection molding of powder injection molding technology

Compared with traditional process, with high precision, homogeneity, good performance, low production cost, etc. In recent years, with the rapid development of MIM technology, its products have been widely used in consumer electronics, communications and information engineering, biological medical equipment, automobiles, watch industry, weapons and aerospace and other industrial fields.

Grade	Chemical Nominal Composition(wt%)
Alloy	C	Si	Cr	Ni	Mn	Mo	Cu	W	V	Fe
316L			16.0-18.0	10.0-14.0		2.0-3.0	-	-	-	Bal.
304L			18.0-20.0	8.0-12.0		-	-	-	-	Bal.
310S			24.0-26.0	19.0-22.0		-	-	-	-	Bal.
17-4PH			15.0-17.5	3.0~5.0		-	3.00-5.00	-	-	Bal.
15-5PH			14.0-15.5	3.5~5.5		-	2.5~4.5	-	-	Bal.
4340	0.38-0.43	0.15-0.35	0.7-0.9	1.65-2.00	0.6-0.8	0.2-0.3	-	-	-	Bal.
S136	0.20-0.45	0.8-1.0	12.0-14.0	-		-	-	-	0.15-0.40	Bal.
D2	1.40-1.60		11.0-13.0	-		0.8-1.2	-	-	0.2-0.5	Bal.
H11	0.32-0.45	0.6-1	4.7-5.2	-	0.2-0.5	0.8-1.2	-	-	0.2-0.6	Bal.
H13	0.32-0.45	0.8-1.2	4.75-5.5	-	0.2-0.5	1.1-1.5	-	-	0.8-1.2	Bal.
M2	0.78-0.88	0.2-0.45	3.75-4.5	-	0.15-0.4	4.5-5.5	-	5.5-6.75	1.75-2.2	Bal.
M4	1.25-1.40	0.2-0.45	3.75-4.5	-	0.15-0.4	4.5-5.5	-	5.25-6.5	3.75-4.5	Bal.
T15	1.4-1.6	0.15-0.4	3.75-5.0	-	0.15-0.4	-	-	11.75-13	4.5-5.25	Bal.
30CrMnSiA	0.28-0.34	0.9-1.2	0.8-1.1	-	0.8-1.1	-	-	-	-	Bal.
SAE-1524	0.18-0.25	-	-	-	1.30-1.65	-	-	-	-	Bal.
4605	0.4-0.6		-	1.5-2.5	-	0.2-0.5	-	-	-	Bal.
8620	0.18-0.23	0.15-0.35	0.4-0.6	0.4-0.7	0.7-0.9	0.15-0.25	-	-	-	Bal.

Powder specification:

Particle Size	Tapping Density	Particle Size Distribution(μm)
	(g/cm³)	D10	D50	D90
D50:12um	＞4.8	3.6- 5.0	11.5-13.5	22-26
D50:11um	＞4.8	3.0- 4.5	10.5-11.5	19-23

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FAQ

1. What types of stainless steel powders are used in 3D printing?

Common grades include 316L (excellent corrosion resistance), 17-4 PH (high strength and hardness), 304L (general-purpose use), and 420 (wear resistance). Each grade has specific properties suited for different applications.

2. What is the typical particle size for stainless steel powders in 3D printing?

The particle size typically ranges from 15 to 45 micrometers (µm). Spherical particles are preferred for better flowability and packing density.

3. Can stainless steel powders be reused?

Yes, unused powder can often be recycled by sieving and blending with fresh powder. However, excessive reuse can degrade powder quality, so regular testing is recommended.

4. What safety precautions should be taken when handling stainless steel powders?

Avoid inhalation or skin contact by using gloves, masks, and protective clothing.
Store powders in a dry, airtight container to prevent moisture absorption.
Handle powders in a well-ventilated area or under inert gas to minimize explosion risks.

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