Titanium Bar Price - Buy Titanium Round/Square Bar

AEM METAL Titanium Bars: Unmatched Durability and Performance

At AEM METAL, we are dedicated to excellence and innovation in the production of titanium bars. As a leading supplier, our company ensures superior quality through advanced manufacturing techniques and rigorous quality control processes. Our commitment to precision and durability sets us apart in the industry.

Our titanium bars are renowned for their remarkable strength, lightweight properties, and exceptional corrosion resistance. By utilizing the finest raw materials and adhering to stringent pbaruction standards, AEM METAL delivers products that offer unparalleled performance and longevity. Choose AEM METAL for titanium bars that exemplify quality and reliability.

Titanium Bar Specifications

Size	Side: 3 mm - 600 mm
Material	Gr.1, Gr.2, Gr.4, Gr.5, Gr.7, Gr.12, Gr.23, etc.
Standard	ASTM B348, ASTM F67, AMS 4928, ASTM F136,AMS 2631b, etc.
Surface	Black, pickling, sand-blasting, polished
Condition	Cold rolled(Y), hot rolled(R), annealed (M), quenching(C)
Shape	Square bar, round bar, hexagonal bar.

Chemical Requirements of Titanium Bar (Nominal %)

	N	C	H	Fe	O	Al	V	Pa	Mo	Ni	Ti
Gr. 1	0.03	0.08	0.015	0.2	0.18	/	/	/	/	/	bal
Gr. 2	0.03	0.08	0.015	0.3	0.25	/	/	/	/	/	bal
Gr. 3	0.05	0.08	0.015	0.3	0.35	/	/	/	/	/	bal
Gr. 4	0.05	0.08	0.015	0.5	0.4	/	/	/	/	/
Gr. 5	0.05	0.08	0.015	0.4	0.2	5.5~6.75	3.5~4.5	/	/	/	bal
Gr. 7	0.03	0.08	0.015	0.3	0.25	/	/	0.12~0.25	/	/	bal
Gr. 9	0.03	0.08	0.015	0.25	0.15	2.5~3.5	2.0~3.0	/	/	/	bal
Gr.12	0.03	0.08	0.015	0.3	0.25	/	/	/	0.2~0.4	0.6~0.9	bal

Mechanical Requirements of Titanium Bar

Grade		Tensil Strength (min)		Yeild Strength (min)		Elongation(%)
Grade		ksi	MPa	ksi	MPa	Elongation(%)
1	UNSR50250	35	240	20	138	24
2	UNSR50400	50	345	40	275	20
3	UNSR50550	65	450	55	380	18
4	UNSR50700	80	550	70	483	15
5	UNSR56400	130	895	120	828	10
7	UNSR52400	50	345	40	275	20
9	UNSR56320	90	620	70	438	15
12	UNSR53400	70	438	50	345	18

Why Choose AEM METAL-Key Benefits of Our Titanium Bar

Unmatched Quality

Our titanium bars are manufactured to the highest industry standards, ensuring exceptional quality and performance.

Superior Strength

Engineered for maximum durability, our titanium bars offer outstanding strength-to-weight ratios.

Precision Engineering

Each bar is crafted with meticulous attention to detail, ensuring precise dimensions and reliable performance.

Custom Solutions

We offer tailored titanium bar solutions to meet your specific requirements, ensuring you get exactly what you need.

Fast Delivery

Our efficient production and logistics ensure timely delivery of your titanium bars, keeping your projects on schedule.

How to Manufacture Titanium Bar

Raw Material Preparation

Cutting Processing

Forming Processing

Precision Processing

Surface Treatment

Raw Material Preparation

The first step in manufacturing titanium bars involves acquiring high-quality titanium materials. It is crucial to ensure that the raw titanium has the desired purity and minimal impurity content. This step typically involves the selection of titanium sponge or titanium ingots, which are then inspected to verify compliance with the required standards.

Cutting Processing

Once the high-quality titanium material is procured, it is cut into the required lengths. This cutting process is usually performed using titanium alloy tools to ensure high cutting accuracy and superior surface quality. Cutting tools designed for titanium are used to handle its hardness and prevent any material deformation during the process.

Forming Processing

After cutting, the titanium bars undergo forming processing to achieve the desired shape and size. This can be done through various methods such as:

Hot Rolling: Heating the titanium to a high temperature and then rolling it into bars.
Cold Extrusion: Forcing the titanium through a die to shape it at room temperature.
Forging: Shaping the titanium using compressive forces, often at elevated temperatures, to achieve the desired bar form.

Each method has its own advantages, with hot rolling being ideal for large-scale production, cold extrusion providing excellent surface finish, and forging offering superior mechanical properties.

Precision Processing

To further refine the formed titanium bars, precision processing is carried out. This includes operations such as:

Drilling: Creating precise holes in the titanium bars.
Milling: Removing material from the surface to achieve the desired dimensions.
Turning: Rotating the bar while a cutting tool removes material to create the final shape.

These processes enhance the surface quality and dimensional accuracy of the titanium bars, ensuring they meet stringent specifications.

Surface Treatment

Surface treatment is essential for improving the corrosion resistance and overall finish of titanium bars. This step typically involves:

Pickling: Removing the oxide layer and impurities from the surface using acid solutions.
Polishing: Smoothing the surface to achieve a fine finish and improve aesthetic appeal.

These treatments enhance the bars' resistance to corrosion and improve their surface quality, making them suitable for various demanding applications.

Send inquiry Now

Commitment to Quality Assurance

Visual Inspection

A thorough visual inspection is the first step in quality control. Inspectors examine the titanium bars for any surface defects, such as cracks, scratches, or discolorations. Visual inspection helps identify obvious issues that could affect the bar's performance and ensures the bars meet aesthetic and surface quality standards.

Dimensional Measurement

Accurate dimensional measurements are critical to ensure that the titanium bars meet specified size requirements. Tools such as micrometers, calipers, and coordinate measuring machines (CMM) are used to measure the diameter, length, and any other critical dimensions of the bars. This ensures that the bars conform to the required tolerances and specifications.

Chemical Composition Analysis

To verify the purity and alloy composition of the titanium bars, a chemical analysis is performed. Techniques such as X-ray fluorescence (XRF) spectroscopy or optical emission spectrometry (OES) are commonly used. This analysis ensures that the bars contain the correct alloying elements and meet the required chemical composition standards.

Mechanical Testing

Mechanical properties of the titanium bars are tested to ensure they meet the necessary strength and durability standards. Common tests include:

Tensile Testing: Determines the bar's tensile strength, yield strength, and elongation.
Hardness Testing: Measures the hardness of the bar using methods such as Rockwell or Vickers hardness tests.
Impact Testing: Assesses the bar's toughness and ability to withstand sudden forces.

Ultrasonic Testing (UT)

Ultrasonic testing is a non-destructive method used to detect internal flaws or inconsistencies within the titanium bars. High-frequency sound waves are passed through the bar, and the reflections are analyzed to identify any internal defects, such as voids or inclusions. This ensures the structural integrity of the bars.

Eddy Current Testing (ECT)

Eddy current testing is another non-destructive testing method used to identify surface and near-surface defects. By inducing electrical currents in the titanium bar and measuring the response, inspectors can detect any anomalies or inconsistencies that could indicate defects.

Surface Roughness Testing

Surface roughness testing measures the finish of the titanium bar's surface. Using profilometers or other surface roughness measuring instruments, the surface texture is quantified to ensure it meets the required smoothness and finish standards.

Corrosion Testing

Corrosion resistance is a critical property of titanium bars. Corrosion testing involves exposing the bars to corrosive environments and measuring their resistance to corrosion over time. This ensures that the bars will perform well in demanding applications where corrosion resistance is vital.

Fatigue Testing

Fatigue testing evaluates the titanium bar's ability to withstand cyclic loading and unloading over time. This test is crucial for applications where the bars will experience repeated stress cycles, ensuring their long-term durability and reliability.

Versatile Applications of Titanium Bar

Medical Applications

Titanium bars play a crucial role in the medical field, particularly in orthopedics. Orthopedic surgeons prefer titanium alloy bars for bone replacements due to their exceptional strength and stability. These bars are used to replace broken bones, providing patients with robust and reliable support. For pediatric orthopedics, expanding titanium bars are invaluable as they can be attached to joints and grow with the child's bones, reducing the need for multiple surgeries. These expanding bars are also suitable for larger bone replacements in adults, such as leg bones, offering long-term solutions with minimal surgical intervention.

Aerospace Applications

The aerospace industry relies heavily on titanium bars for their high strength-to-weight ratio and ability to withstand extreme temperatures and conditions. Titanium bars are integral to the structure and skin of aircraft, including airframes, landing gear components, and engine parts. They are also critical in space exploration vehicles and satellites, where their lightweight nature and resistance to extreme temperatures ensure reliability and performance under demanding conditions.

Automotive Applications

In the automotive sector, titanium bars are essential for enhancing vehicle performance, particularly in high-performance racing cars and luxury vehicles. Titanium bars help reduce weight, improve fuel efficiency, and enhance engine performance. They are also used in exhaust systems and suspension components due to their excellent resistance to corrosion and fatigue, contributing to the longevity and reliability of automotive parts.

Sport Applications

Titanium bars are widely used in sports equipment, offering athletes lightweight yet durable options that enhance performance. They are found in bicycle frames, golf clubs, and hiking equipment, where their low density makes them easier to carry without compromising strength. This combination of lightness and durability helps athletes achieve better performance while maintaining the reliability of their equipment.

Marine Applications

Titanium bars are invaluable in marine environments due to their excellent corrosion resistance in saltwater. They are used in boat hulls, propeller shafts, and underwater pipelines, where they provide long-lasting durability and reliability. This makes them ideal for critical marine structures and equipment that must withstand harsh conditions.

Industrial Equipment

In industrial settings, titanium bars are used in chemical processing equipment, offshore oil rigs, and power generation plants. Their resistance to corrosion and high temperatures makes them suitable for demanding industrial applications, ensuring longevity and minimal maintenance requirements.

Electronics

The electronics industry utilizes titanium bars for their non-magnetic properties and durability. They are employed in consumer electronics such as smartphones and laptops, where their robust nature ensures the longevity and reliability of electronic devices.

Architecture and Design

Titanium bars are also used in architectural structures and sculptures due to their aesthetic appeal, corrosion resistance, and longevity. They provide a modern, sleek look while offering the structural integrity needed for long-lasting architectural projects.

Request A Quote

Exceptional Pbaruct Features Compared to Competitors

Superior Strength-to-Weight Ratio

Compared to Steel: Titanium bars are significantly lighter than steel while offering comparable or greater strength. This makes them ideal for aerospace and automotive applications where weight reduction is critical without compromising structural integrity.
Compared to Aluminum: Titanium bars are much stronger than aluminum, providing superior load-bearing capacity. This is crucial in applications that demand high strength and low weight.

Outstanding Corrosion Resistance

Compared to Stainless Steel: While stainless steel is resistant to corrosion, titanium bars offer superior resistance, especially in harsh environments like saltwater and acidic conditions. This ensures longer life and less maintenance in marine and chemical processing applications.
Compared to Aluminum: Aluminum is susceptible to corrosion in marine and industrial environments. Titanium bars, however, remain unaffected, making them more durable and reliable over time.

Biocompatibility

Compared to Stainless Steel and Cobalt-Chromium Alloys: Titanium bars integrate seamlessly with human bone and tissue, minimizing the risk of adverse reactions. This biocompatibility makes them the preferred choice for medical implants, unlike stainless steel and cobalt-chromium alloys which may cause more frequent complications.

High Temperature Tolerance

Compared to Aluminum: Aluminum loses strength at high temperatures, whereas titanium maintains its integrity, making it suitable for aerospace and high-temperature industrial applications.
Compared to Many Steels: While some high-temperature steels can withstand heat, titanium bars offer a better balance of weight and temperature resistance, crucial for aerospace components and engines.

Excellent Fatigue Resistance

Compared to Aluminum: Aluminum is prone to fatigue failure under repeated stress cycles. Titanium bars, however, exhibit superior fatigue resistance, making them more reliable for automotive suspension systems and aerospace components that undergo constant stress.
Compared to Steel: While steel also has good fatigue resistance, titanium bars offer this property at a much lower weight, providing an advantage in applications where reducing mass is critical.

Low Density

Compared to Steel: Titanium bars are much lighter than steel, significantly reducing the weight of structures and components in aerospace and automotive applications. This weight reduction improves fuel efficiency and overall performance.
Compared to Nickel-Based Alloys: Titanium provides similar strength with lower density, offering performance benefits without the added weight.

Talk To Our Expert

Frequently Asked Questions About Titanium Bar

Can titanium bars be customized for specific applications?

Yes, titanium bars can be customized to meet specific application requirements. Through alloying, varying the manufacturing process, or applying different surface treatments, titanium bars can be tailored to achieve desired properties such as enhanced strength, corrosion resistance, and specific dimensions.
What are the environmental benefits of using titanium bars?

Titanium is a highly recyclable material, making titanium bars an environmentally friendly choice. Their long lifespan and resistance to corrosion reduce the need for frequent replacements, minimizing environmental impact. Additionally, the lightweight nature of titanium bars contributes to energy savings in applications like aerospace and automotive, further enhancing their environmental benefits.
Can titanium bars be welded, and what are the challenges?

Yes, titanium bars can be welded, but the process requires specific techniques to prevent contamination. Welding titanium requires an inert gas shield, typically argon, to protect the weld area from atmospheric contamination. The main challenges include maintaining a clean environment and ensuring proper shielding to avoid defects such as oxidation and embrittlement.
Are there any special storage requirements for titanium bars?

Titanium bars should be stored in a clean, dry environment to prevent contamination and potential corrosion. They should be kept away from chemicals, moisture, and direct sunlight. Proper storage conditions help maintain the material's integrity and performance characteristics. It is also important to handle titanium bars with care to avoid scratches and dents that could affect their structural properties.
How are titanium bars packaged and transported to ensure their quality is maintained?

Titanium bars are packaged carefully to prevent damage during transportation. They are typically wrapped in protective materials such as foam, plastic, or bubble wrap and then placed in sturdy, moisture-resistant wooden crates or metal containers. This packaging protects them from physical damage, contamination, and corrosion during shipping. Additionally, each package is labeled with handling instructions to ensure proper care is taken during loading, transport, and unloading.
How do titanium bars perform in cryogenic conditions?

Titanium bars perform exceptionally well in cryogenic conditions, maintaining their strength and toughness at extremely low temperatures. This makes them suitable for use in applications like cryogenic storage tanks, superconducting magnets, and other equipment that operates in cryogenic environments. Unlike many other materials that become brittle at low temperatures, titanium remains ductile and reliable.
What are the machining challenges associated with titanium bars?

Machining titanium bars can be more challenging compared to other metals due to titanium's high strength and low thermal conductivity. Specialized cutting tools, cooling systems, and machining techniques are often required to achieve precision and maintain tool longevity during titanium bar processing.
What technical support and service can I expect from your team?

Our technical support team is dedicated to assisting you throughout the entire process, from selecting the right titanium bars to providing after-sales service.
What shipping methods do you use to deliver pbaructs?

We typically opt for UPS, DHL, or FedEx. However, for shipments over 100 kg, sea transportation is an option. Feel free to specify your preferred shipping method.
How long does it usually take for goods to be delivered?

Delivery typically takes 3-4 weeks, subject to the product's complexity, quantity, and order volume. Please also understand that if transportation volume accumulates during holidays, the delivery time may be slower.

Request a Titanium Quote Now

No matter what kind of titanium product you require, our vast experience enables us to manufacture it.

Get a quote now or let us know what you're looking for and we will get back to you soon!

Titanium Bar

AEM METAL Titanium Bars: Unmatched Durability and Performance

Titanium Bar Specifications

Chemical Requirements of Titanium Bar (Nominal %)

Mechanical Requirements of Titanium Bar

Why Choose AEM METAL-Key Benefits of Our Titanium Bar

Unmatched Quality

Superior Strength

Precision Engineering

Custom Solutions

Fast Delivery

How to Manufacture Titanium Bar

Raw Material Preparation

Cutting Processing

Forming Processing

Precision Processing

Surface Treatment

Commitment to Quality Assurance

Visual Inspection

Dimensional Measurement

Chemical Composition Analysis

Mechanical Testing

Ultrasonic Testing (UT)

Eddy Current Testing (ECT)

Surface Roughness Testing

Corrosion Testing

Fatigue Testing

Versatile Applications of Titanium Bar

Medical Applications

Aerospace Applications

Automotive Applications

Sport Applications

Marine Applications

Industrial Equipment

Electronics

Architecture and Design

Exceptional Pbaruct Features Compared to Competitors

Superior Strength-to-Weight Ratio

Outstanding Corrosion Resistance

Biocompatibility

High Temperature Tolerance

Excellent Fatigue Resistance

Low Density

Frequently Asked Questions About Titanium Bar

You May Like