2mm GR1 Seamless Titanium Capillary Tube for Medical
USD $10 - $100 /Piece
Min.Order:1 Piece
Baoji Yinggao Metal Materials Co., Ltd.
2mm GR1 Seamless Titanium Capillary Tube for Medical is a small, thin-walled tube made of titanium metal. It is mainly used in applications requiring high corrosion resistance, high strength and light weight.
A capillary is a thin tube with a small inner diameter, usually between a few microns and a few millimeters. It is widely used in several industries such as aerospace, medical, chemical and analytical instrumentation.
Titanium has excellent corrosion resistance, high strength and light weight, making it an ideal material for capillary applications. Titanium capillaries are resistant to corrosion in a variety of corrosive environments, including seawater, acids, and alkalis. Titanium's lightweight properties make it easier to handle and install, making it easier to handle than other metals.
In specific applications, 2mm GR1 Seamless Titanium Capillary Tube for Medical is used for precise control of fluids or gases, such as in chromatography, analytical instruments and medical equipment. They can be used to transport liquids or gases and can be used in heat exchangers or condensers due to titanium's good thermal conductivity.
Parameter:
Material: Pure titanium
Grade: GR1
Outer diameter:2mm
Wall thickness: 0.4mm
Length: Max. 6000mm
Surface treatment: polished
Certificates: ISO9001:2015
How to ensure the ultra-fine size of titanium capillary?
1. Precision processing equipment: use high-precision processing equipment, such as CNC machine tools or laser cutting machines, to achieve precise cutting and processing of titanium materials. These devices have a high degree of automation and control precision, which can ensure that the diameter and wall thickness of the capillary are controlled within the required extremely fine size range.
2. Fine-cavity mold and process: The precision molding of titanium materials can be realized by adopting a specially designed fine-cavity mold and process flow. The mold design takes into account the size and shape requirements of the titanium capillary to ensure dimensional control during the molding process.
3. Accurate measurement and inspection: Use high-precision measuring tools and inspection equipment to accurately measure and verify the size of the titanium capillary. For example, use tools such as microscopes, scanning electron microscopes (SEM) or optical image measuring machines to measure dimensions and compare them to design specifications. This helps to spot any dimensional deviations or defects and correct them promptly.
4. Fine process control: In the process of manufacturing titanium capillary, the processing parameters and process conditions are strictly controlled, including temperature, pressure, cutting speed, etc. Dimensional stability and consistency of the capillary can be ensured through accurate control of processing parameters.
5. Quality management system: establish a sound quality management system, including the whole process of quality control from raw material procurement to production process. Strict quality inspection and monitoring are used to ensure that each manufacturing step meets the specification requirements to guarantee the dimensional quality of the titanium capillary.
Features
1. Capillary effect: Due to the very small diameter of the titanium capillary, the liquid will exhibit a capillary effect in it. This means that liquids can exhibit special flow behaviors in pipes, such as self-priming, condensation, and lifting. The capillary effect makes titanium capillaries very useful in specific applications, such as microfluidics, liquid chromatography and analytical chemistry.
2. Corrosion Resistance: Titanium is a metal with excellent corrosion resistance. Titanium capillaries are resistant to a variety of corrosive media, including acids, bases, salt water, and oxides. This makes titanium capillaries versatile for applications involving corrosive environments or chemicals.
3. Strength and Lightweight: Despite titanium's excellent strength, its relatively low density makes titanium capillary a lightweight tubing choice. This enables it to reduce overall weight in applications that require strength and rigidity, such as structures and equipment in the aerospace sector.
4. Biocompatibility: Titanium is a biocompatible material that is well tolerated by human tissues and organisms. This makes titanium capillaries widely used in medical devices and biomedical fields, such as artificial joints, implantable devices and biosensors.
Applications
1. Orthopedic implants: Due to the good biocompatibility and mechanical properties of titanium materials, titanium capillaries are widely used in the manufacture of orthopedic implants, such as artificial joints, bone plates, screws, and fusion devices. These implants can be used in procedures such as repairing broken bones, joint replacements and bone reconstruction.
2. Dental applications: Titanium capillaries are also widely used in the dental field. For example, titanium implants are used for artificial implantation of teeth, and dental brackets and fixtures use titanium capillaries for restoration and support.
3. Cardiac stents: Titanium capillaries can be used to create heart stents for expanding and supporting narrowed or blocked coronary arteries. The stent could help restore blood flow and reduce symptoms in heart patients.
4. Neural Implants: Titanium capillaries are used in the manufacture of neural repair implants to support and promote nerve regeneration. These implants can be used to repair damaged peripheral and central nervous systems, helping patients regain function.
5. Medical devices and tools: Titanium capillaries are also used in the manufacture of various medical devices and tools, such as surgical forceps, needle tubes, catheters, and microsurgical tools. These tools usually require high strength, light weight and corrosion resistance, and titanium materials can meet these requirements.
6. Medical device coatings: The surface of titanium capillaries can be specially treated and coated to increase their biocompatibility and functionality. For example, surface coatings can improve the implant's adhesion to surrounding tissue, reducing infection and rejection.