Stainless Steel 316Ti 1.4571 coiled tubing capillary tubing

Element	% Present (in product form)
	C, H, P	L	TW	TS
Carbon (C)	0.08	0.08	0.08	0.08
Silicon (Si)	1.00	1.00	1.00	1.00
Manganese (Mn)	2.00	2.00	2.00	2.00
Phosphorous (P)	0.045	0.045	0.0453)	0.040
Sulfur (S)	0.0151)	0.0301)	0.0153)	0.0151)
Chromium (Cr)	16.50 – 18.50	16.50 – 18.50	16.50 – 18.50	16.50 – 18.50
Nickel (Ni)	10.50 – 13.50	10.50 – 13.502)	10.50 – 13.50	10.50 – 13.502)
Molybdenum (Mo)	2.00 – 2.50	2.00 – 2.50	2.00 – 2.50	2.00 – 2.50
Titanium (Ti)	5xC to 070	5xC to 070	5xC to 070	5xC to 070
Iron (Fe)	Balance	Balance	Balance	Balance

Capillary tubing is a slender and delicate tube that is used in various scientific and medical applications. It is typically made of glass or plastic, with a narrow diameter that allows for precise control over the flow of liquids or gases. Capillary tubing can be found in laboratories, hospitals, and research facilities around the world. One of the most common uses for capillary tubing is in chromatography, a technique used to separate different components of a mixture. In this process, the capillary tube acts as a column through which the sample passes. The different components are separated based on their affinity for certain chemicals or materials within the column. Capillary tubing also plays an important role in microfluidics, which involves manipulating small volumes of fluids at the micrometer scale. This technology has numerous applications in fields such as biotechnology and nanotechnology. In addition to its scientific uses, capillary tubing can also be found in medical devices such as catheters and IV lines. These tubes allow healthcare professionals to deliver medications or fluids directly into a patient’s bloodstream with precision and accuracy. Overall, capillary tubing may seem like a small component but it has significant impact across many industries due to its unique properties and versatility.

			Product Form
			C	H	P	L	L	TW	TS
Thickness (mm) Max			8	12	75	160	2502)	60	60
Yield Strength		Rp0.2 N/mm2	2403)	2203)	2203)	2004)	2005)	1906)	1906)
		Rp1.0 N/mm2	2703)	2603)	2603)	2354)	2355)	2256)	2256)
Tensile Strength		Rm N/mm2	540 – 6903)	540 – 6903)	520 – 6703)	500 – 7004)	500 – 7005)	490 – 6906)	490 – 6906)
Elongation min. in %		A1) %min (longitudinal)	-	-	-	40	-	35	35
		A1) %min (transverse)	40	40	40	-	30	30	30
Impact Energy (ISO-V) ≥ 10mm thick		Jmin (longitudinal)	-	90	90	100	-	100	100
		Jmin (transverse)	-	60	60	0	60	60	60

Density at 20°C kg/m3		8.0
Modulus of Elasticity kN/mm2 at	20°C	200
	200°C	186
	400°C	172
	500°C	165
Thermal Conductivity W/m K at 20°C		15
Specific Thermal Capacity at 20°C J/kg K		500
Electrical Resistivity at 20°C Ω mm2 /m		0.75

100°C	16.5
200°C	17.5
300°C	18.0
400°C	18.5
500°C	19.0