Pipe for nuclear power station

Implement standards or specifications including GB 24512.1, GB 24512.1, RCCM series, ASME series. We are capable of producing Grade 2 and Grade 3 steel pipe with OD less than or equal to 273mm, which are used for the main steam pipeline and main water-supply pipeline with common sizes. Products can be ordered in accordance with the client’s requirements.

Usage	Size		Steel Grade	Specification	Typical Application
	OD(mm)	WT(mm)
Seamless Steel Pipe used for Nuclear Power Station	48 - 720	4.5 - 130	HD245, HD245Cr	GB 24512.1	Carbon and alloy seamless steel pipe for Nuclear Station Island and Conventional Island
			HD265, HD265Cr	GB 24512.2
			HD280, HD280Cr
			HD12Cr2Mo
			HD15Ni1MnMoNbCu
			TUE250B	RCC-M
			TU42C
			TU48C
			P280GH
			SA106B/C	ASME SA-106/SA-106M
			P11	ASME SA-335/SA-335M
			P22
			P36
			P91

Nuclear power is a technology which extracts usable energy from atomic nuclei via controlled nuclear reactions – normally atomic fission.

GB24512.1 seamless tubes and pipes for nuclear power plant.

Chemical Composition of GB24512.1

Grade	C	Si	Mn	P	S	Cr	Mo	Ni	Sn	Cu
HD245	≤0.22	0.15-0.39	≤1.04	≤0.025	≤0.02	≤0.25	≤0.15	≤0.25	≤0.030	≤0.20
HD245Cr	≤0.22	0.15-0.39	≤1.04	≤0.025	≤0.02	0.18-0.33	≤0.15	≤0.25	≤0.030	≤0.20
HD265	≤0.22	≤0.44	≤1.44	≤0.025	≤0.02	≤0.3	≤0.08	≤0.3	≤0.030	≤0.20
HD265Cr	≤0.22	≤0.44	≤1.44	≤0.025	≤0.02	0.15~0.3	≤0.08	≤0.3	≤0.030	≤0.20
HD280	≤0.22	0.1-0.4	0.8-1.6	≤0.025	≤0.02	≤0.25	≤0.1	≤0.5	≤0.030	≤0.20
HD280Cr	≤0.22	0.1-0.4	1.0-1.6	≤0.025	≤0.02	0.15-0.33	≤0.1	≤0.5	≤0.030	≤0.20

Mechanical Capacity of GB24512.1

Grade	Tensile   Strength, [MPa]	Yeild Strength,   [MPa]	Elongation (%)
HD245	410-550	≥245	≥24
HD245Cr	410-550	≥245	≥24
HD265	410-570	≥265	≥23
HD265Cr	410-570	≥265	≥23
HD280	410-590	≥275	≥21
HD280Cr	410-590	≥275	≥21

GB24512.2 are alloy steel seamless tubes and pipes for power plant.

Chemical Composition of GB24512.2

Grade

C

Si

Mn

P

S

Cr

Mo

Ni

Nb

N

Cu

V

HD12Cr2Mo

0.07-0.16

≤0.54

0.37-0.73

≤0.03

≤0.02

1.9-2.6

0.86-1.24

≤0.30

-

-

≤0.20

≤0.08

HD15Ni1MnMoNbCu

0.09-0.18

0.21-0.54

0.76-1.24

≤0.030

≤0.020

0.14-0.35

0.21-0.44

0.95-1.35

0.010-0.030

≤0.020

0.45-0.85

≤0.02

Mechanical Capacity of GB24512.2

Grade	Tensile   Strength, [MPa]	Yeild Strength,   [MPa]	Elongation (%)
HD12Cr2Mo	450-600	≥280	≥22
HD15Ni1MnMoNbCu	620-780	≥440	≥19

RCC-M steel pipe for nuclear industry equipment.

Chemical Composition of RCC-M

Grade

C

Si

Mn

P

S

Cr

Mo

Ni

Al

Ceq

Cu

Sn

TU48C

≤0.24

0.09-0.40

0.60-1.30

≤0.040

≤0.040

-

-

-

-

-

≤0.25

≤0.030

P280GH

≤0.22

0.10-0.40

0.80-1.60

≤0.025

≤0.020

≤0.25

≤0.10

≤0.50

0.020-0.050

≤0.48

≤0.25

≤0.030

Mechanical Capacity of RCC-M

Grade	Tensile Strength, [MPa]	Yeild Strength, [MPa]	Elongation (%)
TU48C	470-570	≥275	Rm（A-2）≥10500
P280GH	470-570	≥275	Rm（A-2）≥10500

The process takes place in a nuclear-fuelled power plant, where – much like in a fossil-fuelled power plant – water is turned into steam, which drives turbine generators to produce electricity. The difference between the two power plants is the heat source. Nuclear power produces electricity by splitting uranium atoms which generate phenomenal heat. This is called fission. This heat is used to create the steam which powers the generators. There is no combustion in a nuclear reactor, just the constant splitting of atoms which produces manageable heat.

Either a pressurised water reactor or boiling water reactor is used, but regardless which type of reactor is used to generate heat, the conditions under which they do are extremely hostile. This means that the finest Stainless Steel pipes and tubing are required so that they can deal with constantly high pressures and temperatures.