Commodity: hot rolled coil,hot rolling coil,hot rolled steel coil,HRC
1. Material Grade: S235JR,S275JR,S275JR,S355JR , S235J0, S355J0,
2. Thickness: from 1mm to 25mm
3. Technique: Hot rolled
4. Width: 600-2000mm
5. Length:coil
6. coil I.D. 510-750 m
7. Edge: Mill Edg
8. Package: 10-30tons in a bundle,fixed with steel strips.
9. Application: Raw material for steel pipe and cold rolled steel coil, Construction
10. Delivery: 30-45days(
11. Payment: T/T or L/C
12. MOQ: 100MT for width 1200mm, 1219mm, 1250mm and 1500mm.
1000MT for per special width
13..Executive Standards: Hot-rolled Carbon and Low-alloy Structural Steel Strips, EN10025
COUNTRY | STANDARD | GRADE | YIELDING POINT (MPA) |
CHINA | GB 700 GB/T 1591 GB 713 GB 6654 |
Q235A/B Q295/Q345 20G 16MNR |
MIN 235 MPA MIN 295/345 MPA MIN 225~245 MPA MIN 305~345 MPA |
AMERICA | ASTM A36 ASTM A283 ASTM A516 |
A36 GR C/GR D GR 55/GR 70 |
MIN 245 MPA MIN 205/230 MPA MIN 205/260 MPA |
JAPAN | JIS G3101 JIS G3106 |
SS400 SM490 |
MIN 245 MPA MIN 350 MPA |
GERMANY | DIN17100 | ST37-2/ST52-3 | MIN 235/335 MPA |
E.U. | EN10025 | S235JR/S355JR | MIN 235/355 MPA |
The tables below show the chemical composition of grade S235JR :
Ladle analysis
|
|||||||||||||
Steel grade |
C
max. % |
Mn
max. % |
Si
max. % |
P
max. % |
S
max. % |
N
max. % |
Cu
max. % |
Other
max. % |
CEV
max. % |
||||
Nominal thickness
mm |
Nominal thickness
mm |
||||||||||||
≤16
|
>16
≤40 |
>40
|
≤30
|
>30
≤40 |
>40
≤125 |
||||||||
S235JR |
0,17
|
0,17
|
0,20
|
1,40
|
–
|
0.040
|
0,040
|
0,012
|
0,55
|
–
|
0,35
|
0,35
|
0,38
|
The tables below show the mechanical properties of grade S235JR :
Minimum yield strength Reh
MPa |
Tensile strength Rm
MPa |
Minimum elongation – A
Lo = 5,65 * √So (%) |
Notch impact test
|
|||||||||||
Steel grade |
Nominal thickness
mm |
Nominal thickness
mm |
Nominal thickness
mm |
Temperature
|
Min. absorbed energy
|
|||||||||
≤16
|
>16
≤40 |
>40
≤63 |
>63
≤80 |
>80
≤100 |
>100
≤125 |
>3
≤100 |
>100
≤125 |
>3
≤40 |
>40
≤63 |
>63
≤100 |
>100
≤125 |
°C
|
J
|
|
S235JR |
235
|
225
|
215
|
195
|
360-510
|
350-500
|
26
|
25
|
24
|
22
|
+20
|
27
|
The tables below show the chemical composition of grade S235J0 :
Ladle analysis
|
|||||||||||||
Steel grade |
C
max. % |
Mn
max. % |
Si
max. % |
P
max. % |
S
max. % |
N
max. % |
Cu
max. % |
Other
max. % |
CEV
max. % |
||||
Nominal thickness
mm |
Nominal thickness
mm |
||||||||||||
≤16
|
>16
≤40 |
>40
|
≤30
|
>30
≤40 |
>40
≤125 |
||||||||
S235J0 |
0,17
|
0,17
|
0,17
|
1,40
|
–
|
0.035
|
0,035
|
0,012
|
0,55
|
–
|
0,35
|
0,35
|
0,38
|
The tables below show the mechanical properties of grade S235J0:
Minimum yield strength
MPa |
Tensile strength Rm
MPa |
Minimum elongation – A
Lo = 5,65 * √So (%) |
Notch impact test
|
|||||||||||
Steel grade |
Nominal thickness
mm |
Nominal thickness
mm |
Nominal thickness
mm |
Temperature
|
Min. absorbed energy
|
|||||||||
≤16
|
>16
≤40 |
>40
≤63 |
>63
≤80 |
>80
≤100 |
>100
≤125 |
>3
≤100 |
>100
≤125 |
>3
≤40 |
>40
≤63 |
>63
≤100 |
>100
≤125 |
°C
|
J
|
|
S235J0 |
235
|
225
|
215
|
195
|
360-510
|
350-500
|
26
|
25
|
24
|
22
|
0
|
27
|
The table below show the chemical composition of grade S235J2
Ladle analysis
|
|||||||||||||
Steel grade |
C
max. % |
Mn
max. % |
Si
max. % |
P
max. % |
S
max. % |
N
max. % |
Cu
max. % |
Other
max. % |
CEV
max. % |
||||
Nominal thickness
mm |
Nominal thickness
mm |
||||||||||||
≤16
|
>16
≤40 |
>40
|
≤30
|
>30
≤40 |
>40
≤125 |
||||||||
S235J2 |
0,17
|
0,17
|
0,17
|
1,40
|
–
|
0,030
|
0,030
|
–
|
0,55
|
–
|
0,35
|
0,35
|
0,38
|
The table below show the mechanical properties of grade S235J2
Minimum yield strength Reh
MPa |
Tensile strength Rm
MPa |
Minimum elongation – A
Lo = 5,65 * √So (%) |
Notch impact test
|
|||||||||||
Steel grade |
Nominal thickness
mm |
Nominal thickness
mm |
Nominal thickness
mm |
Temperature
|
Min. absorbed energy
|
|||||||||
≤16
|
>16
≤40 |
>40
≤63 |
>63
≤80 |
>80
≤100 |
>100
≤125 |
>3
≤100 |
>100
≤125 |
>3
≤40 |
>40
≤63 |
>63
≤100 |
>100
≤125 |
°C
|
J
|
|
S235J2
|
235
|
225
|
215
|
195
|
360-510
|
350-500
|
26
|
25
|
24
|
22
|
-20
|
27
|
The table below show the chemical composition of grade S355JR
Ladle analysis
|
|||||||||||||
Steel grade |
C
max. % |
Mn
max. % |
Si
max. % |
P
max. % |
S
max. % |
N
max. % |
Cu
max. % |
Other
max. % |
CEV
max. % |
||||
Nominal thickness
mm |
Nominal thickness
mm |
||||||||||||
≤16
|
>16
≤40 |
>40
|
≤30
|
>30
≤40 |
>40
≤125 |
||||||||
S355JR |
0,24
|
0,24
|
0,24
|
1,60
|
0,55
|
0,040
|
0,040
|
0,012
|
0,55
|
–
|
0,45
|
0,47
|
0,47
|
The table below show the mechanical properties of grade S355JR
Minimum yield strength Reh
MPa |
Tensile strength Rm
MPa |
Minimum elongation – A
Lo = 5,65 * √So (%) |
Notch impact test
|
|||||||||||
Steel grade |
Nominal thickness
mm |
Nominal thickness
mm |
Nominal thickness
mm |
Temperature
|
Min. absorbed energy
|
|||||||||
≤16
|
>16
≤40 |
>40
≤63 |
>63
≤80 |
>80
≤100 |
>100
≤125 |
>3
≤100 |
>100
≤125 |
>3
≤40 |
>40
≤63 |
>63
≤100 |
>100
≤125 |
°C
|
J
|
|
S355JR
|
355
|
345
|
335
|
325
|
315
|
295
|
470-630
|
450-600
|
22
|
21
|
20
|
18
|
+20
|
27
|
The table below show the chemical composition of grade S355J0
Ladle analysis
|
|||||||||||||
Steel grade |
C
max. % |
Mn
max. % |
Si
max. % |
P
max. % |
S
max. % |
N
max. % |
Cu
max. % |
Other
max. % |
CEV
max. % |
||||
Nominal thickness
mm |
Nominal thickness
mm |
||||||||||||
≤16
|
>16
≤40 |
>40
|
≤30
|
>30
≤40 |
>40
≤125 |
||||||||
S355J0 | 0,20 | 0,20 | 0,22 | 1,60 | 0,55 | 0,035 | 0,035 | 0,012 | 0,55 | – | 0,45 | 0,47 | 0,47 |
The table below show the mechanical properties of grade S355J0
Minimum yield strength Reh
MPa |
Tensile strength Rm
MPa |
Minimum elongation – A
Lo = 5,65 * √So (%) |
Notch impact test
|
|||||||||||
Steel grade |
Nominal thickness
mm |
Nominal thickness
mm |
Nominal thickness
mm |
Temperature
|
Min. absorbed energy
|
|||||||||
≤16
|
>16
≤40 |
>40
≤63 |
>63
≤80 |
>80
≤100 |
>100
≤125 |
>3
≤100 |
>100
≤125 |
>3
≤40 |
>40
≤63 |
>63
≤100 |
>100
≤125 |
°C
|
J
|
|
S355J0 |
355
|
345
|
335
|
325
|
315
|
295
|
470-630
|
450-600
|
22
|
21
|
20
|
18
|
0
|
27
|
The table below show the chemical composition of grade S355J2
Ladle analysis
|
|||||||||||||
Steel grade |
C
max. % |
Mn
max. % |
Si
max. % |
P
max. % |
S
max. % |
N
max. % |
Cu
max. % |
Other
max. % |
CEV
max. % |
||||
Nominal thickness
mm |
Nominal thickness
mm |
||||||||||||
≤16
|
>16
≤40 |
>40
|
≤30
|
>30
≤40 |
>40
≤125 |
||||||||
S355J2 |
0,20
|
0,20
|
0,22
|
1,60
|
0,55
|
0,030
|
0,030
|
–
|
0,55
|
–
|
0,45
|
0,47
|
0,47
|
The table below show the mechanical properties of grade S355J2
Minimum yield strength Reh
MPa |
Tensile strength Rm
MPa |
Minimum elongation – A
Lo = 5,65 * √So (%) |
Notch impact test
|
|||||||||||
Steel grade |
Nominal thickness
mm |
Nominal thickness
mm |
Nominal thickness
mm |
Temperature
|
Min. absorbed energy
|
|||||||||
≤16
|
>16
≤40 |
>40
≤63 |
>63
≤80 |
>80
≤100 |
>100
≤125 |
>3
≤100 |
>100
≤125 |
>3
≤40 |
>40
≤63 |
>63
≤100 |
>100
≤125 |
°C
|
J
|
|
S355J2 |
355
|
345
|
335
|
325 | 315 |
295
|
470-630
|
450-600
|
22
|
21
|
20
|
18
|
-20
|
27
|
The table below show the chemical composition of grade S235J2
Ladle analysis
|
|||||||||||||
Steel grade |
C
max. % |
Mn
max. % |
Si
max. % |
P
max. % |
S
max. % |
N
max. % |
Cu
max. % |
Other
max. % |
CEV
max. % |
||||
Nominal thickness
mm |
Nominal thickness
mm |
||||||||||||
≤16
|
>16
≤40 |
>40
|
≤30
|
>30
≤40 |
>40
≤125 |
||||||||
S275JR |
0,21
|
0,21
|
0,22
|
1,50
|
–
|
0,040
|
0,040
|
0,012
|
0,55
|
–
|
0,40
|
0,40
|
0,42
|
The table below show the mechanical properties of grade S275JR
Minimum yield strength Reh
MPa |
Tensile strength Rm
MPa |
Minimum elongation – A
Lo = 5,65 * √So (%) |
Notch impact test
|
|||||||||||
Steel grade |
Nominal thickness
mm |
Nominal thickness
mm |
Nominal thickness
mm |
Temperature
|
Min. absorbed energy
|
|||||||||
≤16
|
>16
≤40 |
>40
≤63 |
>63
≤80 |
>80
≤100 |
>100
≤125 |
>3
≤100 |
>100
≤125 |
>3
≤40 |
>40
≤63 |
>63
≤100 |
>100
≤125 |
°C
|
J
|
|
S275JR |
275
|
265
|
255
|
245 | 235 |
225
|
410-560
|
400-540
|
23
|
22
|
21
|
19
|
+20
|
27
|
The table below show the chemical composition of grade S275J0
Ladle analysis
|
|||||||||||||
Steel grade |
C
max. % |
Mn
max. % |
Si
max. % |
P
max. % |
S
max. % |
N
max. % |
Cu
max. % |
Other
max. % |
CEV
max. % |
||||
Nominal thickness
mm |
Nominal thickness
mm |
||||||||||||
≤16
|
>16
≤40 |
>40
|
≤30
|
>30
≤40 |
>40
≤125 |
||||||||
S275J0 |
0,18
|
0,18
|
0,18
|
1,50
|
–
|
0,035
|
0,035
|
0,012
|
0,55
|
–
|
0,40
|
0,40
|
0,42
|
The table below show the mechanical properties of grade S275J0
Minimum yield strength Reh
MPa |
Tensile strength Rm
MPa |
Minimum elongation – A
Lo = 5,65 * √So (%) |
Notch impact test
|
|||||||||||
Steel grade |
Nominal thickness
mm |
Nominal thickness
mm |
Nominal thickness
mm |
Temperature
|
Min. absorbed energy
|
|||||||||
≤16
|
>16
≤40 |
>40
≤63 |
>63
≤80 |
>80
≤100 |
>100
≤125 |
>3
≤100 |
>100
≤125 |
>3
≤40 |
>40
≤63 |
>63
≤100 |
>100
≤125 |
°C
|
J
|
|
S275J0 |
275
|
265
|
255
|
245
|
235
|
225
|
410-560
|
400-540
|
23
|
22
|
21
|
19
|
0
|
27
|
The table below show the chemical composition of grade S275J2
Ladle analysis
|
|||||||||||||
Steel grade |
C
max. % |
Mn
max. % |
Si
max. % |
P
max. % |
S
max. % |
N
max. % |
Cu
max. % |
Other
max. % |
CEV
max. % |
||||
Nominal thickness
mm |
Nominal thickness
mm |
||||||||||||
≤16
|
>16
≤40 |
>40
|
≤30
|
>30
≤40 |
>40
≤125 |
||||||||
S275J2 |
0,18
|
0,18
|
0,18
|
1,50
|
–
|
0,030
|
0,030
|
–
|
0,55
|
–
|
0,40
|
0,40
|
0,42
|
The table below show the mechanical properties of grade S275J2
Minimum yield strength Reh
MPa |
Tensile strength Rm
MPa |
Minimum elongation – A
Lo = 5,65 * √So (%) |
Notch impact test
|
|||||||||||
Steel grade |
Nominal thickness
mm |
Nominal thickness
mm |
Nominal thickness
mm |
Temperature
|
Min. absorbed energy
|
|||||||||
≤16
|
>16
≤40 |
>40
≤63 |
>63
≤80 |
>80
≤100 |
>100
≤125 |
>3
≤100 |
>100
≤125 |
>3
≤40 |
>40
≤63 |
>63
≤100 |
>100
≤125 |
°C
|
J
|
|
S275J2 |
275
|
265
|
255
|
245
|
235
|
225
|
410-560
|
400-540
|
23
|
22
|
21
|
19
|
-20
|
27
|
The table below show the chemical composition of grade S355K2
Ladle analysis
|
|||||||||||||
Steel grade |
C
max. % |
Mn
max. % |
Si
max. % |
P
max. % |
S
max. % |
N
max. % |
Cu
max. % |
Other
max. % |
CEV
max. % |
||||
Nominal thickness
mm |
Nominal thickness
mm |
||||||||||||
≤16
|
>16
≤40 |
>40
|
≤30
|
>30
≤40 |
>40
≤125 |
||||||||
S355K2 |
0,20
|
0,20
|
0,22
|
1,60
|
0,55
|
0,030
|
0,030
|
–
|
0,55
|
–
|
0,45
|
0,47
|
0,47
|
The table below show the mechanical properties of grade S355K2
Minimum yield strength Reh
MPa |
Tensile strength Rm
MPa |
Minimum elongation – A
Lo = 5,65 * √So (%) |
Notch impact test
|
|||||||||||
Steel grade |
Nominal thickness
mm |
Nominal thickness
mm |
Nominal thickness
mm |
Temperature
|
Min. absorbed energy
|
|||||||||
≤16
|
>16
≤40 |
>40
≤63 |
>63
≤80 |
>80
≤100 |
>100
≤125 |
>3
≤100 |
>100
≤125 |
>3
≤40 |
>40
≤63 |
>63
≤100 |
>100
≤125 |
°C
|
J
|
|
S355K2 |
355
|
345
|
335
|
325
|
315
|
295
|
470-630
|
450-600
|
22
|
21
|
20
|
18
|
-20
|
40
|
The table below show the chemical composition of grade S450J0
Ladle analysis
|
|||||||||||||
Steel grade |
C
max. % |
Mn
max. % |
Si
max. % |
P
max. % |
S
max. % |
N
max. % |
Cu
max. % |
Other
max. % |
CEV
max. % |
||||
Nominal thickness
mm |
Nominal thickness
mm |
||||||||||||
≤16
|
>16
≤40 |
>40
|
≤30
|
>30
≤40 |
>40
≤125 |
||||||||
S450J0 |
0,20
|
0,20
|
0,22
|
1,70
|
0,55
|
0,035
|
0,035
|
0,025
|
0,55
|
–
|
0,47
|
0,49
|
0,49
|
The table below show the mechanical properties of grade S450J0
Minimum yield strength Reh
MPa |
Tensile strength Rm
MPa |
Minimum elongation – A
Lo = 5,65 * √So (%) |
Notch impact test
|
|||||||||||
Steel grade |
Nominal thickness
mm |
Nominal thickness
mm |
Nominal thickness
mm |
Temperature
|
Min. absorbed energy
|
|||||||||
≤16
|
>16
≤40 |
>40
≤63 |
>63
≤80 |
>80
≤100 |
>100
≤125 |
>3
≤100 |
>100
≤125 |
>3
≤40 |
>40
≤63 |
>63
≤100 |
>100
≤125 |
°C
|
J
|
|
S450J0 |
450
|
430
|
410
|
390
|
380
|
380
|
550-720
|
530-700
|
17
|
0
|
27
|
The table below show the chemical composition of grade E295
Ladle analysis
|
|||||||||||||
Steel grade |
C
max. % |
Mn
max. % |
Si
max. % |
P
max. % |
S
max. % |
N
max. % |
Cu
max. % |
Other
max. % |
CEV
max. % |
||||
Nominal thickness
mm |
Nominal thickness
mm |
||||||||||||
≤16
|
>16
≤40 |
>40
|
≤30
|
>30
≤40 |
>40
≤125 |
||||||||
E295 |
0,045
|
0,045
|
0,012
|
The table below show the mechanical properties of grade E295
Minimum yield strength Reh
MPa |
Tensile strength Rm
MPa |
Minimum elongation – A
Lo = 5,65 * √So (%) |
Notch impact test
|
|||||||||||
Steel grade |
Nominal thickness
mm |
Nominal thickness
mm |
Nominal thickness
mm |
Temperature
|
Min. absorbed energy
|
|||||||||
≤16
|
>16
≤40 |
>40
≤63 |
>63
≤80 |
>80
≤100 |
>100
≤125 |
>3
≤100 |
>100
≤125 |
>3
≤40 |
>40
≤63 |
>63
≤100 |
>100
≤125 |
°C
|
J
|
|
E295 |
295
|
285
|
275
|
265
|
255
|
245
|
470-610
|
450-610
|
20
|
19
|
18
|
16
|
The table below show the chemical composition of grade E335
Ladle analysis
|
|||||||||||||
Steel grade |
C
max. % |
Mn
max. % |
Si
max. % |
P
max. % |
S
max. % |
N
max. % |
Cu
max. % |
Other
max. % |
CEV
max. % |
||||
Nominal thickness
mm |
Nominal thickness
mm |
||||||||||||
≤16
|
>16
≤40 |
>40
|
≤30
|
>30
≤40 |
>40
≤125 |
||||||||
E335 |
0,045
|
0,045
|
0,012
|
The table below show the mechanical properties of grade E335
Minimum yield strength Reh
MPa |
Tensile strength Rm
MPa |
Minimum elongation – A
Lo = 5,65 * √So (%) |
Notch impact test
|
|||||||||||
Steel grade |
Nominal thickness
mm |
Nominal thickness
mm |
Nominal thickness
mm |
Temperature
|
Min. absorbed energy
|
|||||||||
≤16
|
>16
≤40 |
>40
≤63 |
>63
≤80 |
>80
≤100 |
>100
≤125 |
>3
≤100 |
>100
≤125 |
>3
≤40 |
>40
≤63 |
>63
≤100 |
>100
≤125 |
°C
|
J
|
|
E335 |
335
|
325
|
315
|
305
|
295
|
275
|
570-710
|
550-710
|
16
|
15
|
14
|
12
|
The table below show the chemical composition of grade E360
Ladle analysis
|
|||||||||||||
Steel grade |
C
max. % |
Mn
max. % |
Si
max. % |
P
max. % |
S
max. % |
N
max. % |
Cu
max. % |
Other
max. % |
CEV
max. % |
||||
Nominal thickness
mm |
Nominal thickness
mm |
||||||||||||
≤16
|
>16
≤40 |
>40
|
≤30
|
>30
≤40 |
>40
≤125 |
||||||||
E360 |
0,045
|
0,045
|
0,012
|
The table below show the mechanical properties of grade E360
Minimum yield strength Reh
MPa |
Tensile strength Rm
MPa |
Minimum elongation – A
Lo = 5,65 * √So (%) |
Notch impact test
|
|||||||||||
Steel grade |
Nominal thickness
mm |
Nominal thickness
mm |
Nominal thickness
mm |
Temperature
|
Min. absorbed energy
|
|||||||||
≤16
|
>16
≤40 |
>40
≤63 |
>63
≤80 |
>80
≤100 |
>100
≤125 |
>3
≤100 |
>100
≤125 |
>3
≤40 |
>40
≤63 |
>63
≤100 |
>100
≤125 |
°C
|
J
|
|
E360 |
360
|
355
|
345
|
335
|
325
|
305
|
670-830
|
650-830
|
11
|
10
|
9
|
8
|
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