Alloy Mnzhmc10-1-1
Alloy MNTS16-29-1.8
Alloy MNMts43-0.5 (Kopel)
Alloy MNMts5-3.7
Alloy MNMz60-20-20
Alloy MNMts68-4-2
Alloy MNMtsAZh3-12-0.25-0.2
Alloy MNMtsAZh3-12-0,3-0,3 (Manganin)
Alloy MNMtsAZhVTNb40-2-1,5-1,4 (MN40S)
Alloy MNMZh40-1,4-0,45
Alloy MNTs12-24
Alloy MNTs15-20 (Neusilber)
Alloy MNTs18-20
Alloy MNC18-27
Alloy MNMts4.5-1.5 (Alloy A)
Alloy Neusilber 30
Alloy NK
Alloy NK2.4 (Cilin)
Alloy HM25
Alloy NM40A
Alloy NM60A
Alloy NMZhMz28-2,5-1,5
Alloy NMMKZhMC30-4-2-1 (VKM)
Alloy NMMZTA26-1,5-1,1-0,5
Alloy NMCAT3-1,5-0,6
Alloy NMCATC1-1,5-2,5-0,15
Alloy NHC9-0.9 (Silch)
Alloy Alloy 273
Alloy MNA13-3 (Kunial A)
Castolin Alloy
Alloy MN0.6 (Alloy TP)
Alloy MN10
Alloy MN15
Alloy MH16 (Alloy TB)
Alloy MH17 (Alloy B)
Alloy MN19 (Melchior)
Alloy MN2.15
Alloy MN23
Alloy MN25
Alloy MN45 (Constantan)
Alloy MN6
Alloy MN95-5
Alloy MNMts40-1.5 (Constantan)
Alloy MNA6-1.5 (Kunial B)
Alloy MNAZHMZ6-0.8-0.8-0.6 (BS-3)
Alloy MNAKH11-2,5-1,0-0,8 (Alloy 131)
Alloy MNAHMC15-3,5-2-3 (Alloy 538)
Alloy MNAHMc20-4-3-4 (Alloy 546; Camelon)
Alloy MNAXMZ4,5-4,5-0,7-2,5 (Kamelin)
Alloy MNZh5-1
Alloy MNZh9.3-0.5 (Menigel)
Alloy MNZHKT5-1-0,2-0,2
Alloy MNZHMZ10-1-1
Alloy MNZHMZ30-1-1
Alloy MNMts3-12 (Manganin)
Designation
| Name |
The value |
| Designation GOST Cyrillic |
МНЖМц10-1-1 |
| Designation GOST Latin |
MHZhMts10-1-1 |
| Transliteration |
MNGMts10-1-1 |
| The chemical elements |
CuNiFeMn10-1-1 |
Description
Alloy Mnzhmc10−1-1 is used: for the manufacture of cold pipes, used for the manufacture of heat exchangers, condenser tubes, tube plates of air conditioners in instrumentation.
Standards
| Name |
Code |
Standards |
| Pipes from non-ferrous metals and alloys |
В64 |
GOST 10092-2006 |
| Non-ferrous metals, including rare metals, and their alloys |
В51 |
GOST 28873-90, GOST 492-2006 |
Chemical composition
| Standard |
C |
S |
Mn |
Fe |
Cu |
Zn |
Pb |
Ni+Co |
| GOST 10092-2006 |
≤0.03 |
≤0.03 |
0.3-1 |
1-2 |
The rest |
≤0.3 |
≤0.03 |
9-11 |
Cu is the basis.
According to GOST 10092-2006, a cobalt mass fraction of 0.50% is allowed due to the mass fraction of nickel + cobalt, which is not taken into account in the total amount of impurities. It is possible to determine the mass fraction of impurities of silicon, magnesium, arsenic, bismuth, phosphorus, tin, antimony. The sum of impurities is ≤ 0.5%. An impurity should be considered an element that has only the maximum limit of its content.
According to GOST 492-2006, the total mass fraction of impurities is ≤ 0.50%. In the alloy, the mass fraction of cobalt ≤ 0.50% is allowed due to the mass fraction of Ni + Co, which is not taken into account in the total amount of impurities. The mass fraction of cobalt exceeding 0.50% is taken into account in the total amount of impurities. In the alloy, in agreement with the consumer, it is possible to determine the mass fraction of silicon, magnesium, arsenic, bismuth, phosphorus, tin, antimony.
Mechanical characteristics
| Section, mm |
σB, MPa |
d5, % |
d10 |
| Cold-deformed pipes for t/o systems (DH=10-50 mm) according to GOST 10092-2006. In the delivery condition |
|
≥290 |
≥35 |
≥30 |
|
≥310 |
≥12 |
≥10 |
|
≥420 |
≥5 |
≥3 |
Description mechanical marks
| Name |
Description |
| Section |
Section |
| σB |
Limit short-term strength |
| d5 |
Elongation after rupture |
| d10 |
Elongation after rupture |
Technological properties
| Name |
The value |
| Weldability |
The alloy is well welded. |
| Pressure treatment |
The alloy is deformed in the cold state. |
| Corrosion resistance |
The alloy is resistant. |
