JPS5844144B2 - Ni-Fe based high permeability alloy with good hot workability and machinability - Google Patents
Ni-Fe based high permeability alloy with good hot workability and machinabilityInfo
- Publication number
- JPS5844144B2 JPS5844144B2 JP51033771A JP3377176A JPS5844144B2 JP S5844144 B2 JPS5844144 B2 JP S5844144B2 JP 51033771 A JP51033771 A JP 51033771A JP 3377176 A JP3377176 A JP 3377176A JP S5844144 B2 JPS5844144 B2 JP S5844144B2
- Authority
- JP
- Japan
- Prior art keywords
- weight
- alloy
- machinability
- hot workability
- based high
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired
Links
Description
【発明の詳細な説明】
本発明はNi−Fe系合金中に微量のマグネシュウムと
イオウを含有させることにより合金本来の磁性を損うこ
となく熱間加工性および被削性を改善したNi −Fe
系高透磁率磁性合金に関するものである。DETAILED DESCRIPTION OF THE INVENTION The present invention is a Ni-Fe alloy that improves hot workability and machinability without impairing the inherent magnetism of the alloy by incorporating trace amounts of magnesium and sulfur into the Ni-Fe alloy.
The present invention relates to high permeability magnetic alloys.
Ni −Fe系合金はいわゆるパーマロイと総称され高
透磁率材料の中で最も高い比透磁率を示すものであり、
現在商用されている種類もきわめて多い。Ni-Fe alloys are collectively known as permalloys and exhibit the highest relative magnetic permeability among high magnetic permeability materials.
There are many types that are currently commercially available.
しかしながらこの種合金はいずれも熱間加工性が悪いう
え柔軟かつ粘靭であるため被削性がきわめて悪いという
難点がある。However, all of these types of alloys have the disadvantage of poor hot workability and extremely poor machinability because they are flexible and tough.
そこで従来からこれらの合金に鉛、ビスマス、セレン、
テルル、カルシュラムなどを少量添加して被削性の向上
を図った合金が種々提案、実施されある程度の成果をあ
げているものもある。Therefore, lead, bismuth, selenium,
Various alloys have been proposed and implemented in which machinability has been improved by adding small amounts of tellurium, calsholum, etc., and some have achieved some success.
しかし一般にこれらの被削性改善元素を添加すると熱間
加工性がさらに低下する傾向にあり、製造性が悪くなる
欠点があった。However, in general, addition of these machinability-improving elements tends to further reduce hot workability, which has the disadvantage of worsening manufacturability.
本発明者は上記の欠点を解消するために種種検討した結
果、合金本来の磁性を損うことなく熱間加工性および被
剛性の良好なNi −Fe系高透磁率合金を得るのに成
功した。The inventors of the present invention investigated various types to overcome the above-mentioned drawbacks, and as a result, succeeded in obtaining a Ni-Fe based high magnetic permeability alloy with good hot workability and rigidity without impairing the inherent magnetism of the alloy. .
すなわち本発明はNi:35〜90重量%、残余が鉄お
よび不純物からなるNi−Fe系合金、または該合金に
一般に知られている範囲の磁気特性、機械的性質改善元
素(Mo、Cu、Crを1種以上合計10重量%以下)
あるいは被削性改善元素(Ca、Se、Teを1種以上
合計30重量%以下)を単独または複合添加したNi−
Fe系合金にたいし、0.004〜0.25重量%のM
gおよび0.005〜0.15重量%のSを含有させた
ことを特徴とするNi −Fe系高透磁率性合金である
。That is, the present invention relates to a Ni-Fe alloy consisting of 35 to 90% by weight of Ni, the balance being iron and impurities, or an alloy containing generally known elements for improving magnetic properties and mechanical properties (Mo, Cu, Cr). 1 or more types (total of 10% by weight or less)
Or Ni-
0.004-0.25% by weight of M based on Fe-based alloy
This is a Ni--Fe based high magnetic permeability alloy characterized by containing g and 0.005 to 0.15% by weight of S.
次に添加元素の限定理由を述べる。Next, the reasons for limiting the number of added elements will be described.
Mo :<6重量%、Cu:<6重量%、Cr :〈
12重量%(合計量2重量%以上、10重量%以下)最
大透磁率、機械的性質を向上される働きがあり多量に添
加すると熱間加工性を劣化させるので上記範囲に定めた
。Mo: <6% by weight, Cu: <6% by weight, Cr: <
12% by weight (total amount: 2% by weight or more, but not more than 10% by weight) It works to improve maximum magnetic permeability and mechanical properties, and adding a large amount deteriorates hot workability, so it was set within the above range.
Se :<0.25重量%、Cu : <0.065
重量%、Te:0.20重量%(合計量0.01重量%
以下、3.0重量%以下)被削性向上に有効であるが多
量に添加すると熱間加工性を害するため上記範囲に定め
た。Se: <0.25% by weight, Cu: <0.065
wt%, Te: 0.20 wt% (total amount 0.01 wt%
(Hereinafter, 3.0% by weight or less) is effective in improving machinability, but since adding a large amount impairs hot workability, it is set within the above range.
なお本発明は磁気特性、機械的性質改善元素としてSi
、AI、V、Nb、、Ta、Ti、Mn、W等をおよび
/または被削性改善元素としてSn、Pb、Bi 等
をこの種の合金に通常加える範囲内で添加してもその本
質が損われないことも確認している。Note that the present invention uses Si as an element for improving magnetic properties and mechanical properties.
, AI, V, Nb, , Ta, Ti, Mn, W, etc. and/or machinability improving elements such as Sn, Pb, Bi, etc. can be added within the range normally added to this type of alloy. We have also confirmed that there will be no damage.
本発明の特徴は、微量のマグネシュウムの添加により熱
間加工性が著るしく改善され、さらにイオウを添加する
ことによりマグネシュウムとイオウの複合効果によって
被削性が著るしく改善されるところにあり、従来のNi
−Fe系高透磁率合金の製造上の欠点を解消した新規な
合金である。The feature of the present invention is that hot workability is significantly improved by adding a small amount of magnesium, and machinability is significantly improved by adding sulfur due to the combined effect of magnesium and sulfur. , conventional Ni
-This is a new alloy that eliminates the manufacturing defects of Fe-based high magnetic permeability alloys.
従来から使用されているNi−Fe系合金は熱間加工性
が悪いため溶鋼精錬時に強力な脱酸・脱硫処理を行い、
酸素およびイオウの含有量を極力低くする必要があり、
したがって高価な低イオウ原料を使用する必要があった
が、本発明合金の製造においてはその必要性はまったく
なく、安価に製造することができる。Conventionally used Ni-Fe alloys have poor hot workability, so strong deoxidation and desulfurization treatments are performed during molten steel refining.
Oxygen and sulfur content must be kept as low as possible.
Therefore, it was necessary to use an expensive low-sulfur raw material, but this is not necessary at all in the production of the alloy of the present invention, and the alloy can be produced at low cost.
本発明合金の特徴であるMgの有効添加量は0.004
〜0.25重量%である。The effective amount of Mg added, which is a feature of the alloy of the present invention, is 0.004
~0.25% by weight.
これは0.004重量%未満では熱間加工性の改善効果
が少いためである。This is because if it is less than 0.004% by weight, the effect of improving hot workability is small.
しかし0.25重量%を越えて添加しても熱間加工性の
改善に大きく寄与しないばかりでなく磁気的特性、特に
最大透磁率を低下させるため上記範囲が有効である。However, adding more than 0.25% by weight not only does not significantly contribute to improving hot workability but also reduces magnetic properties, especially maximum permeability, so the above range is effective.
一方SについてはM2と結びついて被削性を改善する効
果が認められるのは0.005重量%以上である。On the other hand, for S, the effect of combining with M2 and improving machinability is observed at 0.005% by weight or more.
しかし多量に添加すると熱間加工性を着るしく劣化させ
ると同時に磁性にも悪影響をおよぼすので0.15重量
%以下が適当である。However, if added in a large amount, the hot workability will be seriously deteriorated and at the same time it will also have an adverse effect on the magnetism, so the appropriate amount is 0.15% by weight or less.
次に本発明合金の特徴を実施例により詳細に説明する。Next, the characteristics of the alloy of the present invention will be explained in detail using examples.
実施例 1
第1表に示す合金組成のNi −Fe系高透磁率合金を
溶製し、各種の特性を調べた。Example 1 A Ni--Fe based high magnetic permeability alloy having the alloy composition shown in Table 1 was melted and various properties were investigated.
供試材A1〜7及びAs2はMg、Sを含有した45N
i −Fe系高透磁率合金、供試材層8〜11及びA
7’はMg、Sを含有した78Ni−Fe系高透磁率合
金である。Test materials A1 to 7 and As2 are 45N containing Mg and S.
i-Fe-based high magnetic permeability alloy, test material layers 8 to 11 and A
7' is a 78Ni-Fe based high magnetic permeability alloy containing Mg and S.
また供試材層12および13は比較のために溶製した従
来合金組成の45Ni系合金と78Ni系合金である。The test material layers 12 and 13 are a 45Ni alloy and a 78Ni alloy having conventional alloy compositions, which were produced for comparison.
第1表の供試材について熱間加工性を調べるために各イ
ンゴットの表層から熱間ねじり試験片(直径81n7r
t×長さ30mm)を採取した。In order to investigate the hot workability of the test materials in Table 1, hot torsion test pieces (diameter 81n7r) were prepared from the surface layer of each ingot.
t×length 30 mm) was collected.
熱間ねじり試験の条件は歪速度: 5 See −1と
し、破断までのねじり回転数を測定した。The conditions for the hot torsion test were a strain rate of 5 See -1, and the number of twisting rotations until breakage was measured.
第1図は各試1験温度における破断までのねん同値を示
した図であるが、本発明合金はいずれも比較鋼にくらべ
て破断ねん同値は高く熱間加工性の良好なることを示し
ている。Figure 1 shows the tensile strength to fracture at each test temperature, and the alloys of the present invention all have higher tensile strength to fracture than the comparative steels, indicating that they have better hot workability. There is.
次に供試材の被削性を調べるために直径30mmの丸棒
試験片を採取して切削試験を行った。Next, in order to examine the machinability of the sample material, a round bar test piece with a diameter of 30 mm was taken and a cutting test was conducted.
第2図は切削時間と工具のフランク摩耗量を示した図で
あるが、本発明合金は比較鋼にくらべて工具のフランク
摩耗量が少く被削性の良好なることを示している。FIG. 2 is a diagram showing the cutting time and the flank wear amount of the tool, and shows that the alloy of the present invention has a smaller tool flank wear amount and better machinability than the comparative steel.
以上のようにマグネシュウムおよびイオウを適当量添加
することにより、Ni −Fe系高透磁率合金の熱間加
工性と被削性を改善することができることを明瞭に示し
ている。As described above, it is clearly shown that the hot workability and machinability of Ni-Fe based high magnetic permeability alloys can be improved by adding appropriate amounts of magnesium and sulfur.
次に本発明合金の磁気的特性を調べるため、第1表の供
試材から外径45mmX内径33關×厚さ10mmの環
状試験片を切り出し、1100℃×2時間の焼鈍を行っ
た後直流磁気特性を測定した。Next, in order to investigate the magnetic properties of the alloy of the present invention, an annular test piece with an outer diameter of 45 mm, an inner diameter of 33 mm, and a thickness of 10 mm was cut from the test material shown in Table 1, annealed at 1100°C for 2 hours, and then subjected to direct current. The magnetic properties were measured.
結果を第2表に示す。The results are shown in Table 2.
45%Ni−Fe系の成分でみると蔦1.2.3.4と
Mg、Sが増加するにつれて、磁気特性は比較材層12
より劣化傾向にあるが十分実用に耐える高磁性を示す。Looking at the 45%Ni-Fe system components, as the Mg and S content increases, the magnetic properties of the comparison material layer 12
Although it tends to deteriorate more, it exhibits high magnetism that is sufficient for practical use.
また、磁気的性質・機械的性質改善元素ならびに被削性
改善元素を添加した憲5.5′、6.7はいずれも最大
透磁率28000以上と大きな値を示している。In addition, 5.5' and 6.7, in which magnetic and mechanical property improving elements and machinability improving elements were added, both exhibited large maximum permeability values of 28,000 or more.
一方、80%Ni−Fe系合金の成分でみると、本発明
材A7′、8.9.10.11はいずれも最大透磁率1
ooooo以上と、JIS規格を満足している。On the other hand, looking at the composition of the 80% Ni-Fe alloy, the maximum magnetic permeability of the present invention materials A7' and 8.9.10.11 is 1.
ooooo or more, satisfying the JIS standard.
以上のようにNi−Fe系高透磁率合金にたいして、M
gとSを添加することにより磁気特性を損うことなく熱
間加工性と被削性を改善することができ該合金系の製造
性の向上に大きく貢献できるものである。As mentioned above, M
By adding g and S, hot workability and machinability can be improved without impairing magnetic properties, and this can greatly contribute to improving the manufacturability of the alloy system.
第1図は本発明合金と従来合金の熱間破断ねん同値を示
す図、第2図は本発明合金と従来合金の切削性を示す図
である。FIG. 1 is a diagram showing the equivalent hot rupture properties of the alloy of the present invention and the conventional alloy, and FIG. 2 is a diagram showing the machinability of the alloy of the present invention and the conventional alloy.
Claims (1)
からなるNi−Fe系合金に対し、0.004〜0.2
5 重量%のマグネシュウム、0.005〜0.15重
量%のイオウを含有させたことを特徴とするNi −F
e系高透磁率磁性合金。 2 ニッケル35〜90重量%、残余が鉄および不純物
からなるNi −Fe系合金に対し、0.004〜0.
25 重量%のマグネシュウム、O,OO5〜0.15
重量%のイオウと、6重量%以下のモリフデン、6重量
%以下の銅、12重量%以下のクロムのうち1種又は2
種以上(但し合計量で2〜10重量%)含有させたこと
を特徴とするNiFe系高透磁率性合金。 3 ニッケル35〜90重量%、残余が鉄および不純物
からなるNi−Fe系合金に対し、0.004〜0.2
5重量%のマグネシュウム、0.005〜0.15重量
%のイオウと、0.25重量%以下のセレン、0.06
5 重量%以下のカルシュラム、0.20重量%以下の
テルルのうち1種又は2種以上(但し合計量で0.01
〜3重量%)含有させたことを特徴とするNi −Fe
系高透磁率性合金。 4 ニッケル35〜90重量%、残余が鉄および不純物
からなるNi−Fe系合金に対し、0.004〜0.2
5重量%マグネシュウム、0.005〜0.15重量%
のイオウと、6重量%以下のモリフデン、6重量%以下
の銅、12重量%以下のクロムのうち1種又は2種以上
(但し合計量で2重量%以上)と、さらに0.25重量
%以下のセレン、0.065重量%以下のカルシュラム
、0.20重量%以下のテルルのうち1種又は2種以上
(但し合計量で0.01重量%以上)含有させたことを
特徴とするNi−Fe系高透磁率性合金。[Claims] 1 0.004 to 0.2 for a Ni-Fe alloy consisting of 35 to 90% by weight of nickel, the balance being iron and impurities.
5% by weight of magnesium and 0.005 to 0.15% by weight of sulfur.
E-based high permeability magnetic alloy. 2 0.004 to 0.2% for a Ni-Fe alloy consisting of 35 to 90% by weight of nickel, the balance being iron and impurities.
25% by weight of magnesium, O,OO5~0.15
One or two of the following: sulfur at % by weight, molyfdenum at most 6% by weight, copper at most 6% by weight, and chromium at most 12% by weight.
1. A NiFe-based high magnetic permeability alloy containing at least one species (2 to 10% by weight in total). 3 0.004 to 0.2 for a Ni-Fe alloy consisting of 35 to 90% by weight of nickel, the balance being iron and impurities.
5% by weight of magnesium, 0.005-0.15% by weight of sulfur, and up to 0.25% by weight of selenium, 0.06
5 One or more of the following: Calsulam in an amount of up to 0.20% by weight, and tellurium in an amount of up to 0.20% by weight (however, the total amount is 0.01
~3% by weight)
High permeability alloy. 4 0.004 to 0.2 for a Ni-Fe alloy consisting of 35 to 90% by weight of nickel, the balance being iron and impurities.
5% by weight magnesium, 0.005-0.15% by weight
sulfur, one or more of the following: 6% by weight or less of molyfden, 6% by weight or less of copper, 12% by weight or less of chromium (however, the total amount is 2% by weight or more), and an additional 0.25% by weight. Ni characterized by containing one or more of the following selenium, 0.065% by weight or less of calcilum, and 0.20% by weight or less of tellurium (however, the total amount is 0.01% by weight or more) -Fe-based high magnetic permeability alloy.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP51033771A JPS5844144B2 (en) | 1976-03-26 | 1976-03-26 | Ni-Fe based high permeability alloy with good hot workability and machinability |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP51033771A JPS5844144B2 (en) | 1976-03-26 | 1976-03-26 | Ni-Fe based high permeability alloy with good hot workability and machinability |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| JPS52116717A JPS52116717A (en) | 1977-09-30 |
| JPS5844144B2 true JPS5844144B2 (en) | 1983-10-01 |
Family
ID=12395702
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| JP51033771A Expired JPS5844144B2 (en) | 1976-03-26 | 1976-03-26 | Ni-Fe based high permeability alloy with good hot workability and machinability |
Country Status (1)
| Country | Link |
|---|---|
| JP (1) | JPS5844144B2 (en) |
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JPH01169394A (en) * | 1987-12-25 | 1989-07-04 | Hitachi Ltd | Xy stage moving mechanism for vacuum container |
Families Citing this family (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN105506389A (en) * | 2015-12-24 | 2016-04-20 | 常熟市梅李合金材料有限公司 | Nickel-chromium resistance electrothermal alloy |
| CN105506388A (en) * | 2015-12-24 | 2016-04-20 | 常熟市梅李合金材料有限公司 | Nickel-chromium round wire |
| CN107794410A (en) * | 2017-10-27 | 2018-03-13 | 桂林市漓江机电制造有限公司 | A kind of high tenacity nichrome |
Citations (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JPS50117625A (en) * | 1974-03-01 | 1975-09-13 |
-
1976
- 1976-03-26 JP JP51033771A patent/JPS5844144B2/en not_active Expired
Patent Citations (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JPS50117625A (en) * | 1974-03-01 | 1975-09-13 |
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JPH01169394A (en) * | 1987-12-25 | 1989-07-04 | Hitachi Ltd | Xy stage moving mechanism for vacuum container |
Also Published As
| Publication number | Publication date |
|---|---|
| JPS52116717A (en) | 1977-09-30 |
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