JP4292810B2 - Soft magnetic material for magnetic circuit and method for producing the same - Google Patents

Description

【００３９】
【表２】

【００４０】
各実施例及び比較例１に係る試験片についての磁気特性の結果を表２に示す。磁気特性は、岩崎通信機（株）Ｂ・ＨアナライザーＳＹ・８２３２を用い、正弦波状の交流電流を給電して測定した。この場合、Ｈ（磁界）が２０００Ａ／ｍ時における磁気特性を測定した。
【００４１】
表２に示すように、損失（鉄損）については、片状黒鉛鋳鉄製の各実施例は、交流電流の周波数が１０００Ｈｚの場合でも、２０００Ｈｚの場合でも、３０００Ｈｚの場合でも、球状黒鉛鋳鉄製の比較例１よりも損失（鉄損）を小さくすることができた。
【００４２】
また磁束密度については、周波数が１０００Ｈｚの場合には、各実施例よりも比較例１の方が磁束密度は高かった。周波数が２０００Ｈｚの場合には、各実施例の磁束密度は比較例１の磁束密度に近づいた。更に３０００Ｈｚのように周波数が高い場合には、各実施例の磁束密度は比較例１の磁束密度に匹敵するか、あるいはそれ以上であった。このように本実施例は周波数が高くなるほど磁束密度を相対的に高くできる。
【００４３】
上記したよう各実施例によれば、比抵抗が高くなっているため、交番磁界が作用するとき鉄損を低減させることができ、モータコア等の磁気回路形成部材に適用した場合における発熱を抑えることができる。
【００４４】
鉄損は基本的にはヒステリシス損失Ｗｈ＋渦電流損失Ｗｅ＋残留損失Ｗｒで表され、周波数の影響を大きく受ける。鉄系材料では残留損失Ｗｒは一般的には小さい。このためモータコア等の鉄系の磁気回路形成部材で重要となるのは、ヒステリシス損失Ｗｈ及び渦電流損失Ｗｅである。単位時間あたりのヒステリシス損失Ｗｈは基本的には（１）式で表される。板材のとき、単位時間あたりの電流損失Ｗｅは基本的には（２）式で表される。
Ｗｈ=Ｋｈ・ｆ・Ｂｍ……（１）
Ｗｅ=（Ｋｅ・ｆ^２・ｔ^２・Ｂｍ^２）／ρ……（２）
ここで、Ｋｈ、Ｋｅはそれぞれ定数を示す。ｆは周波数を示し、直流パルスの場合にはパルス立ち上がりとパルス立ち下がりとで１Ｈｚとみなし得る。Ｂｍは磁束密度を示す。ｔは板材の厚みを示す。ρは材料の比抵抗を示す。
【００４５】
上記した（１）式、（２）式によれば、周波数ｆが高ければ、ヒステリシス損失Ｗｈ及び渦電流損失Ｗｅが増加するため、鉄損が増加する。よって鉄損を抑えるためには、高周波数領域に対処することが重要である。本実施例に係る軟磁性材料によれば、表２に示すように、高周波数領域において使用しても損失を抑えることができる。
【００４６】
本実施例のように軟磁性材料を鋳鉄で形成した場合には、鋳鉄の優れた鋳造性を生かし、製品近似形状を形成することができ、切削工程を低減または廃止させることができる。このため３次元的な形状のコア等の磁気回路形成部材を容易に製造することができるため、モータ等の機器の小型化及び薄型化が比較的安価に製造可能となる。
【００４７】
またシリコン含有量は軟磁性材料の透磁性を高めるには有利である。しかし珪素鋼板を積層させて軟磁性材料を形成する場合には、シリコン含有量が多いと硬度が高くなるため、珪素鋼板のプレス打ち抜き性が低下する傾向があり、シリコンの増量には制約がある。しかし鋳鉄で軟磁性材料を形成する場合には、鋼板のプレス打ち抜き性の低下を考慮せずとも良いため、鋳鉄の優れた鋳造性を生かして製品近似形状を容易に且つ安価に形成することができる。このため軟磁性材料のシリコン含有量を高め、透磁性を高めるのに有利である。従って本実施例のようにシリコンを質量比で２．５％以上、３．０％以上、４．０％以上とすることが容易にでき、同様に（シリコン含有量／炭素含有量）の比率を高めることも良いのである。
【００４８】
珪素鋼板を積層させて軟磁性材料は、使用条件が厳しいときには、各珪素鋼板の反り変形、剥離等のおそれがあり、強度や磁気特性の安定化の面では必ずしも充分ではない。本実施例の軟磁性材料は溶製材つまり鋳物に基づいているため、軟磁性材料の一体性が高くなり、機械的強度を確保するのに有利である。従って高温環境や温度変化がある環境においても、強度、磁気特性を安定化させることができる。このため使用条件が厳しい環境、例えば自動車等の車両で使用するのに適する。従って、強度が要求される磁気回路形成部材（例えばモータコア材）に適する。
【００４９】
（他の実施例）
本発明に係る第２の実施例は、基本的には前記した実施例と同様に製造するものである。更に、鋳造後の片状黒鉛鋳鉄で形成された鋳物を熱処理炉で焼鈍熱処理し、マトリックス基地におけるフェライト化を更に促進させる。これによりフェライト面積率を一層高めることができ、透磁性を高めることができる。熱処理としては、７５０〜１１００℃の範囲内において所定時間加熱保持することにより行い得る。熱処理の雰囲気としては大気雰囲気、真空雰囲気、還元性雰囲気等を採用できる。熱処理温度が高いと、また熱処理時間が長いと、フェラィトの結晶粒径を大きくでき、透磁率、磁束密度の向上に一層貢献できる。熱処理時間としては、要請されるフェライト面積率、鋳物のサイズによっても相違するが、一般的には１０分〜１００時間の範囲内で設定できる。
【００５０】
本発明に係る参考例によれば、軟磁性材料は、透磁性及び導電性を有する鉄系のマトリックス基地（フェライト系）と、マトリックス基地に分散されたセラミックス繊維からなるセラミックス繊維群とを備えている。セラミックス繊維は、マトリックス基地よりも高い電気抵抗をもつ微小障害物として機能し、アルミナ繊維、シリカ繊維等を例示できる。この場合においても、マトリックス基地において迷路を形成するように成長した多数の繊維が不規則に分散している。当該繊維の比抵抗は鉄系のマトリックス基地の比抵抗に比較してかなり大きく、電流の流れに対して障害物とみなすことができる。このため軟磁性材料の比抵抗を高くし、鉄損を低減させるのに有利である。
【００５１】
（適用例）
図５はモータに適用した一例を示す。図５に示すように、モータは、ハウジングに固定されたステータコア４０と、ステータコア４０内で回転可能なロータ５２とをもつ。ロータ５２は、シャフト５３と、シャフト５３に保持されロータコア５４とをもつ。ロータコア５４は、周方向に沿って一体的に並設された径外方向に突出する複数の突起部５５とをもつ。各突起部５５には励磁巻線（図略）が巻回されている。突起部５５の励磁巻線にＵ相、Ｖ相、Ｗ相となる直流のパルス電流が給電されると、ロータ５２がこれの軸心回りで回転する。ロータコア５４は片状黒鉛鋳鉄で形成されており、透磁性及び導電性を有する鉄系のマトリックス基地（フェライト系）と、マトリックス基地に分散された片状黒鉛からなる片状黒鉛群とを備えている。この片状黒鉛鋳鉄は、前記した実施例１〜実施例９のいずれかに基づいて形成されている。
【００５２】
その他、本発明は上記した実施例及び適用例のみに限定されるものではなく、要旨を逸脱しない範囲内で適宜変更して実施できるものである。上記した記載から次の技術的思想も把握できる。
（付記項１）各請求項において、微小障害物は湾曲または曲成していることを特徴とする磁気回路用軟磁性材料及びその製造方法。比抵抗を高めるのに有利となる。
【００５３】
【発明の効果】
以上説明したように本発明に係る磁気回路用軟磁性材料によれば、比抵抗を高くするのに有利であり、損失を低減させるのに有利である。殊に、本発明に係る磁気回路用軟磁性材料は、周波数が高くなるほど有効となる。
【００５４】
本発明方法によれば、加熱した鋳型のキャビティに片状黒鉛鋳鉄組成の溶湯を注湯させて冷却させるため、鋳鉄の凝固速度、冷却速度をゆっくりとすることができ、片状黒鉛の成長を促進させることができる。これにより軟磁性材料において発生する渦電流等の誘導電流を迂回させ、電流路をあたかも迷路状にさせるのに貢献でき、損失を低減させるのに有利である。更にマトリックス基地のフェライト化を促進させることができ、軟磁性材料の透磁性を一層高めることができる。
【図面の簡単な説明】
【図１】発熱体を装備した砂型を示す概念図である。
【図２】砂型で鋳造したときにおける冷却曲線の一例を示すグラフである。
【図３】実施例４に係る片状黒鉛鋳鉄の顕微鏡写真（倍率１００倍）である。
【図４】黒鉛に関する周囲長の概念を示す図である。
【図５】モータに適用した一例を示す概念図である。
【符号の説明】
図中、４０はステータコア、５２はロータ、５４はロータコアを示す。[0001]
BACKGROUND OF THE INVENTION
The present invention is a magnetic circuit. Soft The present invention relates to a magnetic material (hereinafter also referred to as a soft magnetic material) and a manufacturing method thereof. The present invention can be applied to, for example, a magnetic circuit member installed in an electronic device or an electric device. Specifically, it can be applied to a magnetic circuit member such as an iron core equipped in a motor, an electromagnetic actuator or the like.
[0002]
[Prior art]
Conventionally, soft magnetic materials used for magnetic circuit members and the like are required to have high specific resistance in order to reduce loss. For this reason, a laminate in which magnetically permeable iron plates and silicon steel plates are laminated in the thickness direction, or a powder molded body in which a green compact obtained by compacting iron permeable magnetic powder is used is mainly used. . Further, in order to reduce the loss, an insulating film having a high electric resistance is interposed between the plate members in the above-described laminate, or an insulating film having a high electric resistance is coated on the surface of the iron powder particles. ing.
[0003]
However, a soft magnetic material formed of a laminated body in which iron plates and silicon steel plates are laminated has a problem that it is difficult to form a three-dimensional shape or a complicated shape. Also, in soft magnetic materials that have undergone the process of compacting iron powder, increasing the compactness to increase the strength decreases the specific resistance of the soft magnetic material and increases the loss. If the specific resistance of the soft magnetic material is increased by lowering the value, there arises a problem that the strength of the soft magnetic material is lowered. Therefore, in recent years, a magnetic circuit forming member formed of spheroidal graphite cast iron in which spheroidal graphite is dispersed in a ferrite-containing matrix base has been developed (Patent Document 1). Conventionally, papers relating to the electric resistance of various cast irons have been disclosed (Non-patent Document 1). This paper describes the electrical resistance of flake graphite cast iron and spheroidal graphite cast iron.
[0004]
[Patent Document 1]
JP 2002-280210 A
[Non-Patent Document 1]
Castings Vol. 54, No. 2, pp. 29-33 (Issued Castings Association)
[0005]
[Problems to be solved by the invention]
According to the technique according to Patent Document 1 described above, the magnetic circuit forming member is formed of a spheroidal graphite cast iron casting in which a number of spheroidal graphites are dispersed in a ferrite matrix base. For this reason, the magnetic circuit formation member of a complicated shape can be manufactured at low cost. Moreover, since spherical graphite has a higher electrical resistance than matrix matrix, it has the property that spherical graphite can bypass induced currents such as eddy currents generated in the magnetic circuit forming member, and the specific resistance is increased. It has the advantage of being advantageous in reducing losses.
[0006]
The present invention is a further advancement of the above-described technique, which is advantageous for further reducing the loss by further increasing the specific resistance, and particularly advantageous for reducing the loss in a high frequency region. Soft It is an object of the present invention to provide a magnetic material and a manufacturing method thereof.
[0007]
[Means for Solving the Problems]
(1) The present inventor has been intensively developing soft magnetic materials for magnetic circuits based on the above-described problems. And, when the two-dimensional cut surface of the matrix base that constitutes the soft magnetic material is observed, it is in the shape of a piece and has a higher obstacle than the matrix base. As flake graphite Focusing on the fact that it is easy to improve the property that obstructs the flow of current if it is distributed irregularly, many micro obstacles Flake graphite as It has been found that dispersion of the material in the matrix matrix is advantageous for increasing the specific resistance of the soft magnetic material.
[0008]
The reason why the specific resistance can be increased is that a small obstacle in the form of a piece on a two-dimensional cut surface Flake graphite as Is irregularly distributed in the matrix base, it is presumed that the induced current such as eddy current generated in the soft magnetic material can be bypassed and the current path can be contributed to a maze. Based on this knowledge, the inventor has developed a magnetic circuit according to the present invention. Soft A magnetic material and a manufacturing method thereof were completed.
[0009]
(2) That is, the magnetic circuit according to the present invention Soft Magnetic materials It is formed of flake graphite cast iron containing 2% or more of carbon and 2% or more of silicon by mass ratio. When flake graphite cast iron is observed on the two-dimensional cut surface of the matrix matrix, When the total area of the flake graphite is 100%, the ferrite is 50% or more in terms of area ratio, and the elliptical major axis direction ratio of the flake graphite is 2 or more on average. Is.
[0010]
Micro obstacles that make up a group of micro obstacles (Corresponds to flake graphite) Has a higher electrical resistance than the matrix base. When the two-dimensional cut surface of the matrix base is observed, the micro obstacles are in the form of a piece and a large number of the obstacles are irregularly dispersed in the matrix base. This is advantageous in increasing the specific resistance of the soft magnetic material. As mentioned above, a micro-obstacle that takes the form of a piece on a two-dimensional cut surface (Corresponds to flake graphite) Is distributed in the matrix base, it is assumed that it is possible to bypass the induced current such as eddy current generated in the soft magnetic material and to make the current path as if it is a labyrinth.
[0011]
(3) Magnetic circuit according to the present invention Soft The manufacturing method of the magnetic material is as described above. A method for producing a soft magnetic material for a magnetic circuit, comprising a step of heating a mold having a cavity for forming a casting, and a mass of the heated mold cavity containing 2% or more of carbon and 2% or more of silicon. A cast metal is formed by pouring molten metal having a flake graphite cast iron composition and cooling at a temperature drop rate of 600 ° C. or higher at a casting surface portion of 30 ° C./min or less. Is.
[0012]
According to the method of the present invention, since the molten metal having the flake graphite cast iron composition is poured into the heated mold cavity and cooled, the temperature drop rate of the molten metal and the cast iron after solidification can be delayed, and the flake graphite grows. Can be promoted. As a result, an induced current such as an eddy current generated in the soft magnetic material can be bypassed, and the current path can be contributed to a maze. Furthermore, if the temperature drop rate is delayed, the ferrite area ratio of the matrix base can be increased, and the ferrite crystal grain size can be increased, which is advantageous for enhancing the magnetic permeability of the soft magnetic material.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
-A micro-obstacle means one with a higher electrical resistance than a matrix base. Metal base is used as the matrix base Do . “Fine” means one having a length of 10 mm or less. Adopted flake graphite as a minute obstacle Do . The flake graphite may be linear, but in order to improve the current bypass, it is preferably bent like a curve. The length of flake graphite is generally 1mm or less. The Graphite The electric resistance is higher than that of the matrix base.
[0014]
-When the two-dimensional cut surface of the matrix base is observed, it is possible to adopt a form in which minute obstacles are irregularly dispersed. “Irregularly dispersed” means that the orientation of the flaky micro-obstacle is low. Therefore, the minute obstacles are dispersed in all directions in the matrix base, and it is possible to bypass the current of the induced current such as eddy current generated in the soft magnetic material and contribute to making the current path into a maze shape. “When observing a two-dimensional cut surface of a matrix base” is taken into consideration that it is easy to grasp the form of a minute obstacle with an optical microscope or the like.
[0015]
・ When the two-dimensional cut surface of the matrix base is observed, the area of the matrix base (excluding micro obstacles) is 100%, and the ferrite ratio is 50% or more. The Since ferrite has a small amount of C component dissolved and is equivalent to pure iron, it has excellent magnetic properties and high magnetic permeability. Therefore, considering the application as a magnetic circuit, the ratio of ferrite is generally Higher is preferred. For example, matrix bases (small obstacles Flake graphite In the area ratio, ferrite can be 50% or more, 70% or more, 80% or more, or 90% or more. Further, it can be 95% or more, 100%, or substantially 100%. In order to improve the strength, it can be partially pearlite. Ferrite is a solid solution containing alpha iron or other elements.
[0016]
・ Additional explanation of preferable physical property values for micro obstacles. When observing the two-dimensional cut surface of the matrix base, one minute obstacle (Equivalent to flake graphite) For the perimeter, a form having an average of 80 μm or more can be adopted. A large perimeter for a micro obstacle generally corresponds to a large aspect ratio (length / width) of the micro obstacle, which is advantageous for increasing the specific resistance of the soft magnetic material. In addition, when observing the two-dimensional cut surface of the matrix base, (Equivalent to flake graphite) The ellipse major axis is about 2 on average is there. The ellipse major axis / minor axis ratio for a minute obstacle means (the major axis length of the ellipse / the minor axis length of the ellipse) when a piece-like minute obstacle is simulated as an ellipse. A large ellipse long / short axis ratio for a micro obstacle corresponds to a large aspect ratio (length / width) of the micro obstacle, which is advantageous for increasing the specific resistance of the soft magnetic material.
[0017]
・ The matrix base is iron-based, especially ferrite-based, and the minute obstacle is flake graphite. The Obedience The soft magnetic material according to the present invention is formed of flake graphite cast iron Be done . The specific resistance of graphite is considerably larger than the specific resistance of the iron matrix matrix, and can be regarded as an obstacle to the flow of current. According to the literature, generally, when graphite is hardened and used as an electrode, the specific resistance is said to be 1000-1500 μΩ · cm, and the specific resistance of the iron-based matrix base is said to be 100 μΩ · cm or less. ing. The flake graphite irregularly dispersed in the matrix base has a higher electrical resistance than the matrix base and can therefore act to prevent the straight flow of current in the matrix base, bypassing the current and bypassing the current path. This is effective for forming a labyrinth, and as a result, it is presumed that the specific resistance of the soft magnetic material can be increased.
[0018]
・ When observing the two-dimensional cut surface of the matrix base, Strip A form in which the perimeter of graphite is 80 μm or more on average can be adopted. Strip A large perimeter for graphite is generally equivalent to a large aspect ratio (length / width) of flake graphite for the same graphite cross-sectional area, which increases the specific resistance of soft magnetic materials. It will be advantageous. In addition, when the two-dimensional cut surface of the matrix base is observed, the ellipse major axis ratio of graphite is 2 or more on average. The Strip A large elliptical minor axis ratio for graphite corresponds to a large aspect ratio (length / width) of flake graphite, which is advantageous for increasing the specific resistance of the soft magnetic material. In general, if the obstacle is spherical, such as spherical graphite, Strip The ellipse major axis minor axis ratio for graphite tends to be less than 2.
[0019]
-When the soft magnetic material for magnetic circuit is 100%, it is made of cast iron containing 2% or more of carbon and 2% or more of silicon by mass ratio. The In this case, since a higher carbon content is advantageous for the growth of flake graphite, the cast iron is preferably 2.5% or more and 3% or more in terms of mass ratio, and therefore 3.2%. As mentioned above, it can be 3.5% or more. However, if the carbon content is excessive, the strength decreases, so the carbon content can be 5.0% or less by mass ratio. In addition, since a higher silicon content is advantageous for the growth of flake graphite, the cast iron is preferably 2.5% or more and 3% or more of silicon by mass ratio, and therefore 3.2% or more. 3.5% or more. Since silicon also contributes to increasing the proportion of ferrite, it can be made 3.5% or more, 4.0% or more, 4.5% or more, or 5.0% or more. Increasing the silicon can increase the magnetic permeability of the soft magnetic material and increase the specific resistance. However, when silicon is excessive, the hardness increases, and post-processing is required when post-processing is performed. However, it is recognized that there is a tendency that the hot water flowability is lowered and the castability is lowered. In this sense, the silicon content can be 12% or less and 15% or less.
[0020]
.Magnetic circuit according to the present invention Soft When the magnetic material is formed of cast iron, if the sum of the weight percent of carbon and the weight percent of silicon is defined as α value, the α value is 4. It may be 0% or more, 5.0% or more, particularly 6.0% or more, and may be 7.0% or more, 8.0% or more, or 9.0% or more. However, considering the strength, the α value may be 17.0% or less, 15.0% or less, or 12.0% or less, although it varies depending on the use of the soft magnetic material for the magnetic circuit.
[0021]
・ In order to ensure the strength of soft magnetic material, it is smarter than a coarse and wide form but with a small width. Flake graphite It can be. In order to increase the specific resistance while ensuring the strength and permeability of the soft magnetic material, Flake graphite As an example, it is possible to disperse a smart form having a long length but a small width. Therefore In flake graphite cast iron As the flake graphite as a minute obstacle, one having a long length but a small width can be dispersed. In this case, the silicon content can be set larger than the carbon content. Therefore, in terms of mass ratio, (silicon content / carbon content) can be 1.0 or more, 1.05 or more, 1.08 or more, or 1.1 or more. The (silicon content / carbon content) can be 4.0 or less.
[0022]
When the soft magnetic material according to the present invention is formed of cast iron, the cast iron composition may be any of a hypoeutectic composition, a hypereutectic composition, and a eutectic composition. In consideration of increasing the specific resistance by growing flake graphite, a hypereutectic composition can be obtained. In this case, when chill is generated in an as-cast state, heat treatment may be performed after casting to promote ferritization. The heat treatment temperature is A ₁ It can be above the transformation point, for example in the range 750 to 1100 ° C., in particular 900 to 1050 ° C. However, even if chill is generated, it may be used without heat treatment.
[0023]
-According to the manufacturing method of the present invention, the process of heating the mold and the process of pouring a molten metal of flake graphite cast iron composition into the cavity of the heated mold and cooling the molten metal while slowing the cooling rate. To do. The temperature drop rate affects the growth of flake graphite. For this reason, as a temperature-decreasing rate at a temperature (600 ° C. or higher) that affects the crystallization form of flake graphite, it is 30 ° C./min or less at the casting surface portion. And It is preferably 20 ° C./min or less, particularly preferably 10 ° C./min or less. Examples of the heating element for heating the mold include a heating element such as an electric heater embedded in the mold and a gas burner. A typical mold is a sand mold. The sand mold is a mold having sand particles, and includes a fresh sand mold, a self-hardening mold, a shell mold, and the like. The step of heating the mold is performed before pouring the molten metal. As a result, the solidification rate and the cooling rate after solidification can be further reduced, which is advantageous for growth of flake graphite and an increase in the ferrite area ratio. The step of heating the mold can be performed while pouring the molten metal or after pouring the molten metal. Covering the outer surface of the mold with a heat insulating material is also effective for growing flake graphite and increasing the ferrite area ratio.
[0024]
・ The present invention In Such a soft magnetic material may be used for supplying a DC pulse to the excitation winding, or may be used for supplying an AC current to the excitation winding. For example, a motor, an electromagnetic valve, etc. are employable as an electromagnetic actuator which can be used for the magnetic circuit formation material used for the electrical equipment represented by the electromagnetic actuator, and an electronic device. For motors, it can be used for rotor cores, stator cores, and the like. As a motor, in the case of a vehicle, it can be used with various motors such as an ABS system motor, a power steering motor, a wiper motor, a window regulator motor, a door lock motor, and a sunroof motor. It is not limited.
[0025]
【Example】
Examples in which the present invention is embodied will be described below. By weight, high purity pig iron (carbon content 4.0 wt%) 6 kg, carbon steel (JIS G4051 S25C) 19 kg, carburizing agent (C content 70 wt%) 680 g, ferrosilicon (Si content 70 wt%) 1150 g Were weighed and put into a high-frequency induction furnace for melting to prepare a molten metal. The molten metal was poured into a mold, that is, a self-hardening sand mold cavity, and solidified to form a casting. The pouring temperature was 1450 ° C. At the time of pouring, inoculation was performed using carballoy (Fe-Si series) made by Osaka Special Alloy. One hour after pouring, the sand mold was collapsed and the casting was taken out.
[0026]
In order to suppress a decrease in hot water temperature during pouring, a rod-shaped electric heating element 10 as a heating element was embedded in the sand mold 20 as shown in a conceptual diagram in FIG. Prior to pouring, the vicinity of the cavity 22 of the sand mold 20 was preheated by the heating element 10. Furthermore, the outer surface of the sand mold 20 was covered with a heat insulating material (silica-based) to improve the heat insulating property of the sand mold 20 so that the cooling rate was not increased. The heating element 10 is not limited to a rod shape, and may be a planar shape or a panel shape.
[0027]
FIG. 2 shows an example of the temperature drop state of the casting after casting. In this case, a thermocouple was installed in a portion corresponding to the surface of the casting, and the temperature was measured. As shown in FIG. 2, the rate of temperature decrease is slow. The temperature drop rate affects the growth of flake graphite. For this reason, the temperature lowering rate at a temperature (1000 ° C. or more) affecting the crystallization form of flake graphite is 30 ° C./min or less, 20 ° C./min or less, particularly 10 ° C./min or less at the casting surface portion. It is preferable that In this embodiment, the above-described temperature drop rate is set to 10 ° C./min or less. When the rate of temperature decrease at a temperature (600 ° C. or higher) that affects the crystallization form of flake graphite is high, the growth of graphite tends to be hindered and the specific resistance is difficult to increase. According to the present embodiment, the heating element 10 preheats the vicinity of the cavity 22 of the sand mold 20, which is advantageous for slowing the temperature decrease rate and growing flake graphite.
[0028]
As Comparative Example 1, a spheroidal graphite cast iron casting was formed. In this case, 330 g of spheroidizing agent (TDCR-5 Mg manufactured by Toyo Denka Co., Ltd .: 4.8 wt%, Si: 46 wt%, Ca: 2.4 wt%, balance: Fe, average particle size: 20 mm), ferrosilicon (Si The content was 70 wt%, the balance: Fe) was 70 g, inserted into a crucible for spheroidization treatment, and the upper surface was covered with iron powder (iron powder 110 g). And the above-mentioned original hot water melt | dissolved to 1600 degreeC was poured in the spheroidization crucible, and the spheronization reaction was carried out. Thereafter, the molten metal after the spheroidizing treatment was poured into a self-hardening sand mold 20. Also in this case, the sand mold 20 was preheated with the heating element 10 prior to casting.
[0029]
Test pieces were collected from castings according to Examples and Comparative Examples. The test piece was collected at a depth of 10 mm from the outer peripheral surface of a cylindrical casting (diameter 60 mm, length 200 mm).
[0030]
FIG. 3 shows an optical micrograph (100 times) obtained by photographing the structure of the test piece according to Example 4 having a good specific resistance. In this case, the matrix base is a ferrite base, and the ferrite area ratio is 90% when the entire area of the matrix base (excluding micro obstacles) is 100% when observed on the two-dimensional cut surface of the matrix base. That was all. As shown in FIG. 3, a large number of flake graphite grown so as to form a labyrinth at a matrix base was irregularly dispersed, and a form in which adjacent flake graphites were approached or connected was observed. . In addition, flake graphite grew both in the length direction and in the radial direction of the test piece. According to FIG. 3, it can be seen that a large number of smart flake graphite having a long width but a small width are dispersed. Thus, if a large number of smart flake graphites are dispersed, it is advantageous to increase the specific resistance of the soft magnetic material while ensuring the strength and permeability of the soft magnetic material. In order to produce a large number of smart flake graphite, it is effective to increase the silicon content while relatively suppressing the carbon content. In particular, it is effective to make the silicon content larger than the carbon content.
[0031]
When the degree of dispersion of flake graphite is seen from another viewpoint, when a straight line having a length of 720 μm is defined in a micrograph (FIG. 3) showing a magnification of 100 times, flake graphite as a minute obstacle and the straight line are The number of intersecting portions is 12 or more, particularly 14 or more. The large number of intersections corresponds to the fact that a large number of smart flake graphites are irregularly dispersed in the matrix matrix and the specific resistance of the soft magnetic material can be increased.
[0032]
For the test pieces of other examples, the same structure as that shown in FIG. 3 was obtained. That is, a large number of smart flake graphites grown to form a labyrinth were irregularly dispersed in the ferrite matrix matrix, and a form in which adjacent flake graphites were close to each other or connected was observed. . Also for the test pieces of the other examples, the ferrite area ratio was 90% or more, and the number of the intersecting portions was basically the same.
[0033]
Table 1 shows the carbon content, silicon content, perimeter length related to graphite, ellipse long / short axis ratio related to graphite, and specific resistance for each test piece. The specific resistance was measured at room temperature based on the 4-terminal method (JIS C2525). The perimeter for graphite and the ellipse major axis ratio for graphite were measured as follows. That is, a photograph (100 times magnification) of the optical microscopic structure of the test piece was captured with a scanner, the shade of the captured image was binarized into black and white, and only the object that was a black portion was detected. The object corresponds to flake graphite. In this image analysis, graphite having a maximum particle size of 5 μm or less was excluded.
[0034]
Here, as shown in FIG. 4, the perimeter related to graphite means the length of the outer periphery of the object in the image, means the length from the start end to the end of the outer periphery of the object, and extends along the length direction of the object. Including the length of the forward path and the length of the return path. The ellipse long / short axis ratio for graphite corresponds to the aspect ratio of the object in the image, and the major axis length along the major axis of the simulated ellipse simulating the object, and the minor axis length along the minor axis. Was calculated as (major axis length / minor axis length). The simulated ellipse means an ellipse that has the same area with respect to the object and is defined so that the first moment and the second moment are equal to the object. In addition, the perimeter length related to graphite and the ellipse long / short axis ratio related to graphite were performed by software processing of Image-Pro PLUS manufactured by Planetron Co., Ltd.
[0035]
As shown in Table 1, in many examples, it is formed of cast iron in which the silicon content is set larger than the carbon content. In addition, according to Example 3 and Example 7, although silicon content is less than carbon content, silicon is contained comparatively much with 2.5%.
[0036]
As shown in Table 1, the perimeter of graphite was less than 80 μm in Comparative Example 1, but was 80 μm or more, particularly 100 μm or more in Examples. In particular, in Examples 1, 2, and 4, the perimeter of graphite was as long as 200 μm or more. The elliptical / minor axis ratio for graphite was 2 or less in Comparative Example 1, but was 2 or more in each Example, particularly 4 or more.
[0037]
Furthermore, as shown in Table 1, Examples 1 to 9 formed of flake graphite cast iron showed higher specific resistance than Comparative Example 1 formed of spheroidal graphite cast iron. It is presumed that flake graphite cast iron has a higher rate of diverting current than spheroidal graphite cast iron. In particular, Examples 1, 2 and 4 showed high specific resistance. In Examples 1, 2 and 4, the perimeter of graphite is considerably long.
[0038]
[Table 1]

[0039]
[Table 2]

[0040]
Table 2 shows the results of the magnetic characteristics of the test pieces according to the respective examples and comparative example 1. The magnetic characteristics were measured by supplying a sinusoidal alternating current using a BH analyzer SY-8232 by Iwasaki Tsushinki Co., Ltd. In this case, the magnetic characteristics were measured when H (magnetic field) was 2000 A / m.
[0041]
As shown in Table 2, with respect to loss (iron loss), each example made of flake graphite cast iron is made of spheroidal graphite cast iron regardless of whether the frequency of the alternating current is 1000 Hz, 2000 Hz, or 3000 Hz. The loss (iron loss) could be made smaller than that of Comparative Example 1.
[0042]
As for the magnetic flux density, when the frequency was 1000 Hz, the magnetic flux density in Comparative Example 1 was higher than that in each example. When the frequency was 2000 Hz, the magnetic flux density of each example approached that of Comparative Example 1. Further, when the frequency was high, such as 3000 Hz, the magnetic flux density of each example was comparable to or higher than that of Comparative Example 1. As described above, in this embodiment, the magnetic flux density can be relatively increased as the frequency is increased.
[0043]
As described above, according to each embodiment, since the specific resistance is high, iron loss can be reduced when an alternating magnetic field acts, and heat generation when applied to a magnetic circuit forming member such as a motor core can be suppressed. Can do.
[0044]
The iron loss is basically represented by hysteresis loss Wh + eddy current loss We + residual loss Wr, and is greatly affected by the frequency. For iron-based materials, the residual loss Wr is generally small. For this reason, what is important in iron-based magnetic circuit forming members such as motor cores is hysteresis loss Wh and eddy current loss We. The hysteresis loss Wh per unit time is basically expressed by equation (1). In the case of a plate material, the current loss We per unit time is basically expressed by equation (2).
Wh = Kh · f · Bm (1)
We = (Ke · f ² ・ T ² ・ Bm ² ) / Ρ …… (2)
Here, Kh and Ke are constants. f indicates a frequency, and in the case of a direct current pulse, it can be regarded as 1 Hz at the rising edge and falling edge of the pulse. Bm represents the magnetic flux density. t indicates the thickness of the plate material. ρ represents the specific resistance of the material.
[0045]
According to the above equations (1) and (2), if the frequency f is high, the hysteresis loss Wh and the eddy current loss We increase, so the iron loss increases. Therefore, in order to suppress the iron loss, it is important to deal with the high frequency region. According to the soft magnetic material of this example, as shown in Table 2, loss can be suppressed even when used in a high frequency region.
[0046]
When the soft magnetic material is formed of cast iron as in the present embodiment, the product approximate shape can be formed by utilizing the excellent castability of cast iron, and the cutting process can be reduced or eliminated. For this reason, a magnetic circuit forming member such as a three-dimensional shape core can be easily manufactured, so that downsizing and thinning of a device such as a motor can be manufactured at a relatively low cost.
[0047]
Further, the silicon content is advantageous for increasing the magnetic permeability of the soft magnetic material. However, when a soft magnetic material is formed by laminating silicon steel plates, since the hardness increases when the silicon content is large, the press punchability of the silicon steel plate tends to decrease, and the amount of silicon increase is limited. . However, when soft magnetic material is formed with cast iron, it is not necessary to consider the reduction in press punchability of the steel sheet, so that the approximate shape of the product can be formed easily and inexpensively by utilizing the excellent castability of cast iron. it can. For this reason, it is advantageous in increasing the silicon content of the soft magnetic material and increasing the magnetic permeability. Therefore, silicon can be easily adjusted to 2.5% or more, 3.0% or more and 4.0% or more by mass ratio as in this embodiment, and similarly, the ratio of (silicon content / carbon content). It is also good to increase.
[0048]
When the use condition is severe, the soft magnetic material formed by laminating the silicon steel plates may cause warpage deformation or peeling of each silicon steel plate, and is not necessarily sufficient in terms of stabilization of strength and magnetic properties. Since the soft magnetic material of the present embodiment is based on a melted material, that is, a casting, the soft magnetic material is highly integrated, which is advantageous in securing mechanical strength. Accordingly, the strength and magnetic properties can be stabilized even in a high temperature environment or an environment with temperature changes. For this reason, it is suitable for use in an environment where use conditions are severe, for example, a vehicle such as an automobile. Therefore, it is suitable for a magnetic circuit forming member (for example, a motor core material) requiring strength.
[0049]
(Other examples)
The second embodiment according to the present invention is basically manufactured in the same manner as the above-described embodiment. Further, the casting formed of flake graphite cast iron after casting is annealed in a heat treatment furnace to further promote ferritization at the matrix base. Thereby, a ferrite area ratio can be raised further and magnetic permeability can be improved. The heat treatment can be performed by heating and holding within a range of 750 to 1100 ° C. for a predetermined time. As an atmosphere for the heat treatment, an air atmosphere, a vacuum atmosphere, a reducing atmosphere, or the like can be adopted. When the heat treatment temperature is high and the heat treatment time is long, the crystal grain size of the ferrite can be increased, which can further contribute to the improvement of magnetic permeability and magnetic flux density. The heat treatment time varies depending on the required ferrite area ratio and casting size, but can generally be set within a range of 10 minutes to 100 hours.
[0050]
According to the present invention Reference example According to the present invention, the soft magnetic material includes an iron-based matrix base (ferrite type) having magnetic permeability and conductivity, and a group of ceramic fibers made of ceramic fibers dispersed in the matrix base. The ceramic fiber functions as a fine obstacle having an electric resistance higher than that of the matrix base, and examples thereof include an alumina fiber and a silica fiber. Even in this case, a large number of fibers grown so as to form a maze in the matrix base are dispersed irregularly. The specific resistance of the fibers is considerably larger than the specific resistance of the iron-based matrix base and can be regarded as an obstacle to the current flow. For this reason, it is advantageous in increasing the specific resistance of the soft magnetic material and reducing the iron loss.
[0051]
(Application example)
FIG. 5 shows an example applied to a motor. As shown in FIG. 5, the motor has a stator core 40 fixed to the housing, and a rotor 52 that can rotate within the stator core 40. The rotor 52 has a shaft 53 and a rotor core 54 held by the shaft 53. The rotor core 54 has a plurality of protrusions 55 that protrude in the radially outward direction and are integrally arranged along the circumferential direction. An excitation winding (not shown) is wound around each protrusion 55. When a direct current pulse current of U phase, V phase, and W phase is supplied to the excitation winding of the protrusion 55, the rotor 52 rotates about its axis. The rotor core 54 is made of flake graphite cast iron, and includes an iron-based matrix base (ferrite type) having magnetic permeability and conductivity, and a flake graphite group made of flake graphite dispersed in the matrix base. Yes. This flake graphite cast iron is formed on the basis of any one of the first to ninth embodiments described above.
[0052]
In addition, the present invention is not limited to the above-described embodiments and application examples, and can be implemented with appropriate modifications within a range not departing from the gist. The following technical idea can also be grasped from the above description.
(Additional Item 1) In each claim, the minute obstacle is curved or curved. Soft Magnetic material and manufacturing method thereof. This is advantageous for increasing the specific resistance.
[0053]
【The invention's effect】
As described above, the magnetic circuit according to the present invention Soft The magnetic material is advantageous for increasing the specific resistance and is advantageous for reducing the loss. In particular, the magnetic circuit according to the present invention. Soft The magnetic material becomes more effective as the frequency increases.
[0054]
According to the method of the present invention, the melt of flake graphite cast iron composition is poured into the heated mold cavity and cooled, so the solidification rate of the cast iron and the cooling rate can be reduced, and the flake graphite grows. Can be promoted. As a result, an induced current such as an eddy current generated in the soft magnetic material can be bypassed, and the current path can be contributed to a maze, which is advantageous in reducing loss. Further, the ferrite formation of the matrix base can be promoted, and the magnetic permeability of the soft magnetic material can be further increased.
[Brief description of the drawings]
FIG. 1 is a conceptual diagram showing a sand mold equipped with a heating element.
FIG. 2 is a graph showing an example of a cooling curve when cast with a sand mold.
3 is a micrograph (magnification 100 times) of flake graphite cast iron according to Example 4. FIG.
FIG. 4 is a diagram showing the concept of perimeter related to graphite.
FIG. 5 is a conceptual diagram showing an example applied to a motor.
[Explanation of symbols]
In the figure, 40 is a stator core, 52 is a rotor, and 54 is a rotor core.

Claims (5)

It is formed of flake graphite cast iron containing 2% or more of carbon and 2% or more of silicon by mass ratio. When flake graphite cast iron is observed on the two-dimensional cut surface of the matrix matrix, (Not including) the area of the ferrite is 50% or more, and the flake graphite has an elliptical long / short axis ratio of 2 or more on average. Soft magnetic material. 2. A magnetic soft magnetic material according to claim 1, wherein when the two-dimensional cut surface of the matrix base is observed, the flake graphite is irregularly dispersed. 3. The magnetic soft magnetic material according to claim 1, wherein when the two-dimensional cut surface of the matrix base is observed, an average perimeter of the flake graphite is 80 μm or more. The soft magnetism for a magnetic circuit according to any one of claims 1 to 3, wherein the flake graphite cast iron is set to have a mass ratio and a silicon content larger than a carbon content. material. It is a manufacturing method of the soft-magnetic material for magnetic circuits as described in any one of Claims 1-4, Comprising:
  A step of heating a mold having a cavity for forming a casting, and pouring a molten metal having a flake graphite cast iron composition containing 2% or more of carbon and 2% or more of silicon in a mass ratio into the cavity of the heated mold, A method for producing a soft magnetic material for a magnetic circuit, wherein a casting is formed by cooling under a condition that a temperature drop rate at 600 ° C. or higher is 30 ° C./min or less at a casting surface portion.

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