JPH06271997A - Silicon steel sheet for laminated iron core excellent in end face weldability - Google Patents

Silicon steel sheet for laminated iron core excellent in end face weldability

Info

Publication number
JPH06271997A
JPH06271997A JP6204093A JP6204093A JPH06271997A JP H06271997 A JPH06271997 A JP H06271997A JP 6204093 A JP6204093 A JP 6204093A JP 6204093 A JP6204093 A JP 6204093A JP H06271997 A JPH06271997 A JP H06271997A
Authority
JP
Japan
Prior art keywords
steel sheet
weldability
load curve
roughness
silicon steel
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.)
Granted
Application number
JP6204093A
Other languages
Japanese (ja)
Other versions
JP3419016B2 (en
Inventor
Taizo Mori
泰三 毛利
Atsuto Honda
厚人 本田
Hideo Kobayashi
秀夫 小林
Takashi Obara
隆史 小原
Tomoyuki Ichi
智之 市
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
JFE Steel Corp
Original Assignee
Kawasaki Steel Corp
Priority date (The priority date 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 date listed.)
Filing date
Publication date
Application filed by Kawasaki Steel Corp filed Critical Kawasaki Steel Corp
Priority to JP06204093A priority Critical patent/JP3419016B2/en
Publication of JPH06271997A publication Critical patent/JPH06271997A/en
Application granted granted Critical
Publication of JP3419016B2 publication Critical patent/JP3419016B2/en
Anticipated expiration legal-status Critical
Expired - Fee Related legal-status Critical Current

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  • Soft Magnetic Materials (AREA)
  • Manufacturing Of Steel Electrode Plates (AREA)

Abstract

PURPOSE:To obtain a silicon steel sheet for laminated iron core having both weldability and blanking capability by specifying the three dimensional surface roughness of the silicon steel sheet by adjusting its surface ruggedness. CONSTITUTION:The surface ruggedness of a silicon steel sheet is adjusted by rolling roll. The three dimensional surface roughness of the steel sheet is satisfied such that a center surface average roughness SRa is <=0.5mum, max. height SRma is 0.1-0.2mum and, for each recess, as the largest point of depth direction fall in load curve (the differential coefficient of load curve is min. except points of 0% and 100% of cutting face area ratio) is assumed to be the center, the difference in height direction at two points, where cutting face area ratios differ + or -10%, respectively, is >=50% of SRmax. An insulating film is formed on the steel sheet surface with a deposit of 0.2-2.5g/m<2>. By this method, the end face weldability is improved.

Description

【発明の詳細な説明】Detailed Description of the Invention

【0001】[0001]

【産業上の利用分野】この発明は、表面に精確な凹凸パ
ターンを有する圧延用ロールを用いて表面粗さ調整を行
った積層鉄心用電磁鋼板に関し、特にその端面溶接性の
改善を図ったものである。
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a magnetic steel sheet for laminated cores, the surface roughness of which is adjusted by using a rolling roll having an accurate uneven pattern on the surface, and particularly, the end face weldability of the steel sheet is improved. Is.

【0002】[0002]

【従来の技術】モーター、トランス等に使用される電磁
鋼板は、磁気特性に優れるだけでなく、量産性の観点か
ら良好な打抜性も要求され、この要請を満たすために一
般に有機樹脂を含む絶縁被膜が被成される。しかしなが
ら、この被膜は、溶接時に有機樹脂から発生する多量の
ガスに起因してブローホールを発生するなど溶接性の点
に問題を残していた。この点を解消するものとして、鋼
板表面に20 Hr.m.s.μinch以上の表面粗さを付与したの
ち有機質被膜を被成する方法(特公昭49−6744号公報)
や、有機質被膜自体に粗さを与え、溶接時に発生するガ
スを逸散させることによりブローホールの発生を防止す
る方法(特公昭49-19078号公報) 等が提案されている。
2. Description of the Related Art Magnetic steel sheets used for motors, transformers, etc. are required not only to have excellent magnetic properties, but also to have good punchability from the viewpoint of mass productivity. An insulating coating is applied. However, this coating still has a problem in terms of weldability, such as generation of blowholes due to a large amount of gas generated from the organic resin during welding. As a solution to this point, a method of applying a surface roughness of 20 Hr.ms μinch or more to the surface of a steel sheet and then forming an organic coating (Japanese Patent Publication No. 49-6744).
Alternatively, a method of preventing the formation of blowholes by giving roughness to the organic coating itself and dissipating gas generated during welding (Japanese Patent Publication No. Sho 49-19078) and the like have been proposed.

【0003】また特開昭54−134043号公報においては、
表面粗さを中心線平均粗さRaで0.35〜0.6 μm とした鋼
板上に被膜厚み1〜2.5 g/m2の有機質被膜を被成する方
法が提案された。しかしながらこの方法では、溶接箇所
によってはブローホールの発生が見られ、必ずしも良好
な溶接性が安定して得られるとは限らず、そのため打抜
性の向上を目指して被膜厚を厚くするといった処置を施
すことができないという問題があった。
Further, in JP-A-54-134043,
A method of depositing an organic coating having a coating thickness of 1 to 2.5 g / m 2 on a steel sheet having a surface roughness of 0.35 to 0.6 μm in terms of centerline average roughness Ra has been proposed. However, in this method, blowholes are observed to occur depending on the welding location, and good weldability is not always obtained stably.Therefore, it is necessary to increase the film thickness to improve punchability. There was a problem that it could not be applied.

【0004】[0004]

【発明が解決しようとする課題】上述したとおり、これ
まではブローホールの発生を完全に防止することが難し
く、その改善が望まれていた。この発明は、上記の要請
に有利に応えるもので、被膜特性に悪影響を及ぼすこと
なしに、ブローホールの発生を効果的に防止した積層鉄
心用電磁鋼板を提案することを目的とする。
As described above, it has been difficult to completely prevent the generation of blowholes, and improvement thereof has been desired. The present invention advantageously responds to the above-mentioned demands, and an object thereof is to propose a magnetic steel sheet for laminated iron core that effectively prevents the generation of blowholes without adversely affecting the coating properties.

【0005】[0005]

【課題を解決するための手段】さて発明者らは、上記の
問題を解決すべく、各種の調査及び検討を行なった結
果、電磁鋼板の積層端面溶接に際しては、鋼板表面の粗
さよりも、圧延模様や、圧延疵などの表面の凹凸のパタ
ーンの影響の方が強いことを見出した。この発明は、上
記の知見に立脚するもので、鋼板表面における凹凸パタ
ーンを適正に制御することにより、従来困難とされた有
機質絶縁被膜をそなえる積層用電磁鋼板の積層端面溶接
性の改善を実現したものである。
Means for Solving the Problems Now, as a result of various investigations and studies in order to solve the above-mentioned problems, the inventors have found that when laminating end faces of electromagnetic steel sheets, rolling is performed rather than surface roughness of the steel sheets. It was found that the influence of the pattern and the pattern of surface irregularities such as rolling flaws was stronger. This invention is based on the above knowledge, and by appropriately controlling the uneven pattern on the surface of the steel sheet, the improvement of the weldability of the laminated end surface of the electromagnetic steel sheet for lamination having the organic insulating coating, which has been conventionally difficult, is realized. It is a thing.

【0006】すなわち、この発明の要旨構成は次のとお
りである。 1.圧延ロールによって表面凹凸を調整した電磁鋼板で
あって、鋼板表面の3次元表面粗さが、中心面平均粗さ
SRa で 0.5μm 以下、最大高さSRmax が 0.1〜2.0 μm
でかつ、各凹部につき、負荷曲線で深さ方向落差が最も
大きい点(切断断面積率が0%又は 100%の点を除く負
荷曲線の微分係数が最小である点)を中心として切断面
面積率がそれぞれ±10%異なる2点間における高さ方向
の差がSRma x の50%以上、を満足することを特徴とする
端面溶接性に優れる積層鉄心用電磁鋼板。
That is, the gist of the present invention is as follows. 1. An electromagnetic steel sheet whose surface irregularities are adjusted by rolling rolls, in which the three-dimensional surface roughness of the steel sheet surface is the average roughness of the center plane.
SRa is 0.5 μm or less, maximum height SR max is 0.1 to 2.0 μm
And, for each recess, the cutting surface area centered on the point with the largest depth drop in the load curve (the point where the derivative of the load curve is the minimum except for the point where the cross-sectional area ratio is 0% or 100%) electromagnetic steel sheet for a laminated core having excellent end surface weldability characterized in that the difference in height direction rate is between each ± 10% different two points satisfies 50% or more, the SR ma x.

【0007】2.上記1において、鋼板表面に、付着量
が 0.2〜2.5 g/m2の絶縁被膜をそなえてなる端面溶接性
に優れる積層鉄心用電磁鋼板。
2. The electromagnetic steel sheet for laminated iron cores according to the above 1, which is excellent in end face weldability and is provided with an insulating coating film having an adhesion amount of 0.2 to 2.5 g / m 2 on the steel sheet surface.

【0008】ここに中心面平均粗さSRa とは、粗さ曲面
からその中心面上に面積SM を抜き取り、この抜き取り
部分の中心面上に直交座標軸、X軸、Y軸をおき、中心
面に直交する軸をZ軸として粗さ曲面をZ=f(X,
Y)で表したとき、次の数式
The center plane average roughness SRa is the area S M extracted from the roughness curved surface on the center plane, and the orthogonal coordinate axes, the X axis, and the Y axis are placed on the center plane of the extracted portion. The roughness surface is Z = f (X,
Y), the following formula

【数1】 で与えられる値のことである(単位μm )。[Equation 1] Is the value given by (unit: μm).

【0009】また負荷曲線とは、図1に示されれるよう
な曲線を意味する。すなわち単位面積における最大高さ
SRmax を縦軸の最大点として、任意の切断高さz(μm
)を縦軸とする。一方、横軸は、単位面積に対する各
切断レベルにおける切り口面積の 100分率(切断面面積
率)とする。かかる座標において、切断高さzを、最大
高さSRmax から次第に低減したときの切断高さと切断面
面積率との関係を示したのが負荷曲線である。従って、
たとえば切断面面積率が10%のときの凸部の高さとは図
中にxで示される値である。なお、ここで言う凹部と
は、いわゆる穴であっても、または溝であってもいずれ
でもかまわない。
The load curve means a curve as shown in FIG. Ie maximum height in unit area
Using SR max as the maximum point on the vertical axis, cut height z (μm
) Is the vertical axis. On the other hand, the horizontal axis is the 100-percentage ratio of the cut area at each cutting level to the unit area (cut surface area ratio). At these coordinates, the load curve shows the relationship between the cutting height and the cutting surface area ratio when the cutting height z is gradually reduced from the maximum height SR max . Therefore,
For example, the height of the convex portion when the cut surface area ratio is 10% is a value indicated by x in the figure. In addition, the recessed portion may be a so-called hole or a groove.

【0010】以下、この発明を具体的に説明する。さて
発明者らは、以前に、各種の表面粗さを有する有機樹脂
含有絶縁被膜付き鋼板を用い、これを積層した後、断面
を溶接し、その溶接性について調査した。その結果、従
来使用されてきた2次元表面粗さによる評価では、同一
の表面粗さとされたものでも溶接性にばらつきが生じ、
必ずしも2次元表面粗さでは溶接性を正確に評価できな
いことが判明した。そこで、新たに3次元表面粗さによ
る評価に想到し、改めて3次元粗さ測定器で測定して再
調査したところ、以下に述べる結果が得られた。
The present invention will be described in detail below. The inventors previously used steel sheets with an organic resin-containing insulating coating having various surface roughnesses, laminated the steel sheets, welded the cross-sections, and investigated their weldability. As a result, in the evaluation based on the two-dimensional surface roughness that has been conventionally used, the weldability varies even if the surface roughness is the same.
It has been found that the weldability cannot always be accurately evaluated by the two-dimensional surface roughness. Therefore, when a new evaluation based on the three-dimensional surface roughness was conceived, the measurement was conducted again by the three-dimensional roughness measuring device, and the re-examination was conducted, and the following results were obtained.

【0011】得られた結果を、中心面平均粗さSRa と中
心面における切断面面積率との関係で図2に示す。ここ
に、中心面における切断面面積率は、単位面積SM にお
ける中心面で切断された面積S′の面積率S′/SM ×
100 (%)で与えられる。同図より明らかなように、表
面粗さが中心面平均粗さSRa で0.50μm を超えると占積
率が低下した。かかる表面粗さの影響は従来どおりであ
ったが、同一粗さでも溶接性に相違が見られた。すなわ
ち、 SRaが0.50μm 以下の適正範囲であっても、中心面
における切断面面積率が80%を超えた場合には溶接性の
急激な劣化がみられたのである。
The obtained results are shown in FIG. 2 as a relationship between the center surface average roughness SRa and the cut surface area ratio in the center surface. Here, the cut surface area ratio in the central plane is the area ratio S ′ / S M of the area S ′ cut in the central plane in the unit area S M.
It is given at 100 (%). As is clear from the figure, when the surface roughness exceeds 0.50 μm in the center surface average roughness SRa, the space factor decreases. The influence of such surface roughness was the same as before, but there were differences in weldability even with the same roughness. That is, even if SRa was in the proper range of 0.50 μm or less, the weldability was rapidly deteriorated when the cut surface area ratio in the central plane exceeded 80%.

【0012】そこで発明者らは、上記の事実に鑑み、鋼
板の表面粗さと積層端面溶接性の関係につき、さらに詳
細に調査を行った結果、溶接性は、鋼板の表面に凹部が
多く、鋼板を積層して TIG溶接を行った時にガスの逃げ
道が存在する場合に良好となることが知見された。すな
わち、溶接性は、鋼板の表面粗さよりもむしろ、鋼板表
面に形成される凹部の形状に強く依存することが新規に
見出されたのである。
[0012] In view of the above facts, the present inventors have conducted a more detailed investigation on the relationship between the surface roughness of the steel sheet and the weldability of the laminated end faces, and as a result, the weldability has many recesses on the surface of the steel sheet. It has been found that it becomes good when there is a gas escape route when TIG welding is performed by stacking layers. That is, it was newly found that the weldability strongly depends not on the surface roughness of the steel sheet but on the shape of the recess formed on the steel sheet surface.

【0013】そこで次に、凹部の形状について検討した
結果、図3に示すような、凹部の底面が平坦部を有しか
つ該底面と凹部の肩とが接する角度が直角に近い凹部を
多数存在した場合に、溶接性が格段に向上することが判
明した。
Then, as a result of examining the shape of the recess, as shown in FIG. 3, there are many recesses each having a flat bottom surface and a contact angle between the bottom surface and the shoulder of the recess is nearly a right angle. It was found that the weldability was significantly improved in the case of doing.

【0014】そこでさらに、かかる凹部の具体的な好適
形状について検討した結果、3次元表面粗さが、中心面
平均粗さSRa で 0.5μm 以下、最大高さSRmax が 0.1〜
2.0μm でかつ、負荷曲線で深さ方向落差が最も大きい
点(切断断面積率が0%又は100%の点を除く負荷曲線
の微分係数が最小である点)を中心として切断面面積率
がそれぞれ±10%異なる2点間における高さ方向の差が
SRmax の50%以上の場合に、とりわけ良好な溶接性が得
られることが判明したのである。
Then, as a result of further studying the specific preferable shape of the concave portion, the three-dimensional surface roughness of the center surface average roughness SRa is 0.5 μm or less, and the maximum height SR max is 0.1 to.
The cutting surface area ratio is 2.0μm, and the cutting surface area ratio is centered on the point where the depth-direction drop is the largest in the load curve (the point where the differential coefficient of the load curve is the minimum except the point where the cutting cross-sectional area ratio is 0% or 100%). The difference in the height direction between two points that differ by ± 10%
It was found that particularly good weldability was obtained when SR max was 50% or more.

【0015】ここに、負荷曲線で深さ方向落差が最も大
きい点、すなわち負荷曲線の微分係数が最も小さい点と
は、図4に点P点で示すような点であり、この点から切
断面面積率がそれぞれ±10%異なる点Q及びRの点の高
さの差をΔHとすると、このΔHが大きい程凹部底面と
凹部の肩が接する角度が直角に近くなり、逆にΔHが小
さい程鈍角となり、なだらかであることを示している。
なお、微分係数が最小の点を求める際に、切断面面積率
が0%及び 100%の点を除いた理由は、これらの点で
は、高い山あるいは深い谷が少しでもあるとその影響を
受け易く、微分係数は直ちに−∞となからである。
Here, the point on the load curve where the depthwise drop is the largest, that is, the point where the differential coefficient of the load curve is the smallest, is the point indicated by point P in FIG. If the difference in height between points Q and R, where the area ratios differ by ± 10%, is ΔH, the larger the ΔH, the closer the angle between the bottom of the recess and the shoulder of the recess will be, and conversely, the smaller ΔH is. It is an obtuse angle, indicating that it is gentle.
The reason why the points with cut surface area ratios of 0% and 100% were excluded when obtaining the point with the smallest differential coefficient is that even if there are any high peaks or deep valleys at these points, it is affected. This is because it is easy and the differential coefficient immediately becomes −∞.

【0016】さてこの発明において、凹部形状を上記の
ように限定した理由について説明する。まず SRaについ
ては、前掲図2に示したとおり、この値が 0.5μm を超
えると占積率の低下を招くので、 0.5μm 以下とした。
次に、SRmax が 0.1μm に満たないと、絶縁被膜処理を
施した時に凹部が埋まり、ガスの抜け道が十分に確保さ
れないので TIG溶接性の低下を招き、一方 2.0μm を超
えると、やはり占積率の低下を招くので、 0.1〜2.0 μ
m の範囲に限定した。さらに、負荷曲線で深さ方向落差
が最も大きい点、すなわち負荷曲線の微分係数が最小で
ある点を中心として切断面面積率がそれぞれ±10%異な
る2点間における高さ方向の差を、SRmax の50%以上と
したのは、この値がSRmax の50%に満たないと、凹凸の
形状がなだらかとなり、絶縁被膜処理を施した場合に凹
部が埋まって TIG溶接時にガスの抜け道が確保されず、
TIG 溶接性が劣化するからである。
In the present invention, the reason why the shape of the recess is limited as described above will be described. First, as shown in Fig. 2 above, SRa was set to 0.5 µm or less because if this value exceeds 0.5 µm, the space factor will decrease.
Next, if SR max is less than 0.1 μm, the recess will be filled when the insulating coating is applied, and the gas escape path will not be sufficiently secured, resulting in a decrease in TIG weldability. 0.1-2.0 μ
Limited to m range. Furthermore, the difference in the height direction between the two points where the cutting surface area ratios differ by ± 10% around the point where the depth difference in the load curve is the largest, that is, the point where the differential coefficient of the load curve is the minimum, was a max of 50% or more, when this value is less than 50% of SR max, is a gentle shape of the unevenness, the gas loopholes when TIG welding filled recesses when subjected to insulating coating treatment ensuring not,
This is because the TIG weldability deteriorates.

【0017】次に、この発明鋼板の製造方法について説
明する。鋼板表面に適正な凹凸パターンを転写形成する
ためには、圧延ロールの表面に適正な凹凸パターンを形
成しなければならない。
Next, a method for manufacturing the steel sheet of the present invention will be described. In order to transfer and form an appropriate concavo-convex pattern on the surface of the steel sheet, an appropriate concavo-convex pattern must be formed on the surface of the rolling roll.

【0018】従来から、スキンパス圧延用ロールの表面
をダル仕上げするための方法としては、ショットブラス
トによる方法や放電加工による方法、さらには特開昭62
−224405号公報に開示のようなレーザー加工による方
法、特開平2-99208号公報に開示のようなスクリーン印
刷とエッチング又はスクリーン印刷とめっきとを組合せ
た方法などがある。しかしながら、ショットブラスト法
や放電加工法によってダル仕上げされた圧延用ロール
は、表面に形成された粗度パターンが不規則であるた
め、かかるロールを用いて圧延した場合には、鋼板表面
の粗度パターンも不規則となる。しかも任意の凹凸パタ
ーンを形成することは不可能である。
Conventionally, as a method for dull-finishing the surface of a roll for skin-pass rolling, a method by shot blasting, a method by electric discharge machining, and further, JP-A-62-62
There is a method by laser processing as disclosed in JP-A-224405, a method combining screen printing and etching or a combination of screen printing and plating as disclosed in JP-A-2-99208. However, the rolling roll dull-finished by the shot blasting method or the electric discharge machining method has an irregular roughness pattern formed on the surface. The pattern is also irregular. Moreover, it is impossible to form an arbitrary uneven pattern.

【0019】一方、レーザー加工による場合は、規則的
な粗度パターンは得ることができるけれども、図5に示
すように、レーザー照射によりレーザー中心から離れた
部位が同心円状に盛り上がり、これにより微細なパター
ンを得ることができないし、凹部形状を任意に選択する
こともできない。またロールに直接レーザービームを用
いて穿孔するため、圧延ロールのように広い面積を持つ
被加工物を能率よく加工するためには、レーザー発振器
はしては1kW以上の高出力が要求され、必然的に炭酸ガ
スレーザーとならざるを得ず、加工装置が大型化し、費
用・保守の面での負担が大きい。さらに、レーザービー
ムによって金属が溶融されて形成された凹凸パターン
は、その凹凸部の組織がオーステナイトとなるので、こ
のようなロールは耐摩耗性に劣る。しかも、凹凸パター
ンの凹部の直径は、集光レンズで収束したレーザービー
ムの直径により決まるが、この直径は炭酸ガスレーザー
光の波長が長い(10.6μm )ため、物理的に約100 μm
以下にすることがでない不利もある。
On the other hand, in the case of laser processing, although a regular roughness pattern can be obtained, as shown in FIG. 5, a portion away from the laser center is raised in a concentric circle by laser irradiation, whereby a fine pattern is formed. It is not possible to obtain a pattern and it is not possible to arbitrarily select the shape of the recess. In addition, since the roll is directly drilled using a laser beam, a laser oscillator must have a high output of 1 kW or more in order to efficiently process a workpiece having a large area such as a rolling roll. Inevitably, it will be a carbon dioxide laser, and the processing equipment will become large, which will impose a heavy burden on costs and maintenance. Further, in the concavo-convex pattern formed by melting the metal by the laser beam, the texture of the concavo-convex portion becomes austenite, and thus such a roll has poor wear resistance. Moreover, the diameter of the concave portion of the concavo-convex pattern is determined by the diameter of the laser beam converged by the condenser lens, but this diameter is physically about 100 μm because the wavelength of carbon dioxide laser light is long (10.6 μm).
There is also a disadvantage that you cannot do the following:

【0020】他方、スクリーン印刷法を用いる方法は、
特開平2-99207号公報に見られるように、微細模様をス
クリーン印刷により圧延ロールの表面に印刷し、その
後、エッチング又はめっきを行って微細模様をロール表
面に形成し、該圧延ロールにより鋼板表面に微細模様を
転写することからなる方法であるが、この方法では、シ
ョットブラスト法のようにグリッド粒子を機械的にロー
ル表面に叩きつけてダル目付け加工を行った場合のよう
なうねりがロール表面に発生せず、また放電加工やレー
ザーによる加工法のように高エネルギーを加工部に集中
させることもないので、ロール表面の硬さが劣化せず均
一で、ロールから鋼板への微細模様の転写が可能であ
る。
On the other hand, the method using the screen printing method is
As disclosed in Japanese Patent Laid-Open No. 2-99207, a fine pattern is printed on the surface of a rolling roll by screen printing, and then etching or plating is performed to form a fine pattern on the roll surface. It is a method that consists of transferring a fine pattern to the roll surface.However, in this method, the waviness that occurs when dull weighting is performed by mechanically hitting the grid particles onto the roll surface like the shot blasting method is applied to the roll surface. Since it does not occur and high energy is not concentrated in the processing part like electrical discharge machining or laser processing method, the hardness of the roll surface does not deteriorate and it is uniform, and the fine pattern is transferred from the roll to the steel sheet. It is possible.

【0021】また、特公昭62-11922号公報には、耐酸腐
食性物質で表面を覆い、これをレーザー光で局所的に破
壊し、覆われていない部分を化学的に腐食する方法が開
示されている。さらに、特開平2−175882号公報には、
この技術を能率よく精密に容易に実施できるように改善
した方法及び装置を用い、次の工程から成る、整列され
た又は任意配列の凹凸を有するロールを加工する方法が
開示されている。すなわち、(1) 圧延ロール表面に光吸
収材を混入した耐酸腐食樹脂液を塗布して耐酸腐食性樹
脂膜を形成したのち、(2) この樹脂膜を連続的に平均で
5〜10Wの出力を有するQスイッチ・YAGレーザーを
用いてマーキング加工し、所要の模様に該ロール表面を
露出させ、(3) しかる後、エッチング処理を施してロー
ル表面に所望の模様を付与する方法である。
Further, Japanese Patent Publication No. 62-11922 discloses a method of covering the surface with an acid corrosion resistant substance, locally destroying it with a laser beam, and chemically corroding the uncovered portion. ing. Further, in Japanese Patent Laid-Open No. 2-175882,
Using the improved method and apparatus for performing this technique efficiently and precisely and easily, a method for processing a roll having aligned or arbitrarily arranged irregularities, which comprises the following steps, is disclosed. That is, (1) an acid-corrosion-resistant resin liquid mixed with a light-absorbing material is applied to the surface of the rolling roll to form an acid-corrosion-resistant resin film, and (2) this resin film is continuously output at an average of 5 to 10 W. Marking is performed by using a Q switch / YAG laser having the above, and the roll surface is exposed in a desired pattern. (3) After that, an etching process is performed to impart a desired pattern to the roll surface.

【0022】上掲した各種凹凸パターン形成方法のう
ち、スクリーン印刷法あるいは耐酸腐食性樹脂膜とQス
イッチ・YAGレーザーとを組み合わせた方法は、上述
したとおり、規則的に微細な凹凸模様を形成することが
できるので、これらの方法を用いることによって、この
発明の要件を満足する任意の凹部形状を得ることができ
る。
Among the above-mentioned various uneven pattern forming methods, the screen printing method or the method of combining the acid corrosion resistant resin film and the Q switch / YAG laser forms a regular fine uneven pattern as described above. Therefore, by using these methods, it is possible to obtain any recess shape satisfying the requirements of the present invention.

【0023】[0023]

【作用】次に、この発明において使用する絶縁被膜とし
ては、有機樹脂被膜、クロム酸塩系及び/又はりん酸塩
系と有機樹脂との混合被膜あるいはクロム酸塩系及び/
又はりん酸塩系被膜上に有機樹脂被膜を被成した2層被
膜などを用いることができる。
Next, as the insulating coating used in the present invention, an organic resin coating, a chromate-based and / or a mixed coating of a phosphate and an organic resin, or a chromate-based and / or
Alternatively, a two-layer coating in which an organic resin coating is formed on a phosphate coating can be used.

【0024】ここに被膜が、有機樹脂被膜単独であれ
ば、アクリル樹脂、アルキッド樹脂、フェノール樹脂、
エポキシ樹脂、エチレン樹脂、メラミン樹脂、シリコー
ン樹脂及びアミノ樹脂、あるいはそれらの変性物のうち
から選んだ1種又は2種以上が有利に適合する。
If the coating is an organic resin coating alone, acrylic resin, alkyd resin, phenol resin,
One or more selected from an epoxy resin, an ethylene resin, a melamine resin, a silicone resin and an amino resin, or modified products thereof are advantageously suitable.

【0025】また、クロム酸塩系及びりん酸塩系の1種
又は2種と有機樹脂との混合被膜を用いることもでき
る。ここでクロム酸塩系とは、カルシウム、マグネシウ
ム及び亜鉛の重クロム酸塩又は無水クロム酸にカルシウ
ム、マグネシウム及び亜鉛などの2価の酸化物、水酸化
物、炭酸御を溶解したものの1種又は2種以上の混合
物、あるいはそれらにさらに酸化チタン、コロイド状シ
リカ、コロイド状アルミナ、ほう酸及び有機還元剤等の
1種又は2種以上を添加したものである。また、りん酸
塩系としては、カルシウム、マグネシウム、アルミニウ
ム及び亜鉛のりん酸塩又はりん酸にカルシウム、マグネ
シウム、アルミニウム及び亜鉛等の2価又は3価の酸化
物、水酸化物、炭酸塩を溶解したものの1種又は2種以
上の混合物、あるいはそれらにさらに酸化チタン、コロ
イド状シリカ、コロイド状アルミナ及びほう酸等を1種
又は2種以上添加したものである。
It is also possible to use a mixed coating of one or two chromate-based and phosphate-based and an organic resin. Here, the chromate type is one of dichromate of calcium, magnesium and zinc or dichromic acid such as calcium, magnesium and zinc dissolved in chromic anhydride, hydroxide or carbonate. It is a mixture of two or more kinds, or one or more kinds of titanium oxide, colloidal silica, colloidal alumina, boric acid, an organic reducing agent and the like added thereto. As the phosphate system, calcium, magnesium, aluminum and zinc phosphates or phosphates are used to dissolve divalent or trivalent oxides, hydroxides and carbonates of calcium, magnesium, aluminum and zinc. One or a mixture of two or more of the above, or one or more of titanium oxide, colloidal silica, colloidal alumina, boric acid and the like added thereto.

【0026】さらに混合する有機樹脂としては、水溶性
又はエマルジョンタイプのアクリル樹脂及びその共重合
物、酢酸ビニル樹脂及びその共重合物、ベオバ樹脂スチ
レン樹脂共重合物、アミノ樹脂、アルキッド樹脂、フェ
ノール樹脂、無水マレイン酸共重合物、エポキシ樹脂又
はその変性物等の1種又は2種以上が有利に適合する。
さらに絶縁被膜は、2層構造とすることもできる。この
場合は上記したクロム酸塩系及びりん酸塩系の1種又は
2種の被膜を被成したのち、その上に重ねて有機樹脂被
膜を被成すれば良い。
The organic resin to be further mixed is a water-soluble or emulsion type acrylic resin and its copolymer, vinyl acetate resin and its copolymer, Veova resin styrene resin copolymer, amino resin, alkyd resin, phenol resin. One or more of maleic anhydride copolymers, epoxy resins and modified products thereof are advantageously suitable.
Furthermore, the insulating coating may have a two-layer structure. In this case, one or two chromate-based and phosphate-based coatings described above may be formed, and then an organic resin coating may be formed thereon.

【0027】ここに、かかる絶縁被膜の付着量は 0.2〜
2.5 g/m2とすることが好ましい。というのは、付着量が
0.2 g/m2 に満たないと十分な打ち抜き性が得られず、
一方 2.5 g/m2 を超えると溶接性が劣化するからであ
る。
Here, the adhesion amount of the insulating coating is 0.2 to
It is preferably 2.5 g / m 2 . Because the amount of adhesion is
If it is less than 0.2 g / m 2 , sufficient punching performance cannot be obtained,
On the other hand, if it exceeds 2.5 g / m 2 , the weldability will deteriorate.

【0028】なお、この発明において、素材である電磁
鋼板の組成はとくに限定されることはなく、従来公知の
ものいずれもが適合する。また表面粗さを得る手法につ
いは、上述したように、Qスイッチ−YAGレーザーを
用いてロール表面に予め、圧延後の表面パターンがこの
発明の範囲となるような表面加工を施しておく方法や、
スクリーン印刷法を利用する方法が好適であるが、これ
らの方法に特に限定されることはなく、以下のような方
法も使用可能である。すなわち、鋼板表面を研磨やエッ
チングにより、所定の表面パターンになるように処理す
る方法、あるいは圧延速度の変更又は圧延時に使用する
圧延油の変更により、所定の表面パターンになるよう処
理する方法等である。
In the present invention, the composition of the electromagnetic steel sheet as a raw material is not particularly limited, and any conventionally known one is suitable. As for the method of obtaining the surface roughness, as described above, a method in which the surface of the roll is preliminarily subjected to surface processing using the Q switch-YAG laser so that the surface pattern after rolling falls within the scope of the present invention, and ,
A method using a screen printing method is preferable, but the method is not particularly limited to these methods, and the following methods can also be used. That is, by a method of treating the steel plate surface by polishing or etching so as to have a predetermined surface pattern, or by a method of performing a predetermined surface pattern by changing the rolling speed or the rolling oil used during rolling. is there.

【0029】[0029]

【実施例】【Example】

実施例1 C:0.02%及びSi:0.20%を含有し、残部実質的にFeの
組成になる電磁鋼板を、Qスイッチ−YAGレーザーで
表面加工した圧延用ロールで圧延し、3次元表面粗さ
が、中心面平均粗さSRa で 0.3μm 、SRmax が 1.5μm
、負荷曲線で深さ方向落差が最も大きい点を中心とし
て左右断面面積率がそれぞれ±10%異なる点をとった
時、その高さ方向の偏差ΔHが 0.9μm である凹部を溝
状に形成した。ついでこの電磁鋼板の表面に、下記の処
理液1を、被膜目付け量が 1.0 g/m2 となるように塗布
したのち、 350℃で1分間焼付けた。
Example 1 An electrical steel sheet containing C: 0.02% and Si: 0.20% and the balance being substantially Fe composition was rolled by a rolling roll whose surface was processed by a Q switch-YAG laser to obtain a three-dimensional surface roughness. However, the center surface average roughness SRa is 0.3 μm and SR max is 1.5 μm.
When the load curve has a difference in lateral cross-sectional area ratio of ± 10% centering on the point with the largest depth direction drop, a recess having a deviation ΔH in the height direction of 0.9 μm was formed in a groove shape. . Then, the following treatment liquid 1 was applied to the surface of this magnetic steel sheet so that the coating weight was 1.0 g / m 2, and then baked at 350 ° C. for 1 minute.

【0030】[0030]

【表1】 〔処理液1〕 ・30%重クロム酸マグネシウム溶液 : 130 重量部 (CrO3分) : 32.5 重量部 ・アクリル樹脂エマルジョン(樹脂固形分:40%): 25 重量部 ・エチレングリコール : 10 重量部 ・ほう酸 : 10 重量部[Table 1] [Treatment liquid 1] ・ 30% magnesium dichromate solution: 130 parts by weight (CrO 3 minutes): 32.5 parts by weight ・ Acrylic resin emulsion (resin solid content: 40%): 25 parts by weight ・ Ethylene glycol: 10 parts by weight Boric acid: 10 parts by weight

【0031】かくして得られた、絶縁被膜付き電磁鋼板
の打抜性及び溶接性について調べた結果は次のとおりで
ある。なお打抜性は、ダイス径:15mmφスチールダイス
で打抜いた時のかえり高さが50μm に達するまでの打抜
回数で評価した。また溶接性は、電極:Th−w,加圧
力:100 kg/cm2,電極−材料間距離:1.5 mm,Arガス
量:6 l/min,電流:120Aの条件下に各種速度で溶接
を行ったときのブローホールの発生の有無で評価した。 ・打抜性:100 万回 ・溶接性:100cm/min で良好
The punching and welding properties of the thus-obtained magnetic steel sheet with an insulating coating were examined and the results are as follows. The punchability was evaluated by the number of punches until the burr height reached 50 μm when punching with a die diameter of 15 mmφ steel die. Weldability is as follows: electrode: Th-w, pressure: 100 kg / cm 2 , electrode-material distance: 1.5 mm, Ar gas amount: 6 l / min, current: 120 A at various speeds. It was evaluated based on whether or not blowholes were generated when the test was performed.・ Punchability: 1 million times ・ Welding property: 100 cm / min, good

【0032】比較例1 C:0.02%及びSi:0.20%を含有し、残部実質的にFeの
組成になる電磁鋼板を放電加工法で表面加工した圧延用
ロールで圧延して、3次元表面粗さが中心面平均粗さSR
a で0.40μm 、SRmax が 1.8μm 、負荷曲線で深さ方向
落差が最も大きい点を中心として左右断面面積率がそれ
ぞれ±10%異なる点をとった時、その高さ方向の偏差Δ
Hが 0.4μm である凹部が溝状である電磁鋼板の表面
に、下記の処理液2を、被膜目付け量が 1.0 g/m2 とな
るように塗布した後、 380℃で1分間焼き付けた。
Comparative Example 1 A magnetic steel sheet containing C: 0.02% and Si: 0.20% and the balance being substantially Fe composition was rolled by a rolling roll having a surface processed by an electric discharge machining method to give a three-dimensional surface roughness. Sag center surface average roughness SR
When a is taken to be 0.40 μm, SR max is 1.8 μm, and the cross-sectional area ratios on the left and right sides differ by ± 10% from the point of maximum load drop in the load curve, the deviation in the height direction Δ
The following treatment liquid 2 was applied to the surface of an electromagnetic steel sheet having H-shaped grooves of 0.4 μm and groove-shaped recesses, and then coated at a coating weight of 1.0 g / m 2 and then baked at 380 ° C. for 1 minute.

【0033】[0033]

【表2】 〔処理液2〕 ・30%重クロム酸マグネシウム溶液 : 130 重量部 (CrO3分) : 32.5 重量部 ・酢酸ビニル−ベオバ樹脂エマルジョン (樹脂固形分:40%) : 25 重量部 ・エチレングリコール : 10 重量部 ・ほう酸 : 10 重量部[Table 2] [Treatment liquid 2] ・ 30% magnesium dichromate solution: 130 parts by weight (CrO 3 minutes): 32.5 parts by weight ・ Vinyl acetate-veova resin emulsion (resin solid content: 40%): 25 parts by weight ・Ethylene glycol: 10 parts by weight Boric acid: 10 parts by weight

【0034】かくして得られた、絶縁被膜付き電磁鋼板
の打抜性及び溶接性について調べた結果は次の通りであ
った。 ・打抜性:110 万回 ・溶接性:40 cm/min で不良
The punching and welding properties of the thus obtained magnetic steel sheet with an insulating coating were examined and the results were as follows.・ Punchability: 1.1 million times ・ Welding property: Poor at 40 cm / min

【0035】実施例2 表5に示すロール加工法によって表面粗さを調整した圧
延ロールを用い、鋼板表面に表5に示す凹部形状になる
凹凸を形成した。ついで、鋼板の表面に、処理液1〜4
を、所定の量塗布した後、 350℃で1分間焼き付けた。
なお処理液3及び4の組成はそれぞれ、表3及び表4に
示すとおりである。かくして得られた絶縁被膜付き電磁
鋼板の打抜性及び溶接性について調べた結果を、表5に
併記する。
Example 2 Using a rolling roll whose surface roughness was adjusted by the roll processing method shown in Table 5, unevenness having the concave shape shown in Table 5 was formed on the surface of the steel sheet. Then, on the surface of the steel plate, the treatment liquids 1 to 4
Was applied in a predetermined amount and baked at 350 ° C. for 1 minute.
The compositions of the treatment liquids 3 and 4 are as shown in Tables 3 and 4, respectively. Table 5 also shows the results of an examination of punchability and weldability of the thus obtained insulating coated electromagnetic steel sheet.

【0036】[0036]

【表3】 〔処理液3〕 ・30%重クロム酸マグネシウム溶液 : 130 重量部 (CrO3分) : 32.5 重量部 ・アクリル酢酸ビニル樹脂エマルジョン (樹脂固形分:40%) : 25 重量部 ・エチレングリコール : 10 重量部 ・ほう酸 : 10 重量部[Table 3] [Treatment liquid 3] ・ 30% magnesium dichromate solution: 130 parts by weight (CrO 3 minutes): 32.5 parts by weight ・ Acrylic vinyl acetate resin emulsion (resin solid content: 40%): 25 parts by weight ・ Ethylene Glycol: 10 parts by weight Boric acid: 10 parts by weight

【0037】[0037]

【表4】 〔処理液4〕 ・ポリエステル樹脂/メラミン樹脂:75/25[Table 4] [Treatment liquid 4] -Polyester resin / melamine resin: 75/25

【0038】[0038]

【表5】 [Table 5]

【0039】表5より明らかなように、この発明に従い
得られた鋼板はいずれも、優れた打抜性と溶接性を兼ね
備えている。
As is clear from Table 5, all the steel sheets obtained according to the present invention have excellent punchability and weldability.

【0040】[0040]

【発明の効果】かくしてこの発明によれば、従来、両立
が困難とされた溶接性と打抜性とを共に兼ね備える積層
鉄心用電磁鋼板を得ることができる。
As described above, according to the present invention, it is possible to obtain a magnetic steel sheet for a laminated iron core having both weldability and punchability, which have hitherto been difficult to achieve compatibility.

【図面の簡単な説明】[Brief description of drawings]

【図1】負荷曲線の説明図である。FIG. 1 is an explanatory diagram of a load curve.

【図2】溶接性に及ぼす SRaと切断面面積率との関係を
示したグラフである。
FIG. 2 is a graph showing the relationship between SRa and the area ratio of cut surface that affect weldability.

【図3】この発明に従う好適凹部を示す模式図である。FIG. 3 is a schematic diagram showing a preferred recess according to the present invention.

【図4】表面凹凸を切断面面積率と凸部高さとの関係で
示したグラフである。
FIG. 4 is a graph showing the surface unevenness in terms of the relationship between the cut surface area ratio and the height of a convex portion.

【図5】従来法に従う凹部を示す模式図である。FIG. 5 is a schematic view showing a recess according to a conventional method.

───────────────────────────────────────────────────── フロントページの続き (72)発明者 小林 秀夫 千葉県千葉市中央区川崎町1番地 川崎製 鉄株式会社技術研究本部内 (72)発明者 小原 隆史 千葉県千葉市中央区川崎町1番地 川崎製 鉄株式会社技術研究本部内 (72)発明者 市 智之 岡山県倉敷市水島川崎通1丁目(番地な し) 川崎製鉄株式会社水島製鉄所内 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Hideo Kobayashi, 1 Kawasaki-cho, Chuo-ku, Chiba, Chiba Prefecture, Technical Research Division, Kawasaki Steel Co., Ltd. (72) Takashi Obara, 1 Kawasaki-cho, Chuo-ku, Chiba, Chiba Prefecture Kawasaki Steel Co., Ltd. Technical Research Division (72) Inventor Tomoyuki Ichi 1-chome, Mizushima Kawasaki-dori, Mizushima Steel Works, Kurashiki City, Okayama Prefecture Kawasaki Steel Co., Ltd. Mizushima Steel Works

Claims (2)

【特許請求の範囲】[Claims] 【請求項1】 圧延ロールによって表面凹凸を調整した
電磁鋼板であって、鋼板表面の3次元表面粗さが、中心
面平均粗さSRa で 0.5μm 以下、最大高さSR max が 0.1
〜2.0 μm でかつ、各凹部につき、負荷曲線で深さ方向
落差が最も大きい点(切断断面積率が0%又は 100%の
点を除く負荷曲線の微分係数が最小である点)を中心と
して切断面面積率がそれぞれ±10%異なる2点間におけ
る高さ方向の差がSRmax の50%以上、を満足することを
特徴とする端面溶接性に優れる積層鉄心用電磁鋼板。
1. Surface irregularities are adjusted by a rolling roll.
A magnetic steel sheet, where the three-dimensional surface roughness of the steel sheet surface is the center
Surface average roughness SRa is 0.5 μm or less, maximum height SR maxIs 0.1
~ 2.0 μm and load curve for each recess in the depth direction
The point where the head is the largest (when the cross-sectional area ratio is 0% or 100%
The point where the derivative of the load curve excluding the points is the minimum)
And place it between two points where the cut surface area ratio is ± 10% different.
SR in the height directionmaxMore than 50%, to be satisfied
A magnetic steel sheet for laminated cores with excellent end face weldability.
【請求項2】 請求項1において、鋼板表面に、付着量
が 0.2〜2.5 g/m2の絶縁被膜をそなえてなる端面溶接性
に優れる積層鉄心用電磁鋼板。
2. The electromagnetic steel sheet for laminated core according to claim 1, wherein the steel sheet surface is provided with an insulating coating having an adhesion amount of 0.2 to 2.5 g / m 2 and is excellent in end face weldability.
JP06204093A 1993-03-22 1993-03-22 Electromagnetic steel sheet for laminated iron core with excellent edge weldability Expired - Fee Related JP3419016B2 (en)

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JP06204093A JP3419016B2 (en) 1993-03-22 1993-03-22 Electromagnetic steel sheet for laminated iron core with excellent edge weldability

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Application Number Priority Date Filing Date Title
JP06204093A JP3419016B2 (en) 1993-03-22 1993-03-22 Electromagnetic steel sheet for laminated iron core with excellent edge weldability

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JPH06271997A true JPH06271997A (en) 1994-09-27
JP3419016B2 JP3419016B2 (en) 2003-06-23

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2003077747A (en) * 2001-08-30 2003-03-14 Chugoku Electric Manufacture Co Ltd Method of manufacturing noise suppressing laminated core and noise suppressing structure electromagnetic steel plate

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2003077747A (en) * 2001-08-30 2003-03-14 Chugoku Electric Manufacture Co Ltd Method of manufacturing noise suppressing laminated core and noise suppressing structure electromagnetic steel plate

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JP3419016B2 (en) 2003-06-23

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