JP5275504B1 - METAL MATERIAL FOR ELECTRONIC COMPONENT AND ITS MANUFACTURING METHOD, CONNECTOR TERMINAL USING THE SAME, CONNECTOR AND ELECTRONIC COMPONENT - Google Patents
METAL MATERIAL FOR ELECTRONIC COMPONENT AND ITS MANUFACTURING METHOD, CONNECTOR TERMINAL USING THE SAME, CONNECTOR AND ELECTRONIC COMPONENT Download PDFInfo
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- Manufacturing Of Electrical Connectors (AREA)
- Non-Insulated Conductors (AREA)
- Electroplating Methods And Accessories (AREA)
- Other Surface Treatments For Metallic Materials (AREA)
Abstract
【課題】低ウィスカ性、低凝着磨耗性及び高耐久性を有する電子部品用金属材料、それを用いたコネクタ端子、コネクタ及び電子部品を提供する。
【解決手段】電子部品用金属材料は、基材と、基材上に形成された、Ni,Cr,Mn,Fe,Co及びCuからなる群であるA構成元素群から選択された1種又は2種以上で構成された下層と、下層上に形成された、A構成元素群から選択された1種又は2種以上と、Sn及びInからなる群であるB構成元素群から選択された1種又は2種とで構成された中層と、中層上に形成された、B構成元素群から選択された1種又は2種と、Ag,Au,Pt,Pd,Ru,Rh,Os及びIrからなる群であるC構成元素群から選択された1種又は2種類以上との合金で構成された上層とを備え、下層の厚みが0.05μm以上5.00μm未満であり、中層の厚みが0.01μm以上0.40μm未満であり、上層の厚みが0.02μm以上1.00μm未満である。
【選択図】図1The present invention provides a metal material for electronic parts having low whisker property, low adhesion wear and high durability, and a connector terminal, connector and electronic part using the same.
A metal material for electronic parts is selected from a base material and an A constituent element group formed on the base material, the group consisting of Ni, Cr, Mn, Fe, Co, and Cu, or A lower layer composed of two or more types, one or two or more types selected from the A constituent element group formed on the lower layer, and a B constituent element group that is a group consisting of Sn and In An intermediate layer composed of seeds or two species, one or two species selected from the group B constituent elements formed on the intermediate layer, and Ag, Au, Pt, Pd, Ru, Rh, Os and Ir And an upper layer composed of an alloy of one or more selected from the group consisting of C constituent elements, the thickness of the lower layer is 0.05 μm or more and less than 5.00 μm, and the thickness of the middle layer is 0 .01 μm or more and less than 0.40 μm, and the upper layer thickness is 0.02 μm or more and 1. It is less than 00 μm.
[Selection] Figure 1
Description
本発明は、電子部品用金属材料及びその製造方法、それを用いたコネクタ端子、コネクタ及び電子部品に関する。 The present invention relates to a metal material for an electronic component and a method for manufacturing the same, a connector terminal using the same, a connector, and an electronic component.
民生用及び車載用電子機器用接続部品であるコネクタには、黄銅やリン青銅の表面にNiやCuの下地めっきを施し、さらにその上にSn又はSn合金めっきを施した材料が使用されている。Sn又はSn合金めっきは、一般的に低接触抵抗及び高はんだ濡れ性という特性が求められ、更に近年めっき材をプレス加工で成形したオス端子及びメス端子勘合時の挿入力の低減化も求められている。また、製造工程でめっき表面に、短絡等の問題を引き起こす針状結晶であるウィスカが発生することがあり、このウィスカを良好に抑制する必要もある。 A connector that is a connection part for consumer and in-vehicle electronic devices uses a material in which a surface of brass or phosphor bronze is plated with Ni or Cu and further plated with Sn or Sn alloy. . Sn or Sn alloy plating generally requires characteristics such as low contact resistance and high solder wettability, and in recent years, it is also required to reduce insertion force when mating a male terminal and a female terminal formed by plating a plated material. ing. In addition, whiskers that are needle-like crystals that cause problems such as short circuits may occur on the plating surface in the manufacturing process, and it is necessary to suppress these whiskers well.
これに対し、特許文献1には、接点基材と、前記接点基材の表面に形成されたNiもしくはCoまたは両者の合金から成る下地層と、前記下地層の表面に形成されたAg−Sn合金層とを備え、前記Ag−Sn合金層におけるSnの平均濃度は10質量%未満であり、かつ前記Ag−Sn合金層におけるSnの濃度は前記下地層との界面から前記Ag−Sn合金層の表層部にかけて増大する濃度勾配で変化していることを特徴とする電気接点材料が開示されている。そしてこれによれば、耐摩耗性、耐食性、加工性が優れている電気接点材料とそれを極めて安価に製造することができると記載されている。 On the other hand, Patent Document 1 discloses a contact base material, a base layer made of Ni or Co or an alloy of both formed on the surface of the contact base material, and Ag-Sn formed on the surface of the base layer. And an average concentration of Sn in the Ag—Sn alloy layer is less than 10% by mass, and the Sn concentration in the Ag—Sn alloy layer is from the interface with the underlayer to the Ag—Sn alloy layer. An electrical contact material is disclosed that varies with a concentration gradient that increases over the surface layer of the substrate. According to this, it is described that an electrical contact material having excellent wear resistance, corrosion resistance, and workability can be produced at a very low cost.
また、特許文献2には、少なくとも表面がCuまたはCu合金から成る基体の前記表面に、NiまたはNi合金層から成る中間層を介して、いずれもAg3Sn(ε相)化合物を含有する厚み0.5〜20μmのSn層またはSn合金層から成る表面層が形成されていることを特徴とする電気・電子部品用材料が開示されている。そしてこれによれば、表面層はSnより低融点であり、はんだ付け性に優れ、またウイスカーの発生もなく、はんだ付け後に形成された接合部の接合強度が高いと同時に、その接合強度の高温下における経時的な低下も起こりづらいのでリード材料として好適であり、また高温環境下で使用したときでも接触抵抗の上昇が抑制され、相手材との間で接続信頼性の低下を招くこともないのでコンタクト材料としても好適な電気・電子部品用材料とその製造方法、およびその材料を用いた電気・電子部品の提供を目的とすることが記載されている。 In Patent Document 2, at least the surface of the substrate made of Cu or a Cu alloy has a thickness containing an Ag 3 Sn (ε phase) compound via an intermediate layer made of Ni or a Ni alloy layer on the surface of the substrate. A material for electric / electronic parts is disclosed, in which a surface layer composed of a Sn layer or a Sn alloy layer of 0.5 to 20 μm is formed. And according to this, the surface layer has a lower melting point than Sn, excellent solderability, no whisker, high joint strength of the joint formed after soldering, and high joint strength. This is suitable as a lead material because it does not easily degrade over time, and even when used in a high temperature environment, the increase in contact resistance is suppressed, and the connection reliability with the counterpart material is not reduced. Therefore, it is described that the object is to provide a material for an electric / electronic component suitable as a contact material, a method for manufacturing the same, and an electric / electronic component using the material.
また特許文献3には、導電性を有する基材と、前記基材に形成された被覆層とを備えた被覆材において、 前記被覆層は少なくとも表面側に、Snと、貴金属との金属間化合物を含むことを特徴とする被覆材が開示されている。そしてこれによれば、接触抵抗が低く、低摩擦係数を有して挿入力の低減に有効であって、かつ、耐酸化性に優れて長期に亘って安定した特性を有する被覆材、及びその製造方法の提供を目的とすることが記載されている。 Patent Document 3 discloses a covering material comprising a conductive base material and a coating layer formed on the base material, wherein the coating layer is an intermetallic compound of Sn and a noble metal at least on the surface side. The coating | covering material characterized by including is disclosed. According to this, a coating material having a low contact resistance, a low friction coefficient, effective in reducing the insertion force, excellent in oxidation resistance and stable over a long period of time, and its It describes that it aims to provide a manufacturing method.
しかしながら、特許文献1に記載の技術では、近年求められている挿入力の低減化やウィスカ発生の有無との関係が明らかになっていない。またAg−Sn合金層におけるSnの平均濃度は10質量%未満であり、Ag−Sn合金層中のAgの割合がかなり多いため本発明者らの評価では、塩素ガス、亜硫酸ガス、硫化水素等のガスに対する耐ガス腐食性が十分ではなかった。
また、特許文献2に記載の技術では、Ag3Sn(ε相)化合物を含有する厚み0.5〜20μmのSn層またはSn合金層から成る表面層であり、本発明者らの評価では、この表面層厚みでは十分に挿入力を下げることはできない領域が存在した。更にSn層またはSn合金層から成る表面層のAg3Sn(ε相)の含有量が、Ag換算にして0.5〜5質量%であるとも記載されており、Sn層またはSn合金層から成る表面層におけるSnの割合が多く、Sn層またはSn合金層から成る表面層の厚みも厚いために本発明者らの評価ではウィスカが発生し、耐微摺動磨耗性が十分ではなかった。耐熱性やはんだ濡れ性も十分ではなかった。
また、特許文献3に記載の技術では、被覆層がSnと、貴金属との金属間化合物を含んでいるが、Snと貴金属との金属間化合物(Ag3Sn)の厚みが好ましくは1μm以上3μm以下となっている本発明者らの評価では、この厚みでは、十分に挿入力を下げることができなかった。
このように、従来のSn−Ag合金/Ni下地めっき構造を有する電子部品用金属材料にはまだ十分に挿入力を下げることができず、またウィスカが発生するという問題が残されていた。また耐久性(耐熱性、はんだ濡れ性、耐微摺動磨耗性及び耐ガス腐食性)についても十分満足できる仕様とすることは困難であり、明らかになっていない。
本発明は上記の課題を解決するためになされたものであり、低ウィスカ性、低凝着磨耗性及び高耐久性を有する電子部品用金属材料、それを用いたコネクタ端子、コネクタ及び電子部品を提供することを課題とする。なお、凝着磨耗とは固体間の真実接触面積を構成する凝着部分が、摩擦運動によりせん断されることに基因して生ずる摩耗現象のことをいう。この凝着磨耗が大きくなると、オス端子とメス端子を勘合した時の挿入力が高くなる。
However, in the technique described in Patent Document 1, the relationship between the reduction in insertion force and the presence or absence of whisker generation, which have been required in recent years, has not been clarified. Moreover, since the average concentration of Sn in the Ag—Sn alloy layer is less than 10% by mass and the proportion of Ag in the Ag—Sn alloy layer is considerably large, the evaluation by the present inventors shows that chlorine gas, sulfurous acid gas, hydrogen sulfide, etc. The gas corrosion resistance to the gas was not sufficient.
Moreover, in the technique described in Patent Document 2, it is a surface layer composed of a Sn layer or Sn alloy layer having a thickness of 0.5 to 20 μm containing an Ag 3 Sn (ε phase) compound. There was a region where the insertion force could not be lowered sufficiently with this surface layer thickness. Furthermore, it is described that the content of Ag 3 Sn (ε phase) in the surface layer composed of the Sn layer or the Sn alloy layer is 0.5 to 5% by mass in terms of Ag, and from the Sn layer or the Sn alloy layer. In the evaluation by the present inventors, whisker was generated because the ratio of Sn in the surface layer formed was large and the thickness of the surface layer made of Sn layer or Sn alloy layer was also thick, and the resistance to fine sliding wear was not sufficient. Heat resistance and solder wettability were not sufficient.
In the technique described in Patent Document 3, the coating layer contains an intermetallic compound of Sn and a noble metal. The thickness of the intermetallic compound of Sn and the noble metal (Ag 3 Sn) is preferably 1 μm or more and 3 μm. According to the following evaluations by the present inventors, the insertion force could not be lowered sufficiently with this thickness.
As described above, the metal material for electronic parts having the conventional Sn—Ag alloy / Ni base plating structure still has a problem that the insertion force cannot be sufficiently lowered and whiskers are generated. In addition, it is difficult to make the specification sufficiently satisfactory in terms of durability (heat resistance, solder wettability, fine sliding wear resistance, and gas corrosion resistance), and it has not been clarified.
The present invention has been made in order to solve the above-mentioned problems. A metal material for electronic parts having low whisker properties, low adhesion wear and high durability, and a connector terminal, a connector and an electronic component using the same. The issue is to provide. Adhesive wear refers to a wear phenomenon that occurs due to the fact that an adhesive portion constituting a real contact area between solids is sheared by frictional motion. When this adhesion wear increases, the insertion force when the male terminal and the female terminal are fitted together increases.
本発明者らは、鋭意検討の結果、基材上に下層と中層と上層とを順に設け、下層と中層と上層とに所定の金属を用い、且つ、所定の厚み及び組成とすることで、低ウィスカ性、低凝着磨耗性及び高耐久性を有する電子部品用金属材料を作製することができることを見出した。 As a result of intensive studies, the inventors provided a lower layer, an intermediate layer, and an upper layer in order on the base material, using a predetermined metal for the lower layer, the intermediate layer, and the upper layer, and having a predetermined thickness and composition, It has been found that a metal material for electronic parts having low whisker properties, low adhesion wear properties and high durability can be produced.
以上の知見を基礎として完成した本発明は一側面において、基材と、前記基材上に形成された、Ni、Cr、Mn、Fe、Co及びCuからなる群であるA構成元素群から選択された1種又は2種以上で構成された下層と、前記下層上に形成された、前記A構成元素群から選択された1種又は2種以上と、Sn及びInからなる群であるB構成元素群から選択された1種又は2種とで構成された中層と、前記中層上に形成された、前記B構成元素群から選択された1種又は2種と、Ag、Au、Pt、Pd、Ru、Rh、Os及びIrからなる群であるC構成元素群から選択された1種又は2種類以上との合金で構成された上層とを備え、前記下層の厚みが0.05μm以上5.00μm未満であり、前記中層の厚みが0.01μm以上0.40μm未満であり、前記上層の厚みが0.02μm以上1.00μm未満であり、低ウィスカ性、低凝着磨耗性及び高耐久性を有する電子部品用金属材料である。 In one aspect, the present invention completed based on the above knowledge is selected from a base material and an A constituent element group which is a group consisting of Ni, Cr, Mn, Fe, Co and Cu formed on the base material. B layer which is a group consisting of Sn and In, and a lower layer composed of one or two or more selected, one or more selected from the A constituent element group formed on the lower layer, and An intermediate layer composed of one or two elements selected from the element group, one or two elements selected from the B constituent element group formed on the intermediate layer, and Ag, Au, Pt, Pd And an upper layer made of an alloy of one or more selected from the C constituent element group, which is a group consisting of Ru, Rh, Os, and Ir, and the lower layer has a thickness of 0.05 μm or more. Less than 00 μm, and the thickness of the intermediate layer is 0.01 μm or more and 0.4 Less than [mu] m, the upper layer of a thickness of less than 0.02 [mu] m 1.00 .mu.m, low whisker resistance, a metal material for electronic parts having a low adhesive wear resistance and high durability.
本発明の電子部品用金属材料は一実施形態において、前記上層の最小厚み(μm)が前記上層の厚み(μm)の50%以上である。 In one embodiment of the metal material for electronic parts of the present invention, the minimum thickness (μm) of the upper layer is 50% or more of the thickness (μm) of the upper layer.
本発明の電子部品用金属材料は別の一実施形態において、前記上層と前記中層との界面プロフィールの隣り合う山と谷との高低差の最大値(μm)が、前記上層の厚み(μm)の50%以下である。 In another embodiment of the metal material for electronic parts according to the present invention, the maximum value (μm) of the height difference (μm) between adjacent peaks and valleys in the interface profile between the upper layer and the middle layer is the thickness (μm) of the upper layer. Of 50% or less.
本発明の電子部品用金属材料は更に別の一実施形態において、前記上層の表面に、B構成元素の合計原子濃度(at%)≧C構成元素の合計原子濃度(at%)であり、Oの原子濃度(at%)≧10at%である領域が0.02μm以下で存在する。 In still another embodiment of the metal material for electronic components of the present invention, the surface of the upper layer has a total atomic concentration of B constituent elements (at%) ≧ a total atomic concentration of C constituent elements (at%), and O The region where the atomic concentration (at%) of ≧ 10 at% exists is 0.02 μm or less.
本発明の電子部品用金属材料は更に別の一実施形態において、前記上層が、前記B構成元素群の金属を10〜50at%含有する。 In still another embodiment of the metal material for electronic parts according to the present invention, the upper layer contains 10 to 50 at% of the metal of the B constituent element group.
本発明の電子部品用金属材料は更に別の一実施形態において、前記上層に、Snを11.8〜22.9at%含むSnAg合金であるζ(ゼータ)相が存在する。 In still another embodiment of the metal material for electronic parts of the present invention, a ζ (zeta) phase that is a SnAg alloy containing 11.8 to 22.9 at% of Sn exists in the upper layer.
本発明の電子部品用金属材料は更に別の一実施形態において、前記上層に、Ag3Snであるε(イプシロン)相が存在する。 In still another embodiment of the metal material for electronic parts of the present invention, an ε (epsilon) phase that is Ag 3 Sn exists in the upper layer.
本発明の電子部品用金属材料は更に別の一実施形態において、前記上層に、Snを11.8〜22.9at%含むSnAg合金であるζ(ゼータ)相と、Ag3Snであるε(イプシロン)相とが存在する。 In still another embodiment of the metal material for electronic parts of the present invention, a ζ (zeta) phase that is a SnAg alloy containing 11.8 to 22.9 at% of Sn and ε (Ag 3 Sn) in the upper layer. Epsilon) phase.
本発明の電子部品用金属材料は更に別の一実施形態において、前記上層に、Ag3Snであるε(イプシロン)相のみが存在する。 In still another embodiment of the metal material for electronic parts of the present invention, only the ε (epsilon) phase that is Ag 3 Sn exists in the upper layer.
本発明の電子部品用金属材料は更に別の一実施形態において、前記上層に、Ag3Snであるε(イプシロン)相と、Sn単相であるβSnとが存在する。 In still another embodiment of the metal material for electronic parts of the present invention, an ε (epsilon) phase that is Ag 3 Sn and βSn that is a Sn single phase are present in the upper layer.
本発明の電子部品用金属材料は更に別の一実施形態において、前記上層に、Snを11.8〜22.9at%含むSnAg合金であるζ(ゼータ)相と、Ag3Snであるε(イプシロン)相と、Sn単相であるβSnとが存在する。 In still another embodiment of the metal material for electronic parts of the present invention, a ζ (zeta) phase that is a SnAg alloy containing 11.8 to 22.9 at% of Sn and ε (Ag 3 Sn) in the upper layer. (Epsilon) phase and βSn which is a single Sn phase.
本発明の電子部品用金属材料は更に別の一実施形態において、前記中層が、前記B構成元素群の金属を35at%以上含有する。 In still another embodiment of the metal material for electronic parts of the present invention, the intermediate layer contains 35 at% or more of the metal of the B constituent element group.
本発明の電子部品用金属材料は更に別の一実施形態において、前記中層に、Ni3Sn4と、Ni3Sn2とが存在する。 In still another embodiment of the metal material for electronic parts of the present invention, Ni 3 Sn 4 and Ni 3 Sn 2 are present in the intermediate layer.
本発明の電子部品用金属材料は更に別の一実施形態において、前記中層に、Ni3Sn4と、Sn単相であるβSnとが存在する。 In still another embodiment of the metal material for electronic components of the present invention, Ni 3 Sn 4 and βSn that is a Sn single phase are present in the intermediate layer.
本発明の電子部品用金属材料は更に別の一実施形態において、前記上層と前記中層との厚みの比が、上層:中層=9:1〜3:7である。 In still another embodiment of the metal material for electronic parts of the present invention, the thickness ratio of the upper layer to the middle layer is upper layer: middle layer = 9: 1 to 3: 7.
本発明の電子部品用金属材料は更に別の一実施形態において、前記上層から、前記上層の最表面から0.03μmの範囲を除く前記中層までにおいて、C、S、Oを、それぞれ2at%以下含有する。 In still another embodiment of the metal material for electronic components of the present invention, C, S, and O are each 2 at% or less from the upper layer to the middle layer excluding the range of 0.03 μm from the outermost surface of the upper layer. contains.
本発明の電子部品用金属材料は更に別の一実施形態において、超微小硬さ試験により、前記上層の表面に荷重10mNで打痕を打って測定して得られた硬度である、前記上層の表面の押し込み硬さが1000MPa以上である。 In still another embodiment, the metal material for electronic parts according to the present invention has a hardness obtained by measuring a dent on a surface of the upper layer with a load of 10 mN by an ultra micro hardness test. The indentation hardness of the surface is 1000 MPa or more.
本発明の電子部品用金属材料は更に別の一実施形態において、超微小硬さ試験により、前記上層の表面に荷重10mNで打痕を打って測定して得られた硬度である、前記上層の表面の押し込み硬さが10000MPa以下である。 In still another embodiment, the metal material for electronic parts according to the present invention has a hardness obtained by measuring a dent on a surface of the upper layer with a load of 10 mN by an ultra micro hardness test. The indentation hardness of the surface is 10000 MPa or less.
本発明の電子部品用金属材料は更に別の一実施形態において、前記上層の表面の算術平均高さ(Ra)が0.3μm以下である。 In still another embodiment of the metal material for electronic parts according to the present invention, the arithmetic average height (Ra) of the surface of the upper layer is 0.3 μm or less.
本発明の電子部品用金属材料は更に別の一実施形態において、前記上層の表面の最大高さ(Rz)が3μm以下である。 In still another embodiment of the metal material for electronic parts according to the present invention, the maximum height (Rz) of the surface of the upper layer is 3 μm or less.
本発明の電子部品用金属材料は更に別の一実施形態において、前記上層、前記中層及び前記下層が、前記基材上に前記A構成元素群から選択された1種又は2種以上を成膜し、その後、前記C構成元素群から選択された1種又は2種を成膜し、その後、前記B構成元素群から選択された1種又は2種類以上を成膜し、前記A構成元素群、前記B構成元素群及び前記C構成元素群の各元素が拡散することでそれぞれ形成されている。 In still another embodiment of the metal material for electronic parts according to the present invention, the upper layer, the middle layer, and the lower layer are formed of one or more selected from the group A constituent elements on the substrate. Then, one or two types selected from the C constituent element group are formed, and then one or two or more types selected from the B constituent element group are formed, and the A constituent element group Each element of the B constituent element group and the C constituent element group is formed by diffusing.
本発明の電子部品用金属材料は更に別の一実施形態において、前記拡散が熱処理によって行われている。 In still another embodiment of the metal material for electronic parts of the present invention, the diffusion is performed by heat treatment.
本発明の電子部品用金属材料は更に別の一実施形態において、前記熱処理が、前記B構成元素群の金属の融点以上で行われ、前記B構成元素群から選択された1種又は2種及び前記A構成元素群から選択された1種又は2種以上の合金層、及び、前記B構成元素群から選択された1種又は2種及び前記C構成元素群から選択された1種又は2種類以上の合金層が形成されている。 In still another embodiment of the metal material for electronic parts of the present invention, the heat treatment is performed at a temperature equal to or higher than the melting point of the metal of the B constituent element group, and one or two selected from the B constituent element group and One or more alloy layers selected from the A constituent element group, one or two selected from the B constituent element group, and one or two kinds selected from the C constituent element group The above alloy layer is formed.
本発明の電子部品用金属材料は更に別の一実施形態において、前記A構成元素群の金属がNi、Cr、Mn、Fe、Co、Cuの合計で50mass%以上であり、さらにB、P、Sn及びZnからなる群から選択された1種又は2種以上を含む。 In still another embodiment of the metal material for electronic parts according to the present invention, the metal of the A constituent element group is 50 mass% or more in total of Ni, Cr, Mn, Fe, Co, Cu, and further, B, P, 1 type or 2 types or more selected from the group which consists of Sn and Zn are included.
本発明の電子部品用金属材料は更に別の一実施形態において、前記B構成元素群の金属がSnとInとの合計で50mass%以上であり、残合金成分がAg、As、Au、Bi、Cd、Co、Cr、Cu、Fe、Mn、Mo、Ni、Pb、Sb、W及びZnからなる群から選択された1種又は2種以上の金属からなる。 In still another embodiment of the metal material for electronic parts of the present invention, the total of metals of the B constituent element group is 50 mass% or more, and the remaining alloy components are Ag, As, Au, Bi, It consists of 1 type, or 2 or more types of metals selected from the group which consists of Cd, Co, Cr, Cu, Fe, Mn, Mo, Ni, Pb, Sb, W and Zn.
本発明の電子部品用金属材料は更に別の一実施形態において、前記C構成元素群の金属がAgとAuとPtとPdとRuとRhとOsとIrとの合計で50mass%以上であり、残合金成分がBi、Cd、Co、Cu、Fe、In、Mn、Mo、Ni、Pb、Sb、Se、Sn、W、Tl及びZnからなる群から選択された1種又は2種以上の金属からなる。 In another embodiment of the metal material for electronic parts of the present invention, the metal of the C constituent element group is 50 mass% or more in total of Ag, Au, Pt, Pd, Ru, Rh, Os, and Ir, One or more metals selected from the group consisting of Bi, Cd, Co, Cu, Fe, In, Mn, Mo, Ni, Pb, Sb, Se, Sn, W, Tl and Zn. Consists of.
本発明の電子部品用金属材料は更に別の一実施形態において、前記下層の断面のビッカース硬さがHv300以上である。 In still another embodiment of the metal material for electronic parts according to the present invention, the lower layer has a Vickers hardness of Hv300 or more in the cross section.
本発明の電子部品用金属材料は更に別の一実施形態において、超微小硬さ試験により、前記下層の断面に荷重10mNで打痕を打って測定して得られた硬度である、前記下層の断面の押し込み硬さが1500MPa以上である。 In yet another embodiment, the metal material for electronic parts according to the present invention has a hardness obtained by measuring a dent on a cross section of the lower layer with a load of 10 mN by an ultra micro hardness test. The indentation hardness of the cross section is 1500 MPa or more.
本発明の電子部品用金属材料は更に別の一実施形態において、前記下層の断面のビッカース硬さがHv1000以下である。 In still another embodiment of the metal material for electronic parts according to the present invention, the Vickers hardness of the cross section of the lower layer is Hv 1000 or less.
本発明の電子部品用金属材料は更に別の一実施形態において、超微小硬さ試験により、前記下層の断面に荷重10mNで打痕を打って測定して得られた硬度である、前記下層の断面の押し込み硬さが10000MPa以下である。 In yet another embodiment, the metal material for electronic parts according to the present invention has a hardness obtained by measuring a dent on a cross section of the lower layer with a load of 10 mN by an ultra micro hardness test. The indentation hardness of the cross section is 10000 MPa or less.
本発明の電子部品用金属材料は更に別の一実施形態において、前記中層が、Ni3SnとNi3Sn2とで構成されている。 In still another embodiment of the metal material for electronic parts according to the present invention, the intermediate layer is composed of Ni 3 Sn and Ni 3 Sn 2 .
本発明の電子部品用金属材料は更に別の一実施形態において、前記中層が、Ni3Sn2で構成されている。 In still another embodiment of the metal material for electronic parts according to the present invention, the intermediate layer is made of Ni 3 Sn 2 .
本発明の電子部品用金属材料は更に別の一実施形態において、前記中層が、Ni3Sn4で構成されている。 In still another embodiment of the metal material for electronic parts according to the present invention, the intermediate layer is made of Ni 3 Sn 4 .
本発明の電子部品用金属材料は更に別の一実施形態において、前記下層と中層との間に、さらにA構成元素群の金属とC構成元素群の金属との合金で構成された層を備える。 In still another embodiment, the metal material for electronic parts according to the present invention further includes a layer composed of an alloy of a metal of the A constituent element group and a metal of the C constituent element group between the lower layer and the middle layer. .
本発明の電子部品用金属材料は更に別の一実施形態において、前記上層の表面にPが付着しており、前記Pの付着量が1×10-11〜4×10-8mol/cm2である。 In still another embodiment of the metal material for electronic parts according to the present invention, P adheres to the surface of the upper layer, and the adhesion amount of P is 1 × 10 −11 to 4 × 10 −8 mol / cm 2. It is.
本発明の電子部品用金属材料は更に別の一実施形態において、前記上層の表面にさらにNが付着しており、前記Nの付着量が2×10-12〜8×10-9mol/cm2である。 In still another embodiment of the metal material for electronic parts according to the present invention, N is further adhered to the surface of the upper layer, and the amount of N deposited is 2 × 10 −12 to 8 × 10 −9 mol / cm. 2 .
本発明の電子部品用金属材料は更に別の一実施形態において、前記上層をXPSで分析した際に、検出されるPの2S軌道電子起因の光電子検出強度をI(P2s)、Nの1S軌道電子起因の光電子検出強度をI(N1s)としたとき、0.1≦I(P2s)/I(N1s)≦1を満たす。 In still another embodiment of the metal material for electronic parts of the present invention, when the upper layer is analyzed by XPS, the photoelectron detection intensity caused by the 2S orbital electrons of P detected is I (P2s), and the 1S orbital of N When the photoelectron detection intensity due to electrons is I (N1s), 0.1 ≦ I (P2s) / I (N1s) ≦ 1 is satisfied.
本発明の電子部品用金属材料は更に別の一実施形態において、前記上層をXPSで分析した際に、検出されるPの2S軌道電子起因の光電子検出強度をI(P2s)、Nの1S軌道電子起因の光電子検出強度をI(N1s)としたとき、1<I(P2s)/I(N1s)≦50を満たす。 In still another embodiment of the metal material for electronic parts of the present invention, when the upper layer is analyzed by XPS, the photoelectron detection intensity caused by the 2S orbital electrons of P detected is I (P2s), and the 1S orbital of N When the photoelectron detection intensity due to electrons is I (N1s), 1 <I (P2s) / I (N1s) ≦ 50 is satisfied.
本発明は別の一側面において、基材と、前記基材上に形成された、Ni、Cr、Mn、Fe、Co及びCuからなる群であるA構成元素群から選択された1種又は2種以上で構成された下層と、前記下層上に形成された、前記A構成元素群から選択された1種又は2種以上と、Sn及びInからなる群であるB構成元素群から選択された1種又は2種とで構成された中層と、前記中層上に形成された、前記B構成元素群から選択された1種又は2種と、Ag、Au、Pt、Pd、Ru、Rh、Os及びIrからなる群であるC構成元素群から選択された1種又は2種類以上との合金で構成された上層とを備えた金属材料の表面に、下記一般式〔1〕および〔2〕で表されるリン酸エステルの少なくとも1種と、下記一般式〔3〕および〔4〕で表される環状有機化合物群から選択される少なくとも1種とを含有するリン酸エステル系液で表面処理する本発明の電子部品用金属材料の製造方法である。
本発明の電子部品用金属材料の製造方法は一実施形態において、前記リン酸エステル系液による表面処理を、前記上層の表面にリン酸エステル系液を塗布することで行う。 In one embodiment of the method for producing a metal material for electronic parts according to the present invention, the surface treatment with the phosphate ester solution is performed by applying a phosphate ester solution to the surface of the upper layer.
本発明の電子部品用金属材料の製造方法は別の一実施形態において、前記リン酸エステル系液による表面処理を、前記上層形成後の金属材料をリン酸エステル系液中に浸漬させ、前記上層形成後の金属材料を陽極にして電解することで行う。 In another embodiment of the method for producing a metal material for an electronic component according to the present invention, the surface treatment with the phosphate ester solution is performed by immersing the metal material after the formation of the upper layer in the phosphate ester solution, and This is performed by electrolysis using the formed metal material as an anode.
本発明は更に別の一側面において、本発明の電子部品用金属材料を接点部分に用いたコネクタ端子である。 In still another aspect of the present invention, there is provided a connector terminal using the metal material for electronic parts of the present invention as a contact portion.
本発明は更に別の一側面において、本発明のコネクタ端子を用いたコネクタである。 In still another aspect, the present invention is a connector using the connector terminal of the present invention.
本発明は更に別の一側面において、本発明の電子部品用金属材料を接点部分に用いたFFC端子である。 In still another aspect, the present invention is an FFC terminal using the metal material for electronic parts of the present invention as a contact portion.
本発明は更に別の一側面において、本発明の電子部品用金属材料を接点部分に用いたFPC端子である。 In still another aspect, the present invention is an FPC terminal using the metal material for electronic parts of the present invention as a contact portion.
本発明は更に別の一側面において、本発明のFFC端子を用いたFFCである。 In still another aspect, the present invention is an FFC using the FFC terminal of the present invention.
本発明は更に別の一側面において、本発明のFPC端子を用いたFPCである。 In still another aspect, the present invention is an FPC using the FPC terminal of the present invention.
本発明は更に別の一側面において、本発明の電子部品用金属材料を外部接続用電極に用いた電子部品である。 In still another aspect of the present invention, an electronic component using the metal material for an electronic component of the present invention as an external connection electrode.
本発明は更に別の一側面において、本発明の電子部品用金属材料を、ハウジングに取り付ける装着部の一方側にメス端子接続部が、他方側に基板接続部がそれぞれ設けられ、前記基板接続部を基板に形成されたスルーホールに圧入して前記基板に取り付ける圧入型端子に用いた電子部品である。 In yet another aspect of the present invention, the metal material for electronic components of the present invention is provided with a female terminal connection portion on one side of a mounting portion for mounting on the housing and a substrate connection portion on the other side, and the substrate connection portion. Is an electronic component used for a press-fit terminal that is press-fitted into a through-hole formed in the substrate and attached to the substrate.
本発明によれば、低ウィスカ性、低凝着磨耗性及び高耐久性を有する電子部品用金属材料、それを用いたコネクタ端子、コネクタ及び電子部品を提供することができる。 ADVANTAGE OF THE INVENTION According to this invention, the metal material for electronic components which has low whisker property, low adhesive wear property, and high durability, a connector terminal using the same, a connector, and an electronic component can be provided.
以下、本発明の実施形態に係る電子部品用金属材料について説明する。図1に示すように、実施形態に係る電子部品用金属材料10は、基材11上に下層12が形成され、下層12上に中層13が形成され、中層13上に上層14が形成されている。 Hereinafter, the metal material for electronic components according to the embodiment of the present invention will be described. As shown in FIG. 1, the electronic component metal material 10 according to the embodiment has a lower layer 12 formed on a substrate 11, an intermediate layer 13 formed on the lower layer 12, and an upper layer 14 formed on the intermediate layer 13. Yes.
<電子部品用金属材料の構成>
(基材)
基材11としては、特に限定されないが、例えば、銅及び銅合金、Fe系材、ステンレス、チタン及びチタン合金、アルミニウム及びアルミニウム合金などの金属基材を用いることができる。また、金属基材に樹脂層を複合させたものであっても良い。金属基材に樹脂層を複合させたものとは、例としてFPCまたはFFC基材上の電極部分などがある。
<Configuration of metal materials for electronic parts>
(Base material)
Although it does not specifically limit as the base material 11, For example, metal base materials, such as copper and a copper alloy, Fe-type material, stainless steel, titanium and a titanium alloy, aluminum, and an aluminum alloy, can be used. Alternatively, a metal base and a resin layer may be combined. Examples of composites of metal layers and resin layers include electrode portions on FPC or FFC substrates.
(上層)
上層14は、Sn及びInからなる群であるB構成元素群から選択された1種又は2種と、Ag、Au、Pt、Pd、Ru、Rh、Os及びIrからなる群であるC構成元素群から選択された1種又は2種類以上との合金で構成されている必要がある。
Sn及びInは、酸化性を有する金属ではあるが、金属の中では比較的柔らかいという特徴がある。よって、Sn及びIn表面に酸化膜が形成されていても、例えば電子部品用金属材料を接点材料としてオス端子とメス端子を勘合する時に、容易に酸化膜が削られ、接点が金属同士となるため、低接触抵抗が得られる。
また、Sn及びInは塩素ガス、亜硫酸ガス、硫化水素ガス等のガスに対する耐ガス腐食性に優れ、例えば、上層14に耐ガス腐食性に劣るAg、下層12に耐ガス腐食性に劣るNi、基材11に耐ガス腐食性に劣る銅及び銅合金を用いた場合には、電子部品用金属材料の耐ガス腐食性を向上させる働きがある。なおSn及びInでは、厚生労働省の健康障害防止に関する技術指針に基づき、Inは規制が厳しいため、Snが好ましい。
Ag、Au、Pt、Pd、Ru、Rh、Os、Irは、金属の中では比較的耐熱性を有するという特徴がある。よって基材11、下層12及び中層13の組成が上層14側に拡散するのを抑制して耐熱性を向上させる。また、これら金属は、上層14のSnやInと化合物を形成してSnやInの酸化膜形成を抑制し、はんだ濡れ性を向上させる。なお、Ag、Au、Pt、Pd、Ru、Rh、Os、Irの中では、導電率の観点でAgがより望ましい。Agは導電率が高い。例えば高周波の信号用途にAgを用いた場合、表皮効果により、インピーダンス抵抗が低くなる。
上層14の厚みは0.02μm以上1.00μm未満である必要がある。上層14の厚みが0.02μm未満であると、基材11や下層12の組成が上層14側に拡散しやすくなって耐熱性やはんだ濡れ性が悪くなる。また微摺動によって上層が磨耗し、接触抵抗の高い下層12が露出しやすくなるため耐微摺動磨耗性が悪く、微摺動によって接触抵抗が上昇しやすくなる。更に耐ガス腐食性が悪い下層12が露出しやすくなるため耐ガス腐食性も悪く、ガス腐食試験を行うと外観が変色してしまう。一方、上層14の厚みが1.00μm以上であると、硬い基材11または下層12による薄膜潤滑効果が低下して凝着磨耗が大きくなる。また機械的耐久性が低下して、めっき削れが発生しやすくなる。
上層14は、B構成元素群の金属を10〜50at%含有することが好ましい。B構成元素群の金属が10at%未満であると、例えばC構成元素群の金属がAgの場合、耐ガス腐食性が悪く、ガス腐食試験を行うと外観が変色する場合がある。一方、B構成元素群の金属が50at%を超えると、上層14におけるB構成元素群の金属の割合が大きくなって凝着磨耗が大きくなり、またウィスカも発生しやすくなる。更に耐微摺動磨耗性が悪い場合もある。
上層14に、Snを11.8〜22.9at%含むSnAg合金であるζ(ゼータ)相が存在することが好ましい。当該ζ(ゼータ)相が存在することで耐ガス腐食性が向上し、ガス腐食試験を行っても外観が変色しにくくなる。
上層14に、ζ(ゼータ)相と、Ag3Snであるε(イプシロン)相とが存在することが好ましい。ε(イプシロン)相の存在によって、上層14にζ(ゼータ)相のみが存在する場合と比較して皮膜が硬くなり凝着磨耗が低下する。また上層14のSn割合が多くなることで耐ガス腐食性が向上する。
上層14に、Ag3Snであるε(イプシロン)相のみが存在することが好ましい。上層14にε(イプシロン)相が単独に存在することによって、上層14にζ(ゼータ)相とAg3Snであるε(イプシロン)相とが存在する場合と比較して皮膜が更に硬くなり凝着磨耗が低下する。また上層14のSn割合がより多くなることで耐ガス腐食性も向上する。
上層14に、Ag3Snであるε(イプシロン)相と、Sn単相であるβSnとが存在することが好ましい。Ag3Snであるε(イプシロン)相と、Sn単相であるβSnとが存在することによって、上層14にε(イプシロン)相のみが存在する場合と比較して更に上層のSn割合がより多くなることで耐ガス腐食性が向上する。
上層14に、Snを11.8〜22.9at%含むSnAg合金であるζ(ゼータ)相と、Ag3Snであるε(イプシロン)相と、Sn単相であるβSnとが存在することが好ましい。ζ(ゼータ)相と、Ag3Snであるε(イプシロン)相と、Sn単相であるβSnとが存在することによって、耐ガス腐食性が向上し、ガス腐食試験を行っても外観が変色しにくく、凝着磨耗が低下する。この組成は拡散で生じるものであり、平衡状態の構造ではない。
上層14がβSn単独では存在してはいけない。βSn単独での存在の場合には、凝着磨耗が大きく、ウィスカも発生し、耐熱性及び耐微摺動磨耗性等が劣化する。
(Upper layer)
The upper layer 14 is composed of one or two selected from the group consisting of Sn and In which is a group consisting of B, and a group C consisting of a group consisting of Ag, Au, Pt, Pd, Ru, Rh, Os and Ir It is necessary to be comprised with the alloy with 1 type, or 2 or more types selected from the group.
Sn and In are oxidizable metals, but are relatively soft among metals. Therefore, even if an oxide film is formed on the Sn and In surfaces, for example, when a male terminal and a female terminal are mated using a metal material for electronic parts as a contact material, the oxide film is easily scraped, and the contact becomes metal-to-metal. Therefore, low contact resistance is obtained.
Sn and In are excellent in gas corrosion resistance against gases such as chlorine gas, sulfurous acid gas, and hydrogen sulfide gas. For example, upper layer 14 is inferior in gas corrosion resistance, lower layer 12 is inferior in gas corrosion resistance, When copper and a copper alloy inferior in gas corrosion resistance are used for the base material 11, there exists a function which improves the gas corrosion resistance of the metal material for electronic components. For Sn and In, Sn is preferable because In is strictly regulated based on the technical guidelines for preventing health problems of the Ministry of Health, Labor and Welfare.
Ag, Au, Pt, Pd, Ru, Rh, Os, and Ir are characterized by relatively heat resistance among metals. Therefore, it suppresses that the composition of the base material 11, the lower layer 12, and the middle layer 13 diffuses to the upper layer 14 side, and improves heat resistance. Further, these metals form a compound with Sn or In in the upper layer 14 to suppress the formation of an oxide film of Sn or In and improve solder wettability. Among Ag, Au, Pt, Pd, Ru, Rh, Os, and Ir, Ag is more desirable from the viewpoint of conductivity. Ag has high conductivity. For example, when Ag is used for high frequency signal applications, the impedance resistance is lowered due to the skin effect.
The thickness of the upper layer 14 needs to be 0.02 μm or more and less than 1.00 μm. When the thickness of the upper layer 14 is less than 0.02 μm, the composition of the base material 11 and the lower layer 12 is easily diffused to the upper layer 14 side, and heat resistance and solder wettability are deteriorated. Further, the upper layer is worn by fine sliding, and the lower layer 12 having a high contact resistance is easily exposed, so the resistance to fine sliding wear is poor, and the contact resistance is likely to increase by fine sliding. Furthermore, since the lower layer 12 having poor gas corrosion resistance is easily exposed, the gas corrosion resistance is also poor, and when the gas corrosion test is performed, the appearance is discolored. On the other hand, when the thickness of the upper layer 14 is 1.00 μm or more, the thin film lubrication effect by the hard base material 11 or the lower layer 12 is lowered and adhesion wear is increased. In addition, mechanical durability is lowered, and plating scraping is likely to occur.
The upper layer 14 preferably contains 10 to 50 at% of the metal of the B constituent element group. When the metal of the B constituent element group is less than 10 at%, for example, when the metal of the C constituent element group is Ag, the gas corrosion resistance is poor, and when the gas corrosion test is performed, the appearance may be discolored. On the other hand, if the metal of the B constituent element group exceeds 50 at%, the proportion of the metal of the B constituent element group in the upper layer 14 increases, and adhesion wear increases, and whiskers are likely to occur. Furthermore, there are cases where the resistance to fine sliding wear is poor.
The upper layer 14 preferably has a ζ (zeta) phase that is a SnAg alloy containing 11.8 to 22.9 at% of Sn. The presence of the ζ (zeta) phase improves the gas corrosion resistance, and the appearance hardly changes even when a gas corrosion test is performed.
It is preferable that a ζ (zeta) phase and an ε (epsilon) phase that is Ag 3 Sn exist in the upper layer 14. Due to the presence of the ε (epsilon) phase, the coating becomes harder and the adhesive wear is reduced as compared with the case where only the ζ (zeta) phase is present in the upper layer 14. Moreover, gas corrosion resistance improves because Sn ratio of the upper layer 14 increases.
It is preferable that only the ε (epsilon) phase that is Ag 3 Sn exists in the upper layer 14. The existence of the ε (epsilon) phase alone in the upper layer 14 makes the coating harder and harder than the case where the ζ (zeta) phase and the ε (epsilon) phase of Ag 3 Sn exist in the upper layer 14. Wear is reduced. Further, the higher the Sn ratio of the upper layer 14, the better the gas corrosion resistance.
It is preferable that an ε (epsilon) phase that is Ag 3 Sn and βSn that is a Sn single phase exist in the upper layer 14. By the presence of ε (epsilon) phase that is Ag 3 Sn and βSn that is Sn single phase, the upper layer has a higher Sn ratio than the case where only the ε (epsilon) phase is present in the upper layer 14. As a result, the gas corrosion resistance is improved.
The upper layer 14 may have a ζ (zeta) phase that is a SnAg alloy containing 11.8 to 22.9 at% of Sn, an ε (epsilon) phase that is Ag 3 Sn, and βSn that is a single Sn phase. preferable. The presence of the ζ (zeta) phase, the ε (epsilon) phase that is Ag 3 Sn, and βSn that is the Sn single phase improves the gas corrosion resistance, and the appearance changes even when a gas corrosion test is performed. It is difficult to wear and adhesion wear decreases. This composition occurs by diffusion and is not an equilibrium structure.
The upper layer 14 should not be present by βSn alone. In the presence of βSn alone, adhesion wear is large, whiskers are generated, and heat resistance, fine sliding wear resistance and the like deteriorate.
(中層)
下層12と上層14との間に、Ni、Cr、Mn、Fe、Co及びCuからなる群であるA構成元素群から選択された1種又は2種以上と、Sn及びInからなる群であるB構成元素群から選択された1種又は2種とで構成された中層13が0.01μm以上0.40μm未満の厚さで形成されている必要がある。Sn及びInは塩素ガス、亜硫酸ガス、硫化水素ガス等のガスに対する耐ガス腐食性に優れ、例えば、下層12に耐ガス腐食性に劣るNi、基材11に耐ガス腐食性に劣る銅及び銅合金を用いた場合には、電子部品用金属材料の耐ガス腐食性を向上させる働きがある。Ni、Cr、Mn、Fe、Co及びCuは、SnやInと比較して皮膜が硬いために凝着磨耗が生じにくく、基材11の構成金属が上層14に拡散するのを防止し、耐熱性試験やはんだ濡れ性劣化を抑制するなどの耐久性を向上させる。
中層13の厚みが0.01μm以上であると皮膜が硬くなり凝着磨耗が減少する。一方中層13厚みが0.40μm以上であると曲げ加工性が低下し、また機械的耐久性が低下して、めっき削れが発生する場合もある。
Sn及びInの中では、厚生労働省の健康障害防止に関する技術指針に基づき、Inは規制が厳しいため、Snが好ましい。またNi、Cr、Mn、Fe、Co及びCuの中ではNiが好ましい。これはNiが硬くて凝着磨耗が生じにくく、また十分な曲げ加工性が得られるためである。
中層13においてB構成元素群の金属が35at%以上であることが好ましい。Snが35at%以上になることで皮膜が硬くなり凝着磨耗が減少する場合がある。
中層13は、Ni3SnとNi3Sn2とで構成されていてもよく、Ni3Sn2又はNi3Sn4単独で構成されていてもよい。Ni3Sn、Ni3Sn2、Ni3Sn4が存在することによって耐熱性やはんだ濡れ性が向上する場合がある。
中層13に、Ni3Sn4と、Sn単相であるβSnとが存在することが好ましい。これらが存在することによって耐熱性やはんだ濡れ性は、Ni3Sn4とNi3Sn2が存在する場合と比較して耐熱性やはんだ濡れ性が向上する場合がある。
(Middle layer)
Between the lower layer 12 and the upper layer 14, one or more selected from the group A constituent elements that are a group consisting of Ni, Cr, Mn, Fe, Co and Cu, and a group consisting of Sn and In It is necessary that the middle layer 13 composed of one or two selected from the B constituent element group is formed with a thickness of 0.01 μm or more and less than 0.40 μm. Sn and In are excellent in gas corrosion resistance against gases such as chlorine gas, sulfurous acid gas, and hydrogen sulfide gas. For example, Ni is inferior in gas corrosion resistance in the lower layer 12, and copper and copper inferior in gas corrosion resistance in the base material 11. When an alloy is used, it has the function of improving the gas corrosion resistance of the metal material for electronic parts. Ni, Cr, Mn, Fe, Co, and Cu are hard to cause adhesive wear because the film is harder than Sn and In, and prevent the constituent metals of the base material 11 from diffusing into the upper layer 14. Improve durability, such as suppressing property deterioration and solder wettability degradation.
When the thickness of the middle layer 13 is 0.01 μm or more, the coating becomes hard and adhesion wear decreases. On the other hand, when the thickness of the middle layer 13 is 0.40 μm or more, the bending workability is lowered, the mechanical durability is lowered, and plating scraping may occur.
Among Sn and In, Sn is preferable because In is strictly regulated based on the technical guideline for preventing health problems of the Ministry of Health, Labor and Welfare. Of Ni, Cr, Mn, Fe, Co and Cu, Ni is preferable. This is because Ni is hard and adhesion wear hardly occurs, and sufficient bending workability is obtained.
In the middle layer 13, the B group element group metal is preferably 35 at% or more. If the Sn content is 35 at% or more, the film becomes hard and adhesion wear may be reduced.
The middle layer 13 may be composed of Ni 3 Sn and Ni 3 Sn 2 , or may be composed of Ni 3 Sn 2 or Ni 3 Sn 4 alone. The presence of Ni 3 Sn, Ni 3 Sn 2 and Ni 3 Sn 4 may improve heat resistance and solder wettability.
It is preferable that Ni 3 Sn 4 and βSn which is a Sn single phase exist in the middle layer 13. The presence of these may improve the heat resistance and solder wettability as compared with the case where Ni 3 Sn 4 and Ni 3 Sn 2 exist.
(上層の厚みと上層の最小厚みとの関係)
上層14の最小厚み(μm)が上層14の厚み(μm)の50%以上を満たすことが好ましい。上層14の最小厚みが上層14の厚みの50%未満であると、上層14の表面粗さが粗いこととなり、接触抵抗が高く、はんだも濡れにくく、耐ガス腐食性が劣るNiが表面に露出しやすくなるため、耐熱性、はんだ濡れ性、耐ガス腐食性が悪くなる場合がある。
ここで、上層14の厚みと上層14の最小厚みとの関係を把握する場所は、本発明の皮膜の作用効果を発揮する部分の平均的断面である。当該部分での、素材の正常表面プロフィール(オイルピット、エッチピット、スクラッチ、だ痕、その他表面欠陥部分を含まない)において正常に成膜処置された部分を示す。成膜前後でのプレス加工による変形部分等を含まないことはいうまでもない。
(Relationship between upper layer thickness and upper layer minimum thickness)
It is preferable that the minimum thickness (μm) of the upper layer 14 satisfies 50% or more of the thickness (μm) of the upper layer 14. When the minimum thickness of the upper layer 14 is less than 50% of the thickness of the upper layer 14, the surface roughness of the upper layer 14 is rough, the contact resistance is high, the solder is difficult to wet, and Ni having poor gas corrosion resistance is exposed on the surface. Heat resistance, solder wettability, and gas corrosion resistance may deteriorate.
Here, the place where the relationship between the thickness of the upper layer 14 and the minimum thickness of the upper layer 14 is grasped is the average cross section of the portion that exhibits the effect of the coating of the present invention. A portion where the film is normally formed in the normal surface profile of the material (excluding oil pits, etch pits, scratches, marks, and other surface defect portions) is shown. Needless to say, it does not include a deformed portion by press working before and after film formation.
(上層の厚みと、上層と中層との界面プロフィールの隣り合う山と谷の高低差の最大値との関係)
上層14と中層13との界面プロフィールの隣り合う山と谷の高低差の最大値(μm)が、上層14の厚み(μm)の50%以下を満たすことが好ましい。上層14と中層13との界面プロフィールの隣り合う山と谷の高低差の最大値が、上層14の厚みの50%を超えると、上層14の近くに中層13が存在することとなり、接触抵抗が高く、はんだも濡れにくく、耐ガス腐食性が劣るNiが表面に露出しやすくなるため、耐熱性、はんだ濡れ性、耐ガス腐食性が悪くなる場合がある。
上層14の厚みのミクロ的分布及び上層14と中層13との界面プロフィールは、下層12、中層13及び上層14の成膜条件によって制御することができる。成膜時に、めっき条件(金属濃度、添加剤、陰極電流密度、液攪拌等)の調整により、上記「上層の厚みと上層の最小厚みとの関係」、及び、上記「上層の厚みと、上層と中層との界面プロフィールの隣り合う山と谷の高低差の最大値との関係」を満たすように、平滑に電着成膜させる。
(Relationship between the thickness of the upper layer and the maximum height difference between adjacent peaks and valleys in the interface profile between the upper layer and the middle layer)
It is preferable that the maximum value (μm) of the height difference (μm) between adjacent peaks and valleys in the interface profile between the upper layer 14 and the middle layer 13 satisfies 50% or less of the thickness (μm) of the upper layer 14. When the maximum height difference between adjacent peaks and valleys of the interface profile between the upper layer 14 and the middle layer 13 exceeds 50% of the thickness of the upper layer 14, the middle layer 13 is present near the upper layer 14, and the contact resistance is reduced. Ni, which is high and hardly wets the solder and is inferior in gas corrosion resistance, is likely to be exposed on the surface, so that heat resistance, solder wettability, and gas corrosion resistance may deteriorate.
The microscopic distribution of the thickness of the upper layer 14 and the interface profile between the upper layer 14 and the middle layer 13 can be controlled by the film forming conditions of the lower layer 12, the middle layer 13, and the upper layer 14. By adjusting the plating conditions (metal concentration, additive, cathode current density, liquid stirring, etc.) during film formation, the above “relationship between upper layer thickness and upper layer minimum thickness” and the above “upper layer thickness and upper layer” The film is smoothly electrodeposited so as to satisfy the relationship between the height of the height difference between adjacent peaks and valleys of the interface profile between the intermediate layer and the intermediate layer.
(上層と中層の厚さの割合及び組成)
上層14と中層13の厚みの比が、上層:中層=9:1〜3:7であることが好ましい。上層14の割合が9を超えると、硬い基材11、下層12及び上層14よりも硬い中層13に薄膜潤滑効果が低下して凝着磨耗が大きくなる。一方上層14の割合が3を下回ると、接触抵抗が高く、はんだも濡れにくく、耐ガス腐食性が劣るNiが表面に露出しやすくなるため、耐熱性、はんだ濡れ性、耐微摺動磨耗性及び耐ガス腐食性が悪くなる場合がある。
また、上層14から、上層14の最表面から0.03μmの範囲を除く中層13までにおいて、C、S、Oを、それぞれ2at%以下含有するのが好ましい。C、S、Oが2at%よりも多いと熱処理を施したときにこれら共析元素がガス化して均一な合金皮膜が形成できなくなるおそれがある。
(Ratio and composition of thickness of upper layer and middle layer)
The thickness ratio of the upper layer 14 and the middle layer 13 is preferably upper layer: middle layer = 9: 1 to 3: 7. When the ratio of the upper layer 14 exceeds 9, the thin film lubrication effect is reduced to the hard base material 11, the lower layer 12, and the middle layer 13 that is harder than the upper layer 14, and adhesion wear increases. On the other hand, if the ratio of the upper layer 14 is less than 3, the contact resistance is high, the solder is difficult to get wet, and Ni, which is inferior in gas corrosion resistance, is likely to be exposed on the surface, so heat resistance, solder wettability, fine sliding wear resistance In addition, gas corrosion resistance may deteriorate.
Moreover, it is preferable that C, S, and O are each contained in 2 at% or less from the upper layer 14 to the middle layer 13 excluding the range of 0.03 μm from the outermost surface of the upper layer 14. When C, S, and O are more than 2 at%, these eutectoid elements may be gasified when heat treatment is performed, and a uniform alloy film may not be formed.
(下層)
基材11と上層14との間には、Ni、Cr、Mn、Fe、Co及びCuからなる群であるA構成元素群から選択された1種又は2種以上で構成された下層12を形成する必要がある。Ni、Cr、Mn、Fe、Co及びCuからなる群であるA構成元素群から選択された1種又は2種以上の金属を用いて下層12を形成することで、硬い下層12形成により薄膜潤滑効果が向上して凝着磨耗が低下し、下層12は基材11の構成金属が上層14に拡散するのを防止して耐熱性やはんだ濡れ性などを向上させる。
下層12の厚みは0.05μm以上である必要がある。下層12の厚みが0.05μm未満であると、硬い下層による薄膜潤滑効果が低下して凝着磨耗が大きくなる。基材11の構成金属は上層14に拡散しやすくなり、耐熱性やはんだ濡れ性が劣化する。一方、下層12の厚みは5.00μm未満である必要がある。厚みが5.00μm以上であると曲げ加工性が悪い。
(Underlayer)
Between the base material 11 and the upper layer 14, a lower layer 12 composed of one or more selected from the A constituent element group which is a group consisting of Ni, Cr, Mn, Fe, Co, and Cu is formed. There is a need to. By forming the lower layer 12 using one or two or more metals selected from the group A constituent elements which are a group consisting of Ni, Cr, Mn, Fe, Co and Cu, thin film lubrication is achieved by forming the hard lower layer 12. The effect is improved and adhesion wear is reduced, and the lower layer 12 prevents the constituent metals of the base material 11 from diffusing into the upper layer 14 and improves heat resistance, solder wettability, and the like.
The thickness of the lower layer 12 needs to be 0.05 μm or more. When the thickness of the lower layer 12 is less than 0.05 μm, the thin film lubricating effect by the hard lower layer is lowered, and adhesion wear increases. The constituent metal of the base material 11 is easily diffused into the upper layer 14, and heat resistance and solder wettability are deteriorated. On the other hand, the thickness of the lower layer 12 needs to be less than 5.00 μm. Bending workability is poor when the thickness is 5.00 μm or more.
上層14の表面に、B構成元素の合計原子濃度(at%)≧C構成元素の合計原子濃度(at%)であり、Oの原子濃度(at%)≧10at%である領域が0.02μm以下で存在することが好ましい。B構成元素であるSn等はOとの親和性を有するため、Snめっき後に表面はOと結合する。この結合でできた酸化Snは加熱処理を施してもSgAgの合金化が生じず加熱処理前の状態を維持するため、この領域が存在する。但し、この領域が0.02μmを超えると接触抵抗やはんだ濡れ性が劣化する場合がある。 On the surface of the upper layer 14, the total atomic concentration of B constituent elements (at%) ≧ the total atomic concentration of C constituent elements (at%) and the region where the atomic concentration of O (at%) ≧ 10 at% is 0.02 μm It is preferably present in: Since Sn, which is a B constituent element, has an affinity for O, the surface binds to O after Sn plating. This region exists because Sn oxide formed by this bonding does not cause alloying of SgAg even when heat treatment is performed, and maintains the state before the heat treatment. However, if this region exceeds 0.02 μm, contact resistance and solder wettability may deteriorate.
下層12と中層13との間に、さらにA構成元素群の金属とC構成元素群の金属との合金で構成された層を備えてもよい。当該層としては、例えば、Ni−Ag合金層が好ましい。このような層が下層12と中層13との間に形成されていれば、基材11の構成金属が上層14に拡散するのをさらに良好に防止して耐熱性やはんだ濡れ性などを向上させる。 Between the lower layer 12 and the middle layer 13, a layer made of an alloy of a metal of the A constituent element group and a metal of the C constituent element group may be further provided. As the layer, for example, a Ni—Ag alloy layer is preferable. If such a layer is formed between the lower layer 12 and the middle layer 13, the constituent metal of the base material 11 is further prevented from diffusing into the upper layer 14 to improve heat resistance, solder wettability, and the like. .
(A構成元素群)
A構成元素群の金属がNi、Cr、Mn、Fe、Co、Cuの合計で50mass%以上であり、さらにB、P、Sn及びZnからなる群から選択された1種又は2種以上を含んでも良い。下層12の合金組成がこのような構成となることで、下層12がより硬化することで更に薄膜潤滑効果が向上して更に凝着磨耗が低下し、下層12の合金化は基材11の構成金属が上層に拡散するのを更に防止し、耐熱性やはんだ濡れ性等の耐久性を向上させる場合がある。
(Group A element group)
The metal of the A constituent element group is 50 mass% or more in total of Ni, Cr, Mn, Fe, Co, and Cu, and further includes one or more selected from the group consisting of B, P, Sn, and Zn But it ’s okay. When the alloy composition of the lower layer 12 has such a configuration, the lower layer 12 is further cured, so that the thin film lubrication effect is further improved and adhesion wear is further reduced. It may further prevent the metal from diffusing into the upper layer, and may improve durability such as heat resistance and solder wettability.
(B構成元素群)
B構成元素群の金属がSnとInとの合計で50mass%以上であり、残合金成分がAg、As、Au、Bi、Cd、Co、Cr、Cu、Fe、Mn、Mo、Ni、Pb、Sb、W及びZnからなる群から選択された1種又は2種以上の金属からなっていても良い。これらの金属によって更に凝着磨耗が少なくし、またウィスカの発生を抑制し、さらに耐熱性やはんだ濡れ性等の耐久性を向上させる場合がある。
(B element group)
The B group element group metals are 50 mass% or more in total of Sn and In, and the remaining alloy components are Ag, As, Au, Bi, Cd, Co, Cr, Cu, Fe, Mn, Mo, Ni, Pb, You may consist of 1 type, or 2 or more types of metals selected from the group which consists of Sb, W, and Zn. These metals may further reduce adhesion wear, suppress whisker generation, and improve durability such as heat resistance and solder wettability.
(C構成元素群)
C構成元素群の金属がAgとAuとPtとPdとRuとRhとOsとIrとの合計で50mass%以上であり、残合金成分がBi、Cd、Co、Cu、Fe、In、Mn、Mo、Ni、Pb、Sb、Se、Sn、W、Tl及びZnからなる群から選択された1種又は2種以上の金属からなっていても良い。これらの金属によって更に凝着磨耗が少なくし、またウィスカの発生を抑制し、さらに耐熱性やはんだ濡れ性等の耐久性を向上させる場合がある。
(C element group)
The metal of the C constituent element group is 50 mass% or more in total of Ag, Au, Pt, Pd, Ru, Rh, Os, and Ir, and the remaining alloy components are Bi, Cd, Co, Cu, Fe, In, Mn, You may consist of 1 type, or 2 or more types of metals selected from the group which consists of Mo, Ni, Pb, Sb, Se, Sn, W, Tl, and Zn. These metals may further reduce adhesion wear, suppress whisker generation, and improve durability such as heat resistance and solder wettability.
(拡散処理)
上層14、中層13及び下層12が、基材11上にA構成元素群から選択された1種又は2種以上を成膜し、その後、C構成元素群から選択された1種又は2種を成膜し、その後、B構成元素群から選択された1種又は2種類以上を成膜し、A構成元素群、B構成元素群及びC構成元素群の各元素が拡散することでそれぞれ形成されていても良い。例えばB構成元素群の金属がSn、C構成元素群の金属がAgの場合、SnへのAgの拡散は速く、自然拡散によってSn−Ag合金層を形成する。合金層形成によりSnの凝着力を一層小さくし、また低ウィスカ性及び耐久性も更に向上させることができる。
(Diffusion processing)
The upper layer 14, the middle layer 13 and the lower layer 12 are formed on the base material 11 with one or more selected from the A constituent element group, and then one or two selected from the C constituent element group are formed. After forming a film, one or more types selected from the B constituent element group are formed, and each element of the A constituent element group, the B constituent element group, and the C constituent element group is diffused to form each film. May be. For example, when the metal of the B constituent element group is Sn and the metal of the C constituent element group is Ag, the diffusion of Ag into Sn is fast, and an Sn—Ag alloy layer is formed by natural diffusion. By forming the alloy layer, the adhesion force of Sn can be further reduced, and the low whisker property and durability can be further improved.
(熱処理)
上層14を形成させた後に更に凝着磨耗抑制し、また低ウィスカ性及び耐久性を更に向上させる目的で熱処理を施しても良い。熱処理によって上層14のB構成元素群の金属とC構成元素群の金属、中層13のA構成元素群の金属とB構成元素群の金属とが合金層をより形成しやすくなり、Snの凝着力を一層小さくし、また低ウィスカ性及び耐久性も更に向上させることができる。
なお、この熱処理については、処理条件(温度×時間)は適宜選択できる。また、特にこの熱処理はしなくてもよい。なお熱処理を施す場合にはB構成元素群の金属の融点以上の温度で行った方が上層14のB構成元素群の金属とC構成元素群の金属、中層13のA構成元素群の金属とB構成元素群の金属とが合金層をより形成しやすくなる。
(Heat treatment)
After the upper layer 14 is formed, heat treatment may be performed for the purpose of further suppressing adhesion wear and further improving the low whisker property and durability. The heat treatment makes it easier for the metal of the B constituent element group and the metal of the C constituent element group of the upper layer 14, the metal of the A constituent element group of the middle layer 13 and the metal of the B constituent element group to form an alloy layer, and Sn adhesion force The whisker property and durability can be further improved.
In addition, about this heat processing, process conditions (temperature x time) can be selected suitably. Further, this heat treatment is not particularly required. When heat treatment is performed, the temperature of the B constituent element group metal is higher than the melting point of the B constituent element group metal, the B constituent element group metal of the upper layer 14 and the C constituent element group metal, and the middle layer 13 of the A constituent element group metal. It becomes easier to form an alloy layer with the metal of the B constituent element group.
(後処理)
上層14上に、または上層14上に熱処理を施した後に、更に凝着磨耗を低下させ、また低ウィスカ性及び耐久性も向上させる目的で後処理を施しても良い。後処理によって潤滑性が向上し、更に凝着磨耗が低下しまた上層14の酸化が抑制されて、耐熱性やはんだ濡れ性等の耐久性を向上させることができる。具体的な後処理としてはインヒビターを用いた、リン酸塩処理、潤滑処理、シランカップリング処理等がある。なお、この熱処理については、処理条件(温度×時間)は適宜選択できる。また、特にこの後処理はしなくてもよい。
(Post-processing)
After the heat treatment is performed on the upper layer 14 or on the upper layer 14, a post-treatment may be performed for the purpose of further reducing adhesion wear and improving low whisker property and durability. The post-treatment improves lubricity, further reduces adhesion wear, suppresses oxidation of the upper layer 14, and improves durability such as heat resistance and solder wettability. Specific post-treatment includes phosphate treatment, lubrication treatment, silane coupling treatment, etc. using an inhibitor. In addition, about this heat processing, process conditions (temperature x time) can be selected suitably. Further, this post-processing is not particularly required.
後処理としては、上層14表面を、1種又は2種以上のリン酸エステルと、環状有機化合物の1種又は2種以上とを含有する水溶液(リン酸エステル系液とよぶ)を用いて行うことが望ましい。リン酸エステル系液に添加されるリン酸エステルは、めっきの酸化防止剤および潤滑剤としての機能を果たす。本発明に使用されるリン酸エステルは、一般式〔1〕および〔2〕で表される。一般式〔1〕で表される化合物のうち好ましいものを挙げると、ラウリル酸性リン酸モノエステルなどがある。一般式〔2〕で表される化合物のうち好ましいものを挙げると、ラウリル酸性ジリン酸エステルなどがある。 As post-processing, the surface of the upper layer 14 is performed using an aqueous solution (referred to as a phosphate ester-based solution) containing one or more phosphate esters and one or more cyclic organic compounds. It is desirable. The phosphoric acid ester added to the phosphoric acid ester system liquid functions as an antioxidant and a lubricant for plating. The phosphate ester used in the present invention is represented by the general formulas [1] and [2]. Preferable examples of the compound represented by the general formula [1] include lauryl acidic phosphoric acid monoester. Preferred examples of the compound represented by the general formula [2] include lauryl acid diphosphate.
リン酸エステル系液に添加される環状有機化合物は、めっきの酸化防止剤としての機能をはたす。本発明に使用される環状有機化合物の群を一般式〔3〕および〔4〕で表す。一般式〔3〕および〔4〕で表す環状有機化合物群のうち好ましいものを挙げると、例えばメルカプトベンゾチアゾール、メルカプトベンゾチアゾールのNa塩、メルカプトベンゾチアゾールのK塩、ベンゾトリアゾール、1−メチルトリアゾール、トリルトリアゾール、トリアジン系化合物などがある。 The cyclic organic compound added to the phosphate ester-based liquid functions as an antioxidant for plating. A group of cyclic organic compounds used in the present invention is represented by general formulas [3] and [4]. Preferred examples of the cyclic organic compound group represented by the general formulas [3] and [4] include mercaptobenzothiazole, mercaptobenzothiazole Na salt, mercaptobenzothiazole K salt, benzotriazole, 1-methyltriazole, Examples include tolyltriazole and triazine compounds.
後処理後に上層14表面にPとNが共に存在するように処理を行うのがさらに好ましい。めっき表面にPが存在しないとはんだ付け性が劣化しやすくなり、まためっき材の潤滑性も悪くなる。一方SnまたはSn合金めっき表面にNが存在しないと、高温環境下においてめっき材の接触抵抗が上昇しやすくなる場合がある。
さらに本発明では、上層14表面にPが付着している場合、当該付着量を、1×10-11〜4×10-8mol/cm2とすると、はんだ付け性がさらに劣化しにくく、潤滑性がより良好で、接触抵抗の上昇も少なくなるため好ましい。また、上層14表面にさらにNが付着している場合、当該付着量を、2×10-12〜8×10-9mol/cm2とするとより好ましい。Pの付着量が1×10-11mol/cm2未満では、はんだ濡れ性が劣化しやすくなり、付着量が4×10-8mol/cm2を超えると、接触抵抗が高くなるという不具合が発生する場合がある。
また、上層14をXPS法で分析した際検出されるPの2S軌道電子の遷移による光電子検出強度をI(P2s)、Nの1S軌道電子の遷移による光電子検出強度をI(N1s)とすると、0.1≦I(P2s)/I(N1s)≦1の関係を満たす場合には、めっき材の接触抵抗とはんだ付け性が高温環境下において劣化しにくくなる場合がある。I(P2s)/I(N1s)の値が0.1未満の場合には接触抵抗などの劣化防止機能が十分ではなく、値が1を超える場合は初期の接触抵抗がやや高めになるが、次に説明するように、めっき材の動摩擦係数が小さくなる場合がある。また、この場合、I(P2s)及びI(N1s)は、0.3≦I(P2s)/I(N1s)≦0.8の関係を満たすのがより好ましい。
上記と同様に上層14をXPS法で分析した際検出されるPの2S軌道電子の遷移による光電子検出強度をI(P2s)、Nの1S軌道電子の遷移による光電子検出強度をI(N1s)とすると、1<I(P2s)/I(N1s)≦50の関係を満たす場合にはめっき材の動摩擦係数が小さくなり、端子、コネクタの挿入力が低くなる場合がある。I(P2s)/I(N1s)の値が1以下の場合には挿入力がやや高めになり、値が50を超えると挿入力は低くなるが、初期の接触抵抗が高くなり、初期のはんだ付け性も悪くなる場合がある。また、この場合、I(P2s)及びI(N1s)は、5<I(P2s)/I(N1s)≦40の関係を満たすのがより好ましい。
More preferably, the treatment is performed so that both P and N are present on the surface of the upper layer 14 after the post-treatment. If P is not present on the plating surface, the solderability is likely to deteriorate, and the lubricity of the plating material also deteriorates. On the other hand, if N is not present on the Sn or Sn alloy plating surface, the contact resistance of the plating material may easily increase in a high temperature environment.
Furthermore, in the present invention, when P adheres to the surface of the upper layer 14, if the adhesion amount is 1 × 10 −11 to 4 × 10 −8 mol / cm 2 , the solderability is not further deteriorated and lubrication is performed. This is preferable because the property is better and the increase in contact resistance is less. Further, when N is further adhered to the surface of the upper layer 14, it is more preferable that the amount of adhesion is 2 × 10 −12 to 8 × 10 −9 mol / cm 2 . When the adhesion amount of P is less than 1 × 10 −11 mol / cm 2 , the solder wettability tends to deteriorate, and when the adhesion amount exceeds 4 × 10 −8 mol / cm 2 , the contact resistance increases. May occur.
Further, if the photoelectron detection intensity by the transition of P 2S orbital electrons detected when the upper layer 14 is analyzed by the XPS method is I (P2s), and the photoelectron detection intensity by the transition of 1S orbital electrons of N is I (N1s), When the relationship of 0.1 ≦ I (P2s) / I (N1s) ≦ 1 is satisfied, the contact resistance and solderability of the plating material may not easily deteriorate in a high temperature environment. When the value of I (P2s) / I (N1s) is less than 0.1, the deterioration prevention function such as contact resistance is not sufficient. When the value exceeds 1, the initial contact resistance is slightly higher. As will be described next, the dynamic friction coefficient of the plating material may be small. In this case, it is more preferable that I (P2s) and I (N1s) satisfy the relationship of 0.3 ≦ I (P2s) / I (N1s) ≦ 0.8.
Similarly to the above, I (P2s) is the photoelectron detection intensity due to the transition of P 2S orbital electrons detected when the upper layer 14 is analyzed by the XPS method, and I (N1s) is the photoelectron detection intensity due to the transition of N 1S orbital electrons. Then, when the relationship of 1 <I (P2s) / I (N1s) ≦ 50 is satisfied, the dynamic friction coefficient of the plating material may be decreased, and the insertion force of the terminals and connectors may be decreased. When the value of I (P2s) / I (N1s) is 1 or less, the insertion force is slightly higher. When the value exceeds 50, the insertion force is lowered, but the initial contact resistance is increased, and the initial solder is increased. There is a case that the attachment is also deteriorated. In this case, it is more preferable that I (P2s) and I (N1s) satisfy the relationship of 5 <I (P2s) / I (N1s) ≦ 40.
本発明の上層14表面における後処理液成分の付着量を得るためのリン酸エステルの濃度は、0.1〜10g/L、好ましくは0.5〜5g/Lである。一方環状有機化合物の濃度は処理液全体の体積に対して0.01〜1.0g/L、好ましくは0.05〜0.6g/Lである。
リン酸エステル系液は上述の成分を有する水溶液であるが、溶液の温度を40〜80℃に加熱すると成分の水への乳化がより速やかに進行し、さらの処理後の材料の乾燥が容易になる。
表面処理は、上層14形成後の上層14の表面にリン酸エステル系液を塗布して行ってもよい。塗布するする方法としては、スプレーコーティング、フローコーティング、ディップコーティング、ロールコーティング等の方法が挙げられ生産性の観点からディップコーティングもしくはスプレーコーティングが好ましい。一方、別の処理方法として、上層14形成後の金属材料をリン酸エステル系液に中に浸漬させ、金属材料を陽極にして電解することで行ってもよい。この方法で処理した金属材料では、高温環境下での接触抵抗がより上昇しにくいという利点がある。
The concentration of the phosphate ester for obtaining the adhesion amount of the post-treatment liquid component on the surface of the upper layer 14 of the present invention is 0.1 to 10 g / L, preferably 0.5 to 5 g / L. On the other hand, the concentration of the cyclic organic compound is 0.01 to 1.0 g / L, preferably 0.05 to 0.6 g / L, with respect to the total volume of the treatment liquid.
Phosphate-based liquid is an aqueous solution containing the above-mentioned components, but when the temperature of the solution is heated to 40 to 80 ° C., the emulsification of the components into water proceeds more rapidly, and the material after further treatment can be easily dried. become.
The surface treatment may be performed by applying a phosphate ester-based liquid to the surface of the upper layer 14 after the upper layer 14 is formed. Examples of the application method include spray coating, flow coating, dip coating, roll coating, and the like. From the viewpoint of productivity, dip coating or spray coating is preferred. On the other hand, as another treatment method, the metal material after the formation of the upper layer 14 may be immersed in a phosphoric acid ester solution and electrolyzed using the metal material as an anode. The metal material treated by this method has an advantage that the contact resistance in a high temperature environment is less likely to increase.
これまで説明してきたリン酸エステル系液による表面処理は、上層14形成後、あるいは上層14形成後のリフロー処理の後のどちらで実施しても構わない。また、表面処理に時間的制約は特にないが、工業的観点からは一連の工程で行うのが好ましい。 The surface treatment with the phosphoric acid ester-based liquid described so far may be performed either after the upper layer 14 is formed or after the reflow treatment after the upper layer 14 is formed. The surface treatment is not particularly limited in time, but is preferably performed in a series of steps from an industrial viewpoint.
<電子部品用金属材料の特性>
超微小硬さ試験により、上層14の表面に荷重10mNで打痕を打って測定して得られた硬度である、上層14の表面の押し込み硬さが1000MPa以上であることが好ましい。押し込み硬さが1000MPa以上であることによって硬い上層14による薄膜潤滑効果が向上し、凝着磨耗を低下させる。上層の表面の押し込み硬さが10000MPa以下であることが好ましい。上層14表面の押し込み硬さが10000MPa以下であると、曲げ加工性が向上し、本発明の電子部品用金属材料をプレス成形した場合に、成形した部分にクラックが入り難くなり、耐ガス腐食性低下を抑制する。
上層14の表面の算術平均高さ(Ra)は0.3μm以下であるのが好ましい。上層14の表面の算術平均高さ(Ra)が0.3μm以下であると比較的腐食しやすい凸部が少なくなり平滑となるため、耐ガス腐食性が向上する。
上層14の表面の最大高さ(Rz)は3μm以下であるのが好ましい。上層14の表面の最大高さ(Rz)が3μm以下であると比較的腐食しやすい凸部が少なくなり平滑となるため、耐ガス腐食性が向上する。
下層12のビッカース硬さはHv300以上であるのが好ましい。下層12のビッカース硬さがHv300以上であると、下層がより硬化することで更に薄膜潤滑効果が向上して更に凝着磨耗が低下する。また一方で、下層12のビッカース硬さHv1000以下であるのが好ましい。下層12のビッカース硬さがHv1000以下であると、曲げ加工性が向上し、本発明の電子部品用金属材料をプレス成形した場合に、成形した部分にクラックが入り難くなり、耐ガス腐食性低下を抑制する。
下層12の断面の押し込み硬さは1500MPa以上であるのが好ましい。下層12の断面の押し込み硬さが1500MPa以上であると、下層12がより硬化することで更に薄膜潤滑効果が向上して凝着磨耗が低下する。また一方で、下層12の断面の押し込み硬さが10000MPa以下であるのが好ましい。下層12の断面の押し込み硬さが10000MPa以下であると、曲げ加工性が向上し、本発明の電子部品用金属材料をプレス成形した場合に、成形した部分にクラックが入り難くなり、耐ガス腐食性低下を抑制する。
<Characteristics of metal materials for electronic parts>
It is preferable that the indentation hardness of the surface of the upper layer 14 is 1000 MPa or more, which is the hardness obtained by measuring the surface of the upper layer 14 by making a dent with a load of 10 mN by an ultra micro hardness test. When the indentation hardness is 1000 MPa or more, the thin film lubricating effect by the hard upper layer 14 is improved, and adhesive wear is reduced. The indentation hardness of the upper layer surface is preferably 10,000 MPa or less. When the indentation hardness of the surface of the upper layer 14 is 10000 MPa or less, bending workability is improved, and when the metal material for electronic parts of the present invention is press-molded, cracks are hardly formed in the molded part, and gas corrosion resistance Suppresses the decline.
The arithmetic average height (Ra) of the surface of the upper layer 14 is preferably 0.3 μm or less. When the arithmetic average height (Ra) of the surface of the upper layer 14 is 0.3 μm or less, the number of convex portions that are relatively easily corroded is reduced and smoothed, so that the gas corrosion resistance is improved.
The maximum height (Rz) of the surface of the upper layer 14 is preferably 3 μm or less. When the maximum height (Rz) of the surface of the upper layer 14 is 3 μm or less, the number of convex portions that are relatively easily corroded is reduced and smoothed, so that the gas corrosion resistance is improved.
The Vickers hardness of the lower layer 12 is preferably Hv300 or higher. When the Vickers hardness of the lower layer 12 is Hv300 or more, the lower layer is further cured, so that the thin film lubricating effect is further improved and adhesion wear is further reduced. On the other hand, the lower layer 12 preferably has a Vickers hardness Hv of 1000 or less. When the Vickers hardness of the lower layer 12 is Hv1000 or less, the bending workability is improved, and when the metal material for electronic parts of the present invention is press-molded, cracks are hardly formed in the molded part, and the gas corrosion resistance is lowered. Suppress.
The indentation hardness of the cross section of the lower layer 12 is preferably 1500 MPa or more. When the indentation hardness of the cross section of the lower layer 12 is 1500 MPa or more, the lower layer 12 is further cured, so that the thin film lubrication effect is further improved and adhesion wear is reduced. On the other hand, the indentation hardness of the lower layer 12 is preferably 10,000 MPa or less. When the indentation hardness of the cross section of the lower layer 12 is 10000 MPa or less, bending workability is improved, and when the metal material for electronic parts of the present invention is press-molded, cracks are hardly formed in the molded part, and gas corrosion resistance Suppresses the decline in sex.
<電子部品用金属材料の用途>
本発明の電子部品用金属材料の用途は特に限定しないが、例えば電子部品用金属材料を接点部分に用いたコネクタ端子、電子部品用金属材料を接点部分に用いたFFC端子またはFPC端子、電子部品用金属材料を外部接続用電極に用いた電子部品などが挙げられる。なお、端子については、圧着端子、はんだ付け端子、プレスフィット端子等、配線側との接合方法によらない。外部接続用電極には、タブに表面処理を施した接続部品や半導体のアンダーバンプメタル用に表面処理を施した材料などがある。
また、このように形成されたコネクタ端子を用いてコネクタを作製しても良く、FFC端子またはFPC端子を用いてFFCまたはFPCを作製しても良い。
また本発明の電子部品用金属材料は、ハウジングに取り付ける装着部の一方側にメス端子接続部が、他方側に基板接続部がそれぞれ設けられ、該基板接続部を基板に形成されたスルーホールに圧入して該基板に取り付ける圧入型端子に用いても良い。
コネクタはオス端子とメス端子の両方が本発明の電子部品用金属材料であっても良いし、オス端子またはメス端子の片方だけであっても良い。なおオス端子とメス端子の両方を本発明の電子部品用金属材料にすることで、更に低挿抜性が向上する。
<Applications of metal materials for electronic parts>
The use of the metal material for electronic parts of the present invention is not particularly limited. For example, a connector terminal using the metal material for electronic parts as a contact part, an FFC terminal or FPC terminal using the metal material for electronic parts as a contact part, and an electronic part Electronic parts using metal materials for external connection as electrodes for external connection. In addition, about a terminal, it does not depend on the joining method with a wiring side, such as a crimp terminal, a solder terminal, and a press fit terminal. Examples of the external connection electrode include a connection component in which a surface treatment is performed on a tab and a material in which a surface treatment is applied to a semiconductor under bump metal.
Moreover, a connector may be produced using the connector terminal formed in this way, and an FFC or FPC may be produced using an FFC terminal or an FPC terminal.
In the metal material for electronic parts of the present invention, the female terminal connection portion is provided on one side of the mounting portion to be attached to the housing, and the substrate connection portion is provided on the other side. The substrate connection portion is formed in a through hole formed on the substrate. You may use for the press-fit type terminal which press-fits and attaches to this board | substrate.
In the connector, both the male terminal and the female terminal may be the metal material for electronic parts of the present invention, or only one of the male terminal and the female terminal. In addition, low insertion property is further improved by making both the male terminal and the female terminal into the metal material for electronic parts of the present invention.
<電子部品用金属材料の製造方法>
本発明の電子部品用金属材料の製造方法としては、湿式(電気、無電解)めっき、乾式(スパッタ、イオンプレーティング等)めっき等を用いることができる。
<Method for producing metal material for electronic parts>
As a method for producing a metal material for electronic parts of the present invention, wet (electrical, electroless) plating, dry (sputtering, ion plating, etc.) plating, or the like can be used.
以下、本発明の実施例と比較例を共に示すが、これらは本発明をより良く理解するために提供するものであり、本発明が限定されることを意図するものではない。
実施例、参考例及び比較例として、表1に示す条件で、電解脱脂、酸洗、第1めっき、第2めっき、第3めっき、及び、熱処理の順で表面処理を行った。
Hereinafter, although the Example and comparative example of this invention are shown together, these are provided in order to understand this invention better, and this invention is not intended to be limited.
As examples, reference examples, and comparative examples, surface treatment was performed in the order of electrolytic degreasing, pickling, first plating, second plating, third plating, and heat treatment under the conditions shown in Table 1.
(素材)
(1)板材:厚み0.30mm、幅30mm、成分Cu−30Zn
(2)オス端子:厚み0.64mm、幅2.3mm、成分Cu−30Zn
(3)圧入型端子:常盤商行製、プレスフィット端子PCBコネクタ、R800
(Material)
(1) Plate material: thickness 0.30 mm, width 30 mm, component Cu-30Zn
(2) Male terminal: thickness 0.64 mm, width 2.3 mm, component Cu-30Zn
(3) Press-fit terminal: Tokiwa Shoko, press-fit terminal PCB connector, R800
(第1めっき条件)
(1)半光沢Niめっき
表面処理方法:電気めっき
めっき液:スルファミン酸Niめっき液+サッカリン
めっき温度:55℃
電流密度:0.5〜4A/dm2
(2)光沢Niめっき
表面処理方法:電気めっき
めっき液:スルファミン酸Niめっき液+サッカリン+添加剤
めっき温度:55℃
電流密度:0.5〜4A/dm2
(3)Cuめっき
表面処理方法:電気めっき
めっき液:硫酸Cuめっき液
めっき温度:30℃
電流密度:0.5〜4A/dm2
(4)無光沢Niめっき
表面処理方法:電気めっき
めっき液:スルファミン酸Niめっき液
めっき温度:55℃
電流密度:0.5〜4A/dm2
(5)Ni−Pめっき
表面処理方法:電気めっき
めっき液:スルファミン酸Niめっき液+亜リン酸塩
めっき温度:55℃
電流密度:0.5〜4A/dm2
(First plating condition)
(1) Semi-bright Ni plating Surface treatment method: electroplating plating solution: sulfamic acid Ni plating solution + saccharin plating temperature: 55 ° C
Current density: 0.5-4 A / dm 2
(2) Bright Ni plating Surface treatment method: electroplating Plating solution: sulfamic acid Ni plating solution + saccharin + additive Plating temperature: 55 ° C
Current density: 0.5-4 A / dm 2
(3) Cu plating Surface treatment method: electroplating Plating solution: Cu sulfate plating solution Plating temperature: 30 ° C
Current density: 0.5-4 A / dm 2
(4) Matte Ni plating Surface treatment method: electroplating Plating solution: sulfamic acid Ni plating solution Plating temperature: 55 ° C
Current density: 0.5-4 A / dm 2
(5) Ni-P plating Surface treatment method: electroplating plating solution: sulfamic acid Ni plating solution + phosphite Plating temperature: 55 ° C
Current density: 0.5-4 A / dm 2
(第2めっき条件)
(1)Agめっき
表面処理方法:電気めっき
めっき液:シアン化Agめっき液
めっき温度:40℃
電流密度:0.2〜4A/dm2
(2)Snめっき
表面処理方法:電気めっき
めっき液:メタンスルホン酸Snめっき液
めっき温度:40℃
電流密度:0.5〜4A/dm2
(Second plating condition)
(1) Ag plating Surface treatment method: electroplating Plating solution: Cyanide Ag plating solution Plating temperature: 40 ° C
Current density: 0.2-4 A / dm 2
(2) Sn plating Surface treatment method: Electroplating Plating solution: Methanesulfonic acid Sn plating solution Plating temperature: 40 ° C
Current density: 0.5-4 A / dm 2
(第3めっき条件)
(1)Snめっき条件
表面処理方法:電気めっき
めっき液:メタンスルホン酸Snめっき液
めっき温度:40℃
電流密度:0.5〜4A/dm2
(Third plating condition)
(1) Sn plating conditions Surface treatment method: electroplating plating solution: methanesulfonic acid Sn plating solution Plating temperature: 40 ° C
Current density: 0.5-4 A / dm 2
(熱処理)
熱処理はホットプレートにサンプルを置き、ホットプレートの表面が所定の温度になったことを確認して実施した。
(Heat treatment)
The heat treatment was performed by placing a sample on a hot plate and confirming that the surface of the hot plate reached a predetermined temperature.
(後処理)
実施例25〜40については、実施例1に対し、さらに表面処理液としてリン酸エステル系液を用いて、浸漬による塗布または陽極電解(2V、定電圧電解)を行い、めっき表面に表面処理を行った。このときの表面処理条件は下記の表2に示した。これらの処理の後に、試料を温風により乾燥した。めっき表面に付着するPおよびNの量は、まず付着量既知の数種類の試料を用いてXPS(X線光電子分析法)での定性分析を行ない、P(2s軌道)とN(1s軌道)の検出強度(1秒間に検出されるカウント数)を測定した。次に、この結果をもとに付着量と検出強度の関係を導出し、この関係から未知試料のPとNの付着量を求めた。XPS分析結果の一例を図2に、後処理液成分付着量とXPS検出強度の関係を図3に示す(P付着量=1.1×10-9mol/cm2を1倍、N付着量=7.8×10-11mol/cm2を1倍とする)。
(Post-processing)
For Examples 25 to 40, in addition to Example 1, using a phosphate ester-based liquid as a surface treatment liquid, coating by dip or anodic electrolysis (2 V, constant voltage electrolysis) was performed, and surface treatment was performed on the plating surface. went. The surface treatment conditions at this time are shown in Table 2 below. After these treatments, the sample was dried with warm air. The amount of P and N adhering to the plating surface is first determined by XPS (X-ray photoelectron analysis) using several types of samples with known adhering amounts, and P (2 s orbit) and N (1 s orbit). The detection intensity (the number of counts detected per second) was measured. Next, based on this result, a relationship between the adhesion amount and the detected intensity was derived, and the adhesion amount of P and N of the unknown sample was obtained from this relationship. An example of the XPS analysis result is shown in FIG. 2, and the relationship between the post-treatment liquid component adhesion amount and the detected XPS intensity is shown in FIG. 3 (P adhesion amount = 1.1 × 10 −9 mol / cm 2 , N adhesion amount = 7.8). × 10 -11 mol / cm 2 is multiplied by 1).
(上層及び中層の構造[組成]の決定及び厚み測定)
得られた試料の上層及び中層の構造の決定及び厚み測定は、STEM(走査型電子顕微鏡)分析による線分析で行った。分析した元素は、上層、中層及び下層の組成と、C、S及びOである。これら元素を指定元素とする。また、指定元素の合計を100%として、各元素の濃度(at%)を分析した。厚みは、線分析(または面分析)から求めた距離に対応する。STEM装置は、日本電子株式会社製JEM−2100Fを用いた。本装置の加速電圧は200kVである。
得られた試料の上層及び中層の構造の決定及び厚み測定は、任意の10点について評価を行って平均化した。
(Determination of the structure and composition of upper and middle layers and thickness measurement)
The determination of the structure of the upper layer and the middle layer of the obtained sample and the thickness measurement were performed by line analysis by STEM (scanning electron microscope) analysis. The analyzed elements are upper layer, middle layer and lower layer compositions, C, S and O. These elements are designated elements. Further, the concentration (at%) of each element was analyzed with the total of the designated elements as 100%. The thickness corresponds to the distance obtained from line analysis (or surface analysis). JEM-2100F manufactured by JEOL Ltd. was used as the STEM apparatus. The acceleration voltage of this device is 200 kV.
Determination of the structure of the upper layer and the middle layer of the obtained sample and measurement of the thickness were performed by evaluating 10 points and averaging.
(下層の厚み測定)
下層の厚みは、蛍光X線膜厚計(Seiko Instruments製 SEA5100、コリメータ0.1mmΦ)で測定した。
下層の厚み測定は、任意の10点について評価を行って平均化した。
(Under layer thickness measurement)
The thickness of the lower layer was measured with a fluorescent X-ray film thickness meter (SEA 5100 manufactured by Seiko Instruments, collimator 0.1 mmΦ).
The thickness of the lower layer was averaged by evaluating 10 points.
(評価)
各試料について以下の評価を行った。
A.凝着磨耗
凝着磨耗は、市販のSnリフローめっきメス端子(090型住友TS/矢崎090IIシリーズメス端子非防水/F090−SMTS)を用いてめっきを施したオス端子と挿抜試験することによって評価した。
試験に用いた測定装置は、アイコーエンジニアリング製1311NRであり、オスピンの摺動距離5mmで評価した。サンプル数は5個とし、凝着磨耗は挿入力を用いて評価した。挿入力は、各サンプルの最大値を平均した値を採用した。凝着磨耗のブランク材としては、比較例11のサンプルを採用した。
凝着磨耗の目標は、比較例11の最大挿抜力と比較して85%未満である。これは、比較例3が比較例11の最大挿入力と比較して90%であり、この比較例3よりも、より大きな挿抜力の減少を目標とした。
(Evaluation)
The following evaluation was performed for each sample.
A. Adhesive wear Adhesive wear was evaluated by insertion / extraction testing with a male terminal plated using a commercially available Sn reflow plated female terminal (090 type Sumitomo TS / Yazaki 090II series female terminal non-waterproof / F090-SMTS). .
The measuring device used for the test was 1311NR made by Ikko Engineering, and the evaluation was performed with a male spin sliding distance of 5 mm. The number of samples was 5, and adhesive wear was evaluated using the insertion force. As the insertion force, a value obtained by averaging the maximum values of the respective samples was adopted. As the adhesive wear blank, the sample of Comparative Example 11 was employed.
The adhesion wear target is less than 85% compared to the maximum insertion / extraction force of Comparative Example 11. This is 90% of Comparative Example 3 compared with the maximum insertion force of Comparative Example 11, and aimed to reduce the insertion / extraction force larger than that of Comparative Example 3.
B.ウィスカ
ウィスカは、JEITA RC−5241の荷重試験(球圧子法)にて評価した。すなわち、各サンプルに対して荷重試験を行い、荷重試験を終えたサンプルをSEM(JEOL社製、型式JSM−5410)にて100〜10000倍の倍率で観察して、ウィスカの発生状況を観察した。荷重試験条件を以下に示す。
球圧子の直径:Φ1mm±0.1mm
試験荷重:2N±0.2N
試験時間:120時間
サンプル数:10個
目標とする特性は、長さ20μm以上のウィスカが発生しないことであるが、最大の目標としては、どの長さのウィスカも1本も発生しないことである。
B. Whisker Whisker was evaluated by a load test (ball indenter method) of JEITA RC-5241. That is, a load test was performed on each sample, and the sample after the load test was observed at a magnification of 100 to 10,000 times with a SEM (manufactured by JEOL, model JSM-5410) to observe the occurrence of whiskers. . The load test conditions are shown below.
Diameter of ball indenter: Φ1mm ± 0.1mm
Test load: 2N ± 0.2N
Test time: 120 hours Number of samples: 10 The target characteristic is that whiskers with a length of 20 μm or more are not generated, but the maximum target is that no whisker of any length is generated. .
C.接触抵抗
接触抵抗は、山崎精機研究所製接点シミュレーターCRS−113−Au型を使用し、接点荷重50gの条件で4端子法にて測定した。サンプル数は5個とし、各サンプルの最小値から最大値の範囲を採用した。目標とする特性は、接触抵抗10mΩ以下である。
C. Contact resistance The contact resistance was measured by a 4-terminal method using a contact simulator CRS-113-Au type manufactured by Yamazaki Seiki Laboratories under the condition of a contact load of 50 g. The number of samples was 5, and the range from the minimum value to the maximum value of each sample was adopted. The target characteristic is a contact resistance of 10 mΩ or less.
D.耐熱性
耐熱性は、大気加熱(200℃×1000h)試験後のサンプルの接触抵抗を測定し、評価した。目標とする特性は、接触抵抗10mΩ以下であるが、最大の目標としては、接触抵抗が、耐熱性試験前後で変化がない(同等である)こととした。
D. Heat resistance Heat resistance was evaluated by measuring the contact resistance of a sample after an atmospheric heating (200 ° C. × 1000 h) test. The target characteristic is a contact resistance of 10 mΩ or less, and the maximum target is that the contact resistance does not change before and after the heat resistance test (is equivalent).
E.耐微摺動磨耗性
耐微摺動磨耗性は、山崎精機研究所製精密摺動試験装置CRS−G2050型を使用し、摺動距離0.5mm、摺動速度1mm/s、接触荷重1N、摺動回数500往復条件で摺動回数と接触抵抗との関係を評価した。サンプル数は5個とし、各サンプルの最小値から最大値の範囲を採用した。目標とする特性は、摺動回数100回時に接触抵抗が100mΩ以下である。
E. Fine sliding wear resistance Fine sliding wear resistance is measured using a precision sliding test device CRS-G2050 manufactured by Yamazaki Seiki Laboratories, sliding distance 0.5 mm, sliding speed 1 mm / s, contact load 1 N, The relationship between the number of sliding times and the contact resistance was evaluated under the condition that the number of sliding times was 500. The number of samples was 5, and the range from the minimum value to the maximum value of each sample was adopted. The target characteristic is a contact resistance of 100 mΩ or less when the number of sliding times is 100.
F.はんだ濡れ性
はんだ濡れ性はめっき後のサンプルを評価した。ソルダーチェッカ(レスカ社製SAT−5000)を使用し、フラックスとして市販の25%ロジンメタノールフラックスを用い、メニスコグラフ法にてはんだ濡れ時間を測定した。はんだはSn−3Ag−0.5Cu(250℃)を用いた。サンプル数は5個とし、各サンプルの最小値から最大値の範囲を採用した。目標とする特性は、ゼロクロスタイム5秒(s)以下である。
F. Solder wettability The solder wettability was evaluated on the sample after plating. Solder checker (SAT-5000 manufactured by Reska Co., Ltd.) was used, and a commercially available 25% rosin methanol flux was used as the flux, and the solder wetting time was measured by the meniscograph method. The solder used was Sn-3Ag-0.5Cu (250 ° C.). The number of samples was 5, and the range from the minimum value to the maximum value of each sample was adopted. The target characteristic is a zero cross time of 5 seconds (s) or less.
G.耐ガス腐食性
耐ガス腐食性は、下記の試験環境で評価した。耐ガス腐食性の評価は、環境試験を終えた試験後のサンプルの外観である。なお、目標とする特性は、外観が変色していないことか、実用上問題のない若干の変色である。
硫化水素ガス腐食試験
硫化水素濃度:10ppm
温度:40℃
湿度:80%RH
曝露時間:96h
サンプル数:5個
G. Gas Corrosion Resistance Gas corrosion resistance was evaluated in the following test environment. The evaluation of gas corrosion resistance is the appearance of a sample after a test after an environmental test. The target characteristic is that the appearance is not discolored or is slightly discolored with no practical problem.
Hydrogen sulfide gas corrosion test Hydrogen sulfide concentration: 10ppm
Temperature: 40 ° C
Humidity: 80% RH
Exposure time: 96h
Number of samples: 5
H.機械的耐久性
機械的耐久性は、スルーホール(基板厚2mm、スルーホールΦ1mm)に挿入した圧入型端子をスルーホールから抜き出し、圧入型端子断面をSEM(JEOL社製、型式JSM−5410)にて100〜10000倍の倍率で観察して、粉の発生状況を確認した。粉の直径が5μm未満であるものを○とし、5〜10μm未満であるものを△とし、10μm以上のものを×とした。
H. Mechanical durability Mechanical durability is obtained by extracting the press-fit type terminal inserted into the through hole (substrate thickness 2 mm, through hole Φ1 mm) from the through hole, and making the cross section of the press-fit type terminal into SEM (JEOL, model JSM-5410). Were observed at a magnification of 100 to 10,000 times to confirm the occurrence of powder. A powder having a diameter of less than 5 μm was evaluated as “◯”, a powder having a diameter of less than 5 to 10 μm as “Δ”, and a powder having a diameter of 10 μm or more as “X”.
I.曲げ加工性
曲げ加工性は、W字型の金型を用いて試料の板厚と曲げ半径の比が1となる条件で90°曲げで評価した。評価は曲げ加工部表面を光学顕微鏡で観察し、クラックが観察されない場合の実用上問題ないと判断した場合には○とし、クラックが認められた場合を×とした。なお○と×との区別がつかない場合には△とした。
I. Bending workability The bending workability was evaluated by bending at 90 ° using a W-shaped mold under the condition that the ratio of the plate thickness to the bending radius was 1. In the evaluation, the surface of the bent portion was observed with an optical microscope, and when it was judged that there was no practical problem when no crack was observed, it was evaluated as ◯, and when the crack was observed, it was evaluated as ×. In addition, it was set as △ when it cannot distinguish between ○ and ×.
J.ビッカース硬さ
下層のビッカース硬さは、下層断面より荷重980.7mN(Hv0.1)、荷重保持時間15秒で打根を打って測定した。
J. et al. Vickers hardness The Vickers hardness of the lower layer was measured by hitting the root with a load of 980.7 mN (Hv 0.1) and a load holding time of 15 seconds from the lower layer cross section.
K.押し込み硬さ
上層の押し込み硬さは、超微小硬さ試験(エリオニクス製ENT−2100)により、サンプル表面に荷重10mNで打根を打って測定した。
また、下層の押し込み硬さは、下層断面より荷重10mN(Hv0.1)、荷重保持時間15秒で打根を打って測定した。
K. Indentation hardness The indentation hardness of the upper layer was measured by hitting a root with a load of 10 mN on the sample surface by an ultra-micro hardness test (ENTION 2100 manufactured by Elionix).
Further, the indentation hardness of the lower layer was measured by hitting the root with a load of 10 mN (Hv 0.1) and a load holding time of 15 seconds from the lower layer cross section.
L.表面粗さ
表面粗さ(算術平均高さ(Ra)及び最大高さ(Rz))の測定は、JIS B 0601に準拠し、非接触式三次元測定装置(三鷹光器社製、形式NH−3)を用いて行った。カットオフは0.25mm、測定長さは1.50mmで、1試料当たり5回測定した。
L. Surface Roughness Surface roughness (arithmetic average height (Ra) and maximum height (Rz)) is measured according to JIS B 0601, a non-contact type three-dimensional measuring device (manufactured by Mitaka Kogyo Co., Ltd., model NH- 3). The cut-off was 0.25 mm, the measurement length was 1.50 mm, and measurement was performed 5 times per sample.
M.上層の厚みと上層の最小厚みとの関係
上層の厚みと上層の最小厚みとの関係は、STEM(走査型電子顕微鏡)分析によるHAADF(高角度散乱暗視野)像を用いて評価した。HAADF(高角度散乱暗視野)像の模式図を図4に示す。評価は次のようにして行った。
(1)評価は、倍率50KのHAADF(高角度散乱暗視野)像を用いて、基準長さ3μm/視野とした。
(2)基準長さ3μm/視野の中で上層の最小厚み部位を特定した。また、最小厚み部位が特定しにくい場合には、必要に応じて倍率を高倍率にして特定した。
(3)上層の最小厚みを正確に求めるため、特定した部位より高倍率で観察した。倍率100〜200KのHAADF(高角度散乱暗視野)像を用いて「上層の最小厚み」を正確に求めた。
(4)上述のSTEM(走査型電子顕微鏡)分析による線分析で決定した「上層の厚み(μm)」と「上層の最小厚み(μm)」の関係を、1試料あたり5視野を測定して把握した。
図4は、上記(1)〜(4)の評価方法が理解しやすいように、各層の表面粗さを実測値より誇張して模式的に記載している。
M.M. Relationship between upper layer thickness and minimum upper layer thickness The relationship between upper layer thickness and upper layer minimum thickness was evaluated using a HAADF (high angle scattering dark field) image by STEM (scanning electron microscope) analysis. A schematic diagram of a HAADF (High Angle Scattering Dark Field) image is shown in FIG. Evaluation was performed as follows.
(1) Evaluation was made with a reference length of 3 μm / field using a HAADF (high angle scattering dark field) image with a magnification of 50K.
(2) The minimum thickness portion of the upper layer was specified within a reference length of 3 μm / field of view. Moreover, when it was difficult to specify the minimum thickness part, the magnification was specified as high as necessary.
(3) In order to accurately determine the minimum thickness of the upper layer, observation was performed at a higher magnification than the identified portion. The “minimum thickness of the upper layer” was accurately determined using a HAADF (high angle scattering dark field) image with a magnification of 100 to 200K.
(4) The relationship between the “upper layer thickness (μm)” and the “minimum upper layer thickness (μm)” determined by the line analysis by the above-mentioned STEM (scanning electron microscope) analysis was performed by measuring five visual fields per sample. I figured it out.
FIG. 4 schematically shows the surface roughness of each layer exaggerated from the actual measurement values so that the evaluation methods (1) to (4) can be easily understood.
N.上層の厚みと、上層と中層との界面プロフィールの隣り合う山と谷の高低差の最大値との関係
上層の厚みと、上層と中層との界面プロフィールの隣り合う山と谷の高低差の最大値との関係は、STEM(走査型電子顕微鏡)分析によるHAADF(高角度散乱暗視野)像を用いて評価した。HAADF(高角度散乱暗視野)像の模式図を図4に示す。評価は次のようにして行った。
(1)評価は、倍率50KのHAADF(高角度散乱暗視野)像を用いて、基準長さ3μm/視野とした。
(2)基準長さ3μm/視野の中で上層と中層との界面プロフィールの隣り合う山と谷の高低差の最大値部位を特定した。また、上層と中層との界面プロフィールの隣り合う山と谷の高低差の最大値部位が特定しにくい場合には必要に応じて倍率を高倍率にして特定した。
(3)上層と中層との界面プロフィールの隣り合う山と谷の高低差の最大値部位を正確に求めるため、特定した部位より高倍率で観察した。倍率100〜200KのHAADF(高角度散乱暗視野)像を用いて「上層と中層との界面プロフィールの隣り合う山と谷の高低差」を正確に求めた。
(4)上述のSTEM(走査型電子顕微鏡)分析による線分析で決定した「上層の厚み(μm)」と「上層と中層との界面プロフィールの隣り合う山と谷の高低差(μm)」の関係を、1試料あたり5視野を測定して把握した。
図4は、上記(1)〜(4)の評価方法が理解しやすいように、各層の表面粗さを実測値より誇張して模式的に記載している。
上記試験条件及び試験結果を下記の表に示す。下記表において、「組成」はそれぞれ原子濃度(at%)の比を示す。
N. The relationship between the upper layer thickness and the maximum height difference between adjacent peaks and valleys in the interface profile between the upper layer and middle layer The upper layer thickness and the maximum difference in height between adjacent peaks and valleys in the interface profile between the upper layer and middle layer The relationship with the value was evaluated using a HAADF (high angle scattering dark field) image by STEM (scanning electron microscope) analysis. A schematic diagram of a HAADF (High Angle Scattering Dark Field) image is shown in FIG. Evaluation was performed as follows.
(1) Evaluation was made with a reference length of 3 μm / field using a HAADF (high angle scattering dark field) image with a magnification of 50K.
(2) In the reference length of 3 μm / field of view, the maximum value portion of the height difference between adjacent peaks and valleys of the interface profile between the upper layer and the middle layer was specified. Moreover, when it was difficult to specify the maximum value part of the height difference between the adjacent peaks and valleys of the interface profile between the upper layer and the middle layer, the magnification was specified as high as necessary.
(3) In order to accurately determine the maximum value portion of the height difference between the adjacent peaks and valleys of the interface profile between the upper layer and the middle layer, observation was performed at a higher magnification than the specified portion. Using a HAADF (high angle scattering dark field) image with a magnification of 100 to 200K, the “height difference between adjacent peaks and valleys in the interface profile between the upper layer and the middle layer” was accurately determined.
(4) The “upper layer thickness (μm)” and “height difference between adjacent peaks and valleys of the interface profile between the upper layer and the middle layer (μm)” determined by the line analysis by the above-mentioned STEM (scanning electron microscope) analysis The relationship was grasped by measuring 5 fields per sample.
FIG. 4 schematically shows the surface roughness of each layer exaggerated from the actual measurement values so that the evaluation methods (1) to (4) can be easily understood.
The test conditions and test results are shown in the following table. In the following table, “composition” indicates the ratio of atomic concentration (at%).
A1:ラウリル酸性リン酸モノエステル(リン酸モノラウリルエステル)
A2:ラウリル酸性リン酸ジエステル(リン酸ジラウリルエステル)
B1:ベンゾトリアゾール
B2:メルカプトベンゾチアゾールのNa塩
B3:トリルトリアゾール
A1: Lauryl acid phosphate monoester (phosphate monolauryl ester)
A2: Lauryl acid phosphate diester (phosphate dilauryl ester)
B1: Benzotriazole B2: Mercaptobenzothiazole Na salt B3: Tolyltriazole
実施例1〜41は、低ウィスカ性、低凝着磨耗性及び高耐久性のいずれも優れた電子部品金属材料であった。
参考例1は、上層のAg:Snが3:7であり、実施例1と比較すると上層のSnの割合が多いため、目標とする特性は得られたものの、長さ20μm以上のウィスカは発生しなかったものの、長さ20μm未満のウィスカが発生する場合があった。
参考例2は、中層のSn:Niが3:7であり、実施例1と比較すると中層のNiの割合が多いため、目標とする特性は得られたものの、実施例1と比較して曲げ加工性が若干悪かった。
参考例3は、上層の厚みが0.90μmであり、目標とする特性は得られたものの、実施例1と比較すると上層の厚みが厚く、実施例1と比較して機械的耐久性が若干悪かった。
参考例4は、上層と下層の厚みの比が上層:下層=1:3であり下層の割合が多いため、目標とする特性は得られたものの、耐熱性、耐微摺動磨耗性、はんだ濡れ性及び耐ガス腐食性が実施例と比較すると若干悪かった。
参考例5は、上層の超微小硬さ、下層の超微小硬さ及びビッカース硬さが実施例1と比較して硬いため、目標とする特性は得られたものの、曲げ加工性が悪かった。
参考例6は、最表層の最小厚みが最表層の厚みの50%未満であり、目標とする特性は得られたものの、耐熱性、はんだ濡れ性、耐ガス腐食性が実施例よりも悪かった。
参考例7は、最表層と上層との界面プロフィールの隣り合う山と谷の高低差の最大値が、最表層の厚みの50%を超えたため、目標とする特性は得られたものの、耐熱性、はんだ濡れ性、耐ガス腐食性が実施例よりも悪かった。
参考例8は、上層の表面に、B構成元素の合計原子濃度(at%)≧C構成元素の合計原子濃度(at%)であり、Oの原子濃度(at%)≧10at%である領域が0.02μmを超えて存在するため、目標とする特性は得られたものの、耐熱性、はんだ濡れ性が実施例よりも悪かった。
参考例9は、上層の厚みが0.03μmと実施例よりも薄かったため、目標とする特性は得られたものの、耐熱性、はんだ濡れ性、耐ガス腐食性が実施例よりも悪かった。
比較例1は、上層の厚みが目標よりも薄かったため、耐熱性、耐微摺動磨耗性、はんだ濡れ性及び耐ガス腐食性が悪かった。
比較例2は、上層の厚みが目標よりも厚かったため、凝着磨耗が多いために挿入力が高く、機械的磨耗性が悪かった。
比較例3は、上層がβSn単独で存在したため、長さ20μm以上のウィスカが発生してしまい、凝着磨耗が多いために挿入力も高く、耐熱性及び耐微摺動磨耗性が悪かった。
比較例4は、中層の厚みが目標よりも薄かったため凝着磨耗が多いために挿入力が高かった。
比較例5は、中層の厚みが目標よりも厚かったため、機械的磨耗性や曲げ加工性が悪かった。
比較例6は、下層の厚みが目標よりも薄かったため、凝着磨耗が多いために挿入力が高く、耐熱性及びはんだ濡れ性が悪かった。
比較例7は、下層の厚みが目標よりも厚かったため、曲げ加工性が悪かった。
比較例8〜9は、上層に占めるAgの割合が高いため、耐ガス腐食性が悪かった。
比較例11は、本発明のブランク材である。長さ20μm以上のウィスカが発生してしまい、耐熱性や耐微摺動磨耗性が悪かった。
また、図5に本発明の実施形態に係るSTEM(走査型電子顕微鏡)の線分析結果を示す。図5より、最表面からAgSn合金が0.3μmの厚みで、SnNi合金が0.07μmの厚みで存在することがわかる。さらに、AgSn合金の組成(at%)が、Ag:Sn=8:2であり、図6のAgSn状態図よりAgSn合金はβSnは存在せず、SnAg合金のζ相(Sn11.8〜22.9%)とε相(Ag3Sn)が存在することが分かる。またSnNi合金の組成(at%)が、Sn:Ni=7:3であり、図7のSnNi状態図よりSnNi合金のNi3Sn4とβSnが存在することが分かる。
Examples 1-41 were electronic component metal materials excellent in all of low whisker properties, low adhesion wear properties, and high durability.
In Reference Example 1, Ag: Sn in the upper layer is 3: 7, and the ratio of Sn in the upper layer is larger than that in Example 1. Therefore, although target characteristics were obtained, whiskers with a length of 20 μm or more were generated. In some cases, whiskers having a length of less than 20 μm were generated.
In Reference Example 2, Sn: Ni in the middle layer is 3: 7, and since the ratio of Ni in the middle layer is larger than that in Example 1, the target characteristics are obtained, but bending is performed in comparison with Example 1. The processability was slightly bad.
In Reference Example 3, the thickness of the upper layer was 0.90 μm, and the target characteristics were obtained, but the thickness of the upper layer was thicker than that of Example 1, and the mechanical durability was slightly higher than that of Example 1. It was bad.
In Reference Example 4, the ratio of the thickness of the upper layer to the lower layer is upper layer: lower layer = 1: 3, and the ratio of the lower layer is large, so the target characteristics were obtained, but heat resistance, anti-sliding wear resistance, solder The wettability and gas corrosion resistance were slightly worse compared to the examples.
In Reference Example 5, the ultrafine hardness of the upper layer, the ultrafine hardness of the lower layer, and the Vickers hardness are harder than those of Example 1, so that the target characteristics were obtained, but the bending workability was poor. It was.
In Reference Example 6, the minimum thickness of the outermost layer was less than 50% of the thickness of the outermost layer, and the target characteristics were obtained, but the heat resistance, solder wettability, and gas corrosion resistance were worse than the examples. .
In Reference Example 7, the maximum value of the height difference between adjacent peaks and valleys in the interface profile between the outermost layer and the upper layer exceeded 50% of the thickness of the outermost layer, so that the target characteristics were obtained, but the heat resistance The solder wettability and gas corrosion resistance were worse than those of the examples.
In Reference Example 8, the total atomic concentration of B constituent elements (at%) ≧ the total atomic concentration of C constituent elements (at%) and the atomic concentration of O (at%) ≧ 10 at% on the surface of the upper layer However, although the target characteristics were obtained, the heat resistance and solder wettability were worse than those of the examples.
In Reference Example 9, the thickness of the upper layer was 0.03 μm, which was thinner than that of the example. Therefore, although target characteristics were obtained, the heat resistance, solder wettability, and gas corrosion resistance were worse than those of the example.
In Comparative Example 1, since the thickness of the upper layer was thinner than the target, the heat resistance, the fine sliding wear resistance, the solder wettability, and the gas corrosion resistance were poor.
In Comparative Example 2, since the thickness of the upper layer was thicker than the target, there was much adhesion wear, so the insertion force was high and the mechanical wearability was poor.
In Comparative Example 3, since the upper layer was formed of βSn alone, whiskers having a length of 20 μm or more were generated, and since there was much adhesion wear, the insertion force was high, and the heat resistance and fine sliding wear resistance were poor.
In Comparative Example 4, since the thickness of the middle layer was thinner than the target, there was much adhesive wear, so the insertion force was high.
In Comparative Example 5, since the thickness of the middle layer was thicker than the target, mechanical wear and bending workability were poor.
In Comparative Example 6, since the thickness of the lower layer was thinner than the target, there was much adhesion wear, so the insertion force was high , and the heat resistance and solder wettability were poor.
In Comparative Example 7, since the thickness of the lower layer was thicker than the target, bending workability was poor.
In Comparative Examples 8 to 9 , since the ratio of Ag in the upper layer was high, the gas corrosion resistance was poor.
Comparative Example 11 is a blank material of the present invention. Whisker having a length of 20 μm or more was generated, and heat resistance and fine sliding wear resistance were poor.
FIG. 5 shows a line analysis result of a STEM (scanning electron microscope) according to the embodiment of the present invention. From FIG. 5, it can be seen that the AgSn alloy is present at a thickness of 0.3 μm and the SnNi alloy is present at a thickness of 0.07 μm from the outermost surface. Further, the composition (at%) of the AgSn alloy is Ag: Sn = 8: 2, and from the AgSn phase diagram of FIG. 6, there is no βSn in the AgSn alloy, and the ζ phase (Sn 11.8-22.Sn) of the SnAg alloy. 9%) and ε phase (Ag 3 Sn). Further, the composition (at%) of the SnNi alloy is Sn: Ni = 7: 3, and it can be seen from the SnNi phase diagram of FIG. 7 that Ni 3 Sn 4 and βSn of the SnNi alloy exist.
10 電子部品用金属材料
11 基材
12 下層
13 中層
14 上層
DESCRIPTION OF SYMBOLS 10 Metal material for electronic components 11 Base material 12 Lower layer 13 Middle layer 14 Upper layer
Claims (49)
前記基材上に形成された、Ni、Cr、Mn、Fe、Co及びCuからなる群であるA構成元素群から選択された1種又は2種以上で構成された下層と、
前記下層上に形成された、前記A構成元素群から選択された1種又は2種以上と、Sn及びInからなる群であるB構成元素群から選択された1種又は2種とで構成された中層と、
前記中層上に形成された、前記B構成元素群から選択された1種又は2種と、Ag、Au、Pt、Pd、Ru、Rh、Os及びIrからなる群であるC構成元素群から選択された1種又は2種類以上との合金で構成された上層と、
を備え、
前記下層の厚みが0.05μm以上5.00μm未満であり、
前記中層の厚みが0.01μm以上0.40μm未満であり、
前記上層の厚みが0.02μm以上1.00μm未満である電子部品用金属材料。
A substrate;
A lower layer composed of one or more selected from the group consisting of Ni, Cr, Mn, Fe, Co and Cu, which is a group consisting of A constituent elements, formed on the substrate;
It is composed of one or more selected from the A constituent element group formed on the lower layer and one or two selected from the B constituent element group which is a group consisting of Sn and In. The middle layer,
One or two selected from the B constituent element group formed on the middle layer and a C constituent element group that is a group consisting of Ag, Au, Pt, Pd, Ru, Rh, Os, and Ir An upper layer composed of an alloy of one kind or two or more kinds,
With
The thickness of the lower layer is 0.05 μm or more and less than 5.00 μm,
The middle layer has a thickness of 0.01 μm or more and less than 0.40 μm,
Metal material for electronic parts the upper layer of thickness Ru 1.00μm less der than 0.02 [mu] m.
前記基材上に前記A構成元素群から選択された1種又は2種以上を成膜し、その後、前記C構成元素群から選択された1種又は2種を成膜し、その後、前記B構成元素群から選択された1種又は2種類以上を成膜し、前記A構成元素群、前記B構成元素群及び前記C構成元素群の各元素が拡散することでそれぞれ形成されている請求項1〜20のいずれかに記載の電子部品用金属材料。 The upper layer, the middle layer and the lower layer are
One or more selected from the A constituent element group is formed on the substrate, and then one or two selected from the C constituent element group is formed, and then the B The film is formed by depositing one kind or two or more kinds selected from a constituent element group, and each element of the A constituent element group, the B constituent element group, and the C constituent element group is diffused. The metal material for electronic components in any one of 1-20.
前記基材上に形成された、Ni、Cr、Mn、Fe、Co及びCuからなる群であるA構成元素群から選択された1種又は2種以上で構成された下層と、
前記下層上に形成された、前記A構成元素群から選択された1種又は2種以上と、Sn及びInからなる群であるB構成元素群から選択された1種又は2種とで構成された中層と、
前記中層上に形成された、前記B構成元素群から選択された1種又は2種と、Ag、Au、Pt、Pd、Ru、Rh、Os及びIrからなる群であるC構成元素群から選択された1種又は2種類以上との合金で構成された上層と、
を備えた金属材料の表面に、下記一般式〔1〕および〔2〕で表されるリン酸エステルの少なくとも1種と、下記一般式〔3〕および〔4〕で表される環状有機化合物群から選択される少なくとも1種とを含有するリン酸エステル系液で表面処理する請求項35〜38のいずれかに記載の電子部品用金属材料の製造方法。
A lower layer composed of one or more selected from the group consisting of Ni, Cr, Mn, Fe, Co and Cu, which is a group consisting of A constituent elements, formed on the substrate;
It is composed of one or more selected from the A constituent element group formed on the lower layer and one or two selected from the B constituent element group which is a group consisting of Sn and In. The middle layer,
One or two selected from the B constituent element group formed on the middle layer and a C constituent element group that is a group consisting of Ag, Au, Pt, Pd, Ru, Rh, Os, and Ir An upper layer composed of an alloy of one kind or two or more kinds,
On the surface of a metal material provided with at least one of the phosphoric acid esters represented by the following general formulas [1] and [2], and a cyclic organic compound group represented by the following general formulas [3] and [4] The method for producing a metal material for electronic parts according to any one of claims 35 to 38, wherein the surface treatment is performed with a phosphate ester-based liquid containing at least one selected from the group consisting of:
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