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JP2008182171A - Solder-plated wire for solar cell and manufacturing method thereof, and solar cell - Google Patents

Solder-plated wire for solar cell and manufacturing method thereof, and solar cell Download PDF

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JP2008182171A
JP2008182171A JP2007071755A JP2007071755A JP2008182171A JP 2008182171 A JP2008182171 A JP 2008182171A JP 2007071755 A JP2007071755 A JP 2007071755A JP 2007071755 A JP2007071755 A JP 2007071755A JP 2008182171 A JP2008182171 A JP 2008182171A
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solder
wire
copper
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solar cell
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Masayoshi Aoyama
正義 青山
Hirohisa Endo
裕寿 遠藤
Hiroshi Okikawa
寛 沖川
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Hitachi Cable Ltd
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Abstract

<P>PROBLEM TO BE SOLVED: To provide a low-cost solder-plated wire for a solar cell that has a strength lower by 0.2% as compared with a conventional solder-plated wire for a solar cell with tough-pitch copper (TPC) as a conductive material and has 0.2% strength equal to or lower than that of the conventional solder-plated wire for a solar cell with oxygen-free copper (OFC) as a conductor material, to provide a method of manufacturing the solder-plated wire for a solar cell, and to provide the solar cell. <P>SOLUTION: In the solder-plated wire 2 for a solar cell, the surface of a conductor 3 of which a section is formed in a flat-square shape is covered with solder plating 4 partially or wholly for joint to the solar cell 1. In this case, the conductor 3 is made of copper, and a copper material that is an inevitable impurity. The copper contains a sulfur affinity metal of one kind or not less than one kind selected from Nb, Ti, Zr, V, Ta, Fe, Ca, Mg, or Ni and has oxygen content exceeding 10 massppm at the remaining section. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

本発明は、太陽電池用接続リード線及びその製造方法に係り、特に、太陽電池のシリコンセルとはんだ接続するのに好適な太陽電池用はんだめっき線及びその製造方法並びに太陽電池に関するものである。   The present invention relates to a solar cell connection lead wire and a manufacturing method thereof, and more particularly to a solar cell solder plating wire suitable for solder connection with a silicon cell of a solar cell, a manufacturing method thereof, and a solar cell.

一般的な太陽電池セルは、受光面を持ち、かつ平板形状をしており、その受光面(上面)と相対する面(下面)とにそれぞれ電極が形成された構造を有している。複数の太陽電池セルを接続するための接続用リード線は、平角状の銅箔などからなり、図2に示すように、接続用リード線2の一方端が太陽電池セル1の受光面(上面)に、その他方端が太陽電池セル1の受光面と相対する面(下面)に、ハンダなどを用いて接続され、通常、複数の太陽電池セル1が直列に接続されている。図3に示すように、この接続用リード線2は、平角導体3の表面に、太陽電池セルとの接続のためのはんだめっき4が形成されている。   A general solar battery cell has a light receiving surface and a flat plate shape, and has a structure in which electrodes are formed on a surface (lower surface) opposite to the light receiving surface (upper surface). A connection lead wire for connecting a plurality of solar cells is made of a rectangular copper foil or the like. As shown in FIG. 2, one end of the connection lead wire 2 is a light receiving surface (upper surface) of the solar cell 1. The other end is connected to the surface (lower surface) facing the light receiving surface of the solar battery cell 1 using solder or the like, and usually a plurality of solar battery cells 1 are connected in series. As shown in FIG. 3, the connecting lead wire 2 is formed with a solder plating 4 on the surface of a flat conductor 3 for connection with a solar battery cell.

ところで、太陽電池を構成する部材のうち、シリコン結晶ウェハ(太陽電池セル)が材料コストの大半を占めていることから、製造コストの低減を図るべくシリコン結晶ウェハの薄板化が進んでいる。しかし、シリコン結晶ウェハを薄板化すると、図4(a)に示す接続用リード線2のはんだ接合時における加熱プロセスや、太陽電池使用時における温度変化により、図4(b)に示すように、接続用リード線2をはんだ接続した太陽電池セル1全体が反って、破損したりするおそれがある。   By the way, since the silicon crystal wafer (solar cell) occupies most of the material cost among the members constituting the solar cell, the silicon crystal wafer is being made thinner in order to reduce the manufacturing cost. However, when the silicon crystal wafer is thinned, as shown in FIG. 4B, due to the heating process at the time of soldering the connecting lead wire 2 shown in FIG. The entire solar battery cell 1 to which the connecting lead wire 2 is soldered may be warped and damaged.

このような太陽電池セルの反りおよび破損を防止するため、近年では、シリコン結晶ウェハとの熱膨張係数の差が小さい導電性材料を、接続用リード線として用いるようになってきている。このような材料としては、銅層とコバール層と銅層を備えた3層クラッド材、又は銅層とインバー層と銅層を備えた3層クラッド材があり、さらにそれらの外周を略全体にわたってはんだめっきした材料が知られている(例えば、特許文献1)。   In order to prevent such warpage and damage of the solar battery cell, in recent years, a conductive material having a small difference in thermal expansion coefficient from that of a silicon crystal wafer has been used as a connecting lead wire. As such a material, there are a three-layer clad material provided with a copper layer, a kovar layer, and a copper layer, or a three-layer clad material provided with a copper layer, an invar layer, and a copper layer, and the outer periphery thereof is substantially entirely covered. A solder-plated material is known (for example, Patent Document 1).

しかしながら、前記特許文献1に記載された3層クラッド材を接続用リード線として使用する場合には、太陽電池セルに生じる熱応力を軽減することができるものの、体積抵抗率が比較的高いコバール層やインバー層を中間層として使用するため、平均の電気抵抗が高くなり、太陽電池の発電効率が低下するという問題がある。   However, when the three-layer clad material described in Patent Document 1 is used as a connecting lead wire, the thermal stress generated in the solar cell can be reduced, but the Kovar layer having a relatively high volume resistivity. In addition, since the invar layer is used as an intermediate layer, there is a problem that the average electric resistance is increased and the power generation efficiency of the solar cell is lowered.

このような事情に鑑み、体積抵抗率が2.3μΩ・cm以下で、かつ耐力が19.6〜85MPaであり、酸素含有量が20massppm以下の純銅からなる焼鈍材で構成された芯材の表面に、溶融はんだめっき層を備えた太陽電池用電極線材が検討されている(例えば、特許文献2)。   In view of such circumstances, the surface of a core material made of an annealed material made of pure copper having a volume resistivity of 2.3 μΩ · cm or less, a proof stress of 19.6 to 85 MPa, and an oxygen content of 20 massppm or less. In addition, a solar cell electrode wire having a molten solder plating layer has been studied (for example, Patent Document 2).

太陽電池用接続リード線のCuの種類として、タフピッチ銅、無酸素Cu、高純度銅(純度99.9999%以上)などが考えられるが、発明者らの検討によると、導体の引張り試験における0.2%耐力を最も小さくするためには、純度が高いCuが有利であることがわかっており、その候補としては、無酸素Cu、高純度銅(純度99.9999%以上)が挙げられる(特許文献3)。   As the types of Cu in the connection lead wires for solar cells, tough pitch copper, oxygen-free Cu, high-purity copper (purity 99.9999% or more), and the like are considered. It has been found that Cu having a high purity is advantageous for minimizing the 2% proof stress, and examples thereof include oxygen-free Cu and high-purity copper (purity of 99.9999% or more) ( Patent Document 3).

特開2006−73706号公報JP 2006-73706 A 国際公開第2005/114751号パンフレットInternational Publication No. 2005/114751 Pamphlet 特開2006−276709号公報JP 2006-276709 A

無酸素Cu、高純度銅(純度99.9999%以上)を用いて太陽電池用接続リード線を連続鋳造装置により製造する場合には、その製造過程において、銅母材を脱酸する工程などが必要になり、その制御など製造工程が煩雑になり、また、高純度銅等を無酸化保護ガス(CO)中で連続溶解鋳造する大規模な設備を要するなど、製造費用がかかってしまうという課題がある。   When manufacturing connection lead wires for solar cells using a continuous casting apparatus using oxygen-free Cu and high-purity copper (purity 99.9999% or more), a step of deoxidizing the copper base material in the manufacturing process, etc. The manufacturing process such as the control becomes complicated, and the manufacturing cost is high, such as requiring large-scale equipment for continuous melting and casting of high-purity copper in non-oxidation protective gas (CO). There is.

このため、タフピッチ銅などの酸素含有量が比較的多く、工業的に取り扱い易く、かつ安価な銅材料を出発材料としつつ、少なくとも無酸素Cuと同等またはそれ以上の良好な軟化特性を有する銅材の開発、検討が急がれている。   For this reason, a copper material having a relatively soft oxygen characteristic such as tough pitch copper, which has a relatively large oxygen content, is industrially easy to handle and inexpensive, and at least equal to or more than oxygen-free Cu. The development and examination of is urgently needed.

本発明の目的は、タフピッチ銅(TPC)を導体材料とした従来の太陽電池用はんだめっき線よりも0.2%耐力が低く、無酸素銅(OFC)を導体材料とした従来の太陽電池用はんだめっき線と同等又はそれ以下の0.2%耐力を備え、かつ低コストである太陽電池用はんだめっき線及びその製造方法並びに太陽電池を提供することにある。   An object of the present invention is 0.2% lower in proof stress than a conventional solder-plated wire for solar cells using tough pitch copper (TPC) as a conductive material, and for conventional solar cells using oxygen-free copper (OFC) as a conductive material. An object of the present invention is to provide a solar cell solder plated wire having a 0.2% proof stress equal to or lower than that of a solder plated wire and a low cost, a manufacturing method thereof, and a solar cell.

上記の目的を達成するために、請求項1の発明は、太陽電池セルに接合すべく、断面平角状に形成された導体の表面の一部又は全部にはんだめっきが被覆された太陽電池用はんだめっき線において、
上記導体を、Nb、Ti、Zr、V、Ta、Fe、Ca、Mg又はNiから選択される1種又は2種以上の硫黄親和性金属を含有し、残部が酸素含有量が10massppmを超える銅及び不可避的不純物である銅材で構成したことを特徴とする太陽電池用はんだめっき線である。
In order to achieve the above object, the invention of claim 1 is a solar battery solder in which a solder plating is coated on a part or all of the surface of a conductor having a rectangular cross section so as to be joined to a solar battery cell. In plated wire,
Copper containing one or more sulfur-affinity metals selected from Nb, Ti, Zr, V, Ta, Fe, Ca, Mg, or Ni, with the remainder having an oxygen content of more than 10 massppm And it is comprised with the copper material which is an unavoidable impurity, It is the solder plating wire for solar cells characterized by the above-mentioned.

請求項2の発明は、上記導体が、上記硫黄親和性金属を0.0007〜0.04質量%含有する請求項1記載の太陽電池用はんだめっき線である。   The invention according to claim 2 is the solder plated wire for a solar cell according to claim 1, wherein the conductor contains 0.0007 to 0.04 mass% of the sulfur affinity metal.

請求項3の発明は、上記導体の結晶粒径が270μm以下である請求項1又は2記載の太陽電池用はんだめっき線である。   The invention according to claim 3 is the solder plated wire for a solar cell according to claim 1 or 2, wherein the conductor has a crystal grain size of 270 µm or less.

請求項4の発明は、請求項1から3いずれかに記載の太陽電池用はんだめっき線と、太陽電池セルをはんだ接続したことを特徴とする太陽電池である。   A fourth aspect of the present invention is a solar battery characterized in that the solar cell solder-plated wire according to any one of the first to third aspects and a solar battery cell are solder-connected.

請求項5の発明は、連続鋳造圧延装置を用いて、銅溶湯から太陽電池用はんだめっき線を製造する方法であって、
上記連続鋳造圧延装置の溶湯貯溜手段に貯溜され、酸素含有量が10massppmを超える銅溶湯に、Nb、Ti、Zr、V、Ta、Fe、Ca、Mg又はNiから選択される1種又は2種以上の硫黄親和性金属を添加し、銅溶湯中に含まれる該硫黄親和性金属の割合を0.0007〜0.04質量%に調整し、その銅溶湯を用いて荒引き材を製造した後、その荒引き材に減面率30%以上の冷間伸線加工を施し、この冷間加工材に190〜750℃で熱処理を施すことを特徴とする太陽電池用はんだめっき線の製造方法である。
The invention of claim 5 is a method of producing a solar cell solder-plated wire from a molten copper using a continuous casting and rolling apparatus,
One or two kinds selected from Nb, Ti, Zr, V, Ta, Fe, Ca, Mg, or Ni in the molten copper stored in the molten metal storage means of the continuous casting and rolling apparatus and having an oxygen content exceeding 10 massppm. After adding the above sulfur-affinity metal, adjusting the ratio of the sulfur-affinity metal contained in the molten copper to 0.0007 to 0.04 mass%, and manufacturing the roughing material using the molten copper A method for producing a solder-plated wire for a solar cell, characterized in that the roughing material is subjected to cold drawing with a reduction in area of 30% or more, and the cold-worked material is subjected to heat treatment at 190 to 750 ° C. is there.

請求項6の発明は、上記冷間加工材に、400〜750℃で熱処理を施す請求項5記載の太陽電池用はんだめっき線の製造方法である。   Invention of Claim 6 is a manufacturing method of the solder plating wire for solar cells of Claim 5 which heat-processes at 400-750 degreeC to the said cold work material.

請求項7の発明は、上記熱処理を、ヒータによるバッチ式加熱方式もしくは通電加熱方式により行う請求項5又は6記載の太陽電池用はんだめっき線の製造方法である。   The invention according to claim 7 is the method for producing a solder-plated wire for a solar cell according to claim 5 or 6, wherein the heat treatment is performed by a batch-type heating method or a current heating method using a heater.

本発明の太陽電池用はんだめっき線によれば、タフピッチ銅(TPC)を導体材料とした従来の太陽電池用はんだめっき線よりも0.2%耐力が低く、無酸素銅(OFC)を導体材料とした従来の太陽電池用はんだめっき線と同等又はそれ以下の0.2%耐力を実現でき、かつ、低コストで製造可能である。   According to the solder plated wire for solar cell of the present invention, 0.2% lower proof stress than conventional solder plated wire for solar cell using tough pitch copper (TPC) as a conductor material, and oxygen free copper (OFC) as a conductor material. Thus, 0.2% proof stress equivalent to or lower than that of the conventional solder plated wire for solar cells can be realized, and can be manufactured at low cost.

以下、本発明の実施の形態を添付図面に基いて説明する。   Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

(太陽電池用はんだめっき線)
本発明の好適一実施の形態に係る太陽電池用はんだめっき線は、図3に示すように、導体3の表面全体に、はんだめっき4を施したものである。この導体3は、Nb、Ti、Zr、V、Ta、Fe、Ca、Mg又はNiから選択される1種又は2種以上の硫黄親和性金属を含有し、残部が酸素含有量が10massppmを超える銅及び不可避的不純物である銅材で構成されるものである。導体3は、硫黄親和性金属を0.0007〜0.04質量%の割合で含有する。この含有量の範囲内であれば、硫黄親和性金属に加えてミッシュメタル(MM)を添加してもよい。
(Solder plating wire for solar cells)
The solar cell solder-plated wire according to a preferred embodiment of the present invention is obtained by applying solder plating 4 to the entire surface of the conductor 3, as shown in FIG. This conductor 3 contains one or more sulfur-affinity metals selected from Nb, Ti, Zr, V, Ta, Fe, Ca, Mg, or Ni, and the remainder has an oxygen content exceeding 10 massppm. It is composed of copper and a copper material that is an inevitable impurity. The conductor 3 contains a sulfur affinity metal in a proportion of 0.0007 to 0.04 mass%. Within this content range, misch metal (MM) may be added in addition to the sulfur-affinity metal.

導体3の結晶粒径は270μm以下、導体3の0.2%耐力は23〜66MPaとされる。また、この導体3にはんだめっき4を被覆した太陽電池用はんだめっき線2全体の0.2%耐力は、43〜86MPaとされる。   The crystal grain size of the conductor 3 is 270 μm or less, and the 0.2% proof stress of the conductor 3 is 23 to 66 MPa. Moreover, the 0.2% yield strength of the entire solar cell solder-plated wire 2 in which the conductor 3 is coated with the solder plating 4 is 43 to 86 MPa.

導体3の被覆に用いるはんだめっき4は、環境面から、好ましくは鉛フリー品とされ、Sn系はんだ、あるいは第2成分としてPb、In、Bi、Sb、Ag、Zn、Ni、Cuから選択される少なくとも1種の元素を0.1mass%以上含むSn系合金はんだが挙げられる。このSn系はんだ、あるいはSn系合金はんだは、それぞれ、第3成分として1000massppm以下の微量元素を含んでいてもよい。また、はんだめっき4の被覆は、導体3の一部、例えば、導体の上下面のみであってもよい。   The solder plating 4 used for covering the conductor 3 is preferably a lead-free product from an environmental point of view, and is selected from Sn-based solder or Pb, In, Bi, Sb, Ag, Zn, Ni, Cu as the second component. Sn-based alloy solder containing 0.1 mass% or more of at least one element. Each of the Sn-based solder or the Sn-based alloy solder may contain a trace element of 1000 massppm or less as a third component. Further, the coating of the solder plating 4 may be a part of the conductor 3, for example, only the upper and lower surfaces of the conductor.

本実施の形態に係る太陽電池用はんだめっき線2における導体3の酸素含有量、は、特に限定するものではないが、例えば、10massppmを超え、400massppm以内の範囲が想定される。後述する実施例では、導体3の原材料として特にタフピッチ銅などの汎用材料を使用していることから、10massppmを超え、より正確には150massppm〜400massppm程度であるが、無酸素銅、高純度銅(6N)などと同等の特性を得るという観点からすると、本実施の形態に係る太陽電池用はんだめっき線2における導体3の好ましい酸素含有量は150massppm以下、より好ましくは10massppm〜50massppmとされる。   The oxygen content of the conductor 3 in the solar cell solder-plated wire 2 according to the present embodiment is not particularly limited, but for example, a range exceeding 10 massppm and within 400 massppm is assumed. In the examples to be described later, since a general-purpose material such as tough pitch copper is used as the raw material of the conductor 3, it exceeds 10 massppm, more precisely, about 150 massppm to 400 massppm, but oxygen-free copper, high-purity copper ( From the viewpoint of obtaining characteristics equivalent to 6N) and the like, the preferable oxygen content of the conductor 3 in the solar cell solder-plated wire 2 according to the present embodiment is 150 massppm or less, and more preferably 10 massppm to 50 massppm.

この太陽電池用はんだめっき線2を、図2に示したシリコン結晶ウェハ1(太陽電池モジュール)におけるシリコンセル面の所定の接点領域(例えば、Agメッキ領域)に接続することで、太陽電池アセンブリが得られる。   By connecting this solar cell solder-plated wire 2 to a predetermined contact region (for example, an Ag plating region) on the silicon cell surface of the silicon crystal wafer 1 (solar cell module) shown in FIG. can get.

(太陽電池用はんだめっき線の製造方法)
本実施の形態に係る太陽電池用はんだめっき線2の製造方法の一例を以下に示す。
(Method for manufacturing solder-plated wire for solar cells)
An example of the manufacturing method of the solar cell solder plated wire 2 according to the present embodiment will be described below.

先ず、連続鋳造圧延装置の溶湯貯溜手段において、酸素含有量が10massppmを超えるタフピッチ銅を溶解すると共に、その銅溶湯に硫黄親和性金属を0.0007〜0.05質量%の割合で添加する。硫黄親和性金属は全て銅溶湯の中に残留するものではなく、最終的に銅溶湯中に含まれる硫黄親和性金属の割合は0.0007〜0.04質量%となる。この銅溶湯を用いて、銅の荒引き材を連続的に製造する。また、この荒引き材に、減面率30%以上の冷間伸線加工を施して断面形状が平角状の導体3を作製する。その後、平角状の導体3に熱処理を施す。この加工と熱処理によって、導体3を構成する銅の結晶の平均粒径が270μm以下に、導体3の0.2%耐力が23〜66MPaに調整される。熱処理としては、例えば、190〜750℃の温度範囲で30〜90分、好ましくは400〜750℃の温度範囲で30〜90分加熱する。   First, in the molten metal storage means of the continuous casting and rolling apparatus, tough pitch copper having an oxygen content exceeding 10 massppm is dissolved, and a sulfur-affinity metal is added to the molten copper at a ratio of 0.0007 to 0.05 mass%. Not all sulfur-affinity metals remain in the molten copper, and the final ratio of sulfur-affinity metals contained in the molten copper is 0.0007 to 0.04 mass%. A copper roughening material is continuously produced using this molten copper. Further, this roughing material is subjected to cold drawing with a reduction in area of 30% or more to produce a conductor 3 having a flat cross section. Thereafter, the flat rectangular conductor 3 is subjected to heat treatment. By this processing and heat treatment, the average grain size of the copper crystals constituting the conductor 3 is adjusted to 270 μm or less, and the 0.2% proof stress of the conductor 3 is adjusted to 23 to 66 MPa. As heat processing, it heats for 30 to 90 minutes in the temperature range of 190-750 degreeC, for example, Preferably it is 30-90 minutes in the temperature range of 400-750 degreeC.

熱処理後、導体3の表面にはんだめっき4を被覆し、本実施の形態に係る太陽電池用はんだめっき線2が得られる。はんだめっき4は、太陽電池用はんだめっき線2の0.2%耐力が43〜86MPaとなるように、めっき種類及びめっき厚さが調整される。   After the heat treatment, the surface of the conductor 3 is covered with the solder plating 4 to obtain the solar cell solder plating wire 2 according to the present embodiment. The plating type and the plating thickness of the solder plating 4 are adjusted so that the 0.2% proof stress of the solder plating wire 2 for solar cells is 43 to 86 MPa.

ここで、冷間減面加工時の減面率を30%以上、好ましくは30〜99.9%と規定したのは、減面率が30%未満だと、加工時に荒引き線に十分な歪みを発生させることができず、荒引き線内部の転位を十分に増大、成長させることができないためである。その結果、銅材に固溶しているSやPbなどを十分に析出させることができなくなり、ひいては、銅材の軟化温度を十分に低下させることができなくなる。   Here, the area reduction rate at the time of cold area reduction is specified to be 30% or more, preferably 30 to 99.9%. If the area reduction ratio is less than 30%, it is sufficient for roughing lines at the time of processing. This is because distortion cannot be generated, and dislocations inside the roughing lines cannot be sufficiently increased and grown. As a result, S, Pb, etc., dissolved in the copper material cannot be sufficiently precipitated, and as a result, the softening temperature of the copper material cannot be sufficiently lowered.

なお、減面率は以下の式(1)
減面率=[1−(減面加工後の線材断面積/減面加工前の線材断面積)]×100…(1)
により求める。
In addition, the area reduction rate is the following formula (1)
Area reduction ratio = [1− (wire cross-sectional area after surface reduction processing / wire cross-sectional area before surface reduction processing)] × 100 (1)
Ask for.

導体3の0.2%耐力を低減するための熱処理方法としては、ヒータによるバッチ式加熱方式、若しくは通電加熱方式(例えば、通電アニーラ)などが適用可能である。安定した熱処理が必要な場合には、導体3をコイル状に巻き付けた後、炉に入れ、バッチ式で加熱する方式が、連続で長尺にわたって熱処理する場合には通電加熱方式が望ましい。また、酸化を防止する観点から、水素還元雰囲気の炉を用いて熱処理を行ってもよい。   As a heat treatment method for reducing the 0.2% proof stress of the conductor 3, a batch-type heating method using a heater or an electric heating method (for example, an electric annealing) can be applied. When stable heat treatment is required, a method of winding the conductor 3 in a coil shape and then placing it in a furnace and heating in a batch method is preferable, and an electric heating method is desirable when heat-treating continuously over a long length. Further, from the viewpoint of preventing oxidation, heat treatment may be performed using a furnace in a hydrogen reducing atmosphere.

連続鋳造圧延法としては、例えば、SCR、ヘズレータイプ、アプキャスト法などが適用可能である。   As the continuous casting and rolling method, for example, SCR, Hesley type, Upcast method and the like can be applied.

次に、本実施の形態に係る太陽電池用はんだめっき線2の作用を説明する。   Next, the effect | action of the solder plating wire 2 for solar cells which concerns on this Embodiment is demonstrated.

(硫黄親和性金属の含有量)
本実施の形態において、導体3に占める硫黄親和性金属の含有量を0.0007〜0.04質量%、好ましくは0.001〜0.04質量%と規定したのは、含有量が0.0007質量%未満であると、硫黄親和性金属と銅母材に固溶しているSが十分に反応しないためである。一方、含有量が0.04質量%を超えると、導体3に固溶する硫黄親和性金属の固溶量が多くなりすぎて、銅の結晶成長を妨げ、導体3の結晶粒径が小さくなりすぎる(例えば、19μm未満)ためである。
(Sulfur affinity metal content)
In the present embodiment, the sulfur-affinity metal content in the conductor 3 is defined as 0.0007 to 0.04 mass%, preferably 0.001 to 0.04 mass%. This is because, if it is less than 0007% by mass, the sulfur-soluble metal and S dissolved in the copper base material do not sufficiently react. On the other hand, if the content exceeds 0.04% by mass, the amount of sulfur-affinity metal dissolved in the conductor 3 is excessively increased, preventing copper crystal growth and reducing the crystal grain size of the conductor 3. It is because it is too much (for example, less than 19 micrometers).

通常のタフピッチ銅には10massppm前後のSが固溶しており、このSがタフピッチ銅材の軟らかさを阻害する要因であった。そこで、本実施の形態の太陽電池用はんだめっき線2では、導体3の構成材として、酸素含有量が10massppmを超える銅母材(タフピッチ銅材)に、Nb、Ti、Zr、V、Ta、Fe、Ca、Mg又はNiから選択される1種又は2種以上の硫黄親和性金属を0.0007〜0.04質量%の割合で含有させたものを採用している。   In normal tough pitch copper, about 10 mass ppm of S was dissolved, and this S was a factor inhibiting the softness of the tough pitch copper material. Therefore, in the solar cell solder-plated wire 2 of the present embodiment, as a constituent material of the conductor 3, a copper base material (tough pitch copper material) having an oxygen content exceeding 10 massppm, Nb, Ti, Zr, V, Ta, The thing which contained 1 type, or 2 or more types of sulfur affinity metals selected from Fe, Ca, Mg, or Ni in the ratio of 0.0007-0.04 mass% is employ | adopted.

(硫黄親和性金属の添加と軟化特性との関係)
この硫黄親和性金属(例えば、Ti)が、酸素含有量が10massppmを超える銅溶湯中に固溶しているSと反応することで、Sが硫化物(例えば、TiS)として析出し、銅溶湯のS固溶量が減少する。このため、S含有量が比較的多いタフピッチ銅などを出発材料にしたとしても、銅のマトリクスからSを析出させることができ、軟化特性の点において、高純度の銅(例えば、OFC)とほぼ同等の特性が得られるようになる。
(Relationship between sulfur-affinity metal addition and softening properties)
This sulfur-affinity metal (for example, Ti) reacts with S dissolved in a copper melt having an oxygen content exceeding 10 massppm, so that S precipitates as a sulfide (for example, TiS), and the copper melt The amount of S solid solution of is reduced. For this reason, even if a tough pitch copper having a relatively high S content is used as a starting material, S can be deposited from a copper matrix, and in terms of softening characteristics, it is almost the same as that of high-purity copper (for example, OFC). Equivalent characteristics can be obtained.

また、硫黄親和性金属を含む銅溶湯を用いて前述した荒引き線を製造する際、銅のマトリクス(結晶粒)の周囲には、Sの化合物である硫化物が析出することになるが、これら硫化物は微小の化合物であり、夫々間隔をもって析出されるため、銅の結晶成長を妨げるおそれはない。よって、荒引き線の結晶粒を大きく成長させることができ、降伏応力が低い荒引き線、すなわち導体3を得ることができる。   In addition, when the above-described rough drawn wire is produced using a molten copper containing a sulfur-affinity metal, sulfide that is a compound of S is deposited around the copper matrix (crystal grains). Since these sulfides are fine compounds and are deposited at intervals, there is no possibility of hindering copper crystal growth. Therefore, the crystal grain of the rough drawing line can be grown greatly, and the rough drawing line having a low yield stress, that is, the conductor 3 can be obtained.

(導体の結晶粒径)
0.2%耐力は導体3の結晶粒径との相関が大きいことが知られており、一方で粒界が少ないほど、すなわち結晶粒径が大きいほど変形抵抗は小さい。他方で結晶粒径が大きくなりすぎると、材料の伸びが低下し、脆い材料となる。従って、結晶粒径は一定条件範囲に入っている必要がある。ここで言う結晶粒径とは、導体3の結晶粒径を平均化したものである。
(Crystal grain size of conductor)
It is known that the 0.2% proof stress has a large correlation with the crystal grain size of the conductor 3, while the smaller the grain boundary, that is, the larger the crystal grain size, the smaller the deformation resistance. On the other hand, if the crystal grain size becomes too large, the elongation of the material is lowered and the material becomes brittle. Therefore, the crystal grain size needs to be within a certain range. The crystal grain size referred to here is an average of the crystal grain size of the conductor 3.

導体3の結晶粒径が270μm超だと、導体3が脆くなるため耐クラック性が落ちる。そのため、導体3の結晶粒径が270μm超だと、太陽電池パネルなどへ組み込む成型加工の際、太陽電池用はんだめっき線2、例えばはんだ被覆導体平角線に亀裂が発生したり、長期信頼性が不十分になるといった不具合の原因になる。また、導体3の結晶粒径があまり小さすぎると、例えば19μm未満だと、耐クラック性は問題はないが、導体3の軟質性が失われるため、シリコンセル(太陽電池セル1)の反りが大きくなる。従って、導体3の結晶粒径としては270μm以下の範囲が好ましい。   When the crystal grain size of the conductor 3 is more than 270 μm, the conductor 3 becomes brittle and the crack resistance is lowered. For this reason, if the crystal grain size of the conductor 3 exceeds 270 μm, cracks may occur in the solar cell solder-plated wire 2, for example, the solder-coated conductor rectangular wire, during long-term reliability, during the molding process incorporated into a solar cell panel or the like. This may cause problems such as insufficiency. If the crystal grain size of the conductor 3 is too small, for example, less than 19 μm, there is no problem with crack resistance, but the flexibility of the conductor 3 is lost, so that the silicon cell (solar cell 1) warps. growing. Therefore, the crystal grain size of the conductor 3 is preferably in the range of 270 μm or less.

以上より、本実施の形態に係る太陽電池用はんだめっき線2によれば、タフピッチ銅(TPC)を導体材料とした従来の太陽電池用はんだめっき線よりも0.2%耐力が低くなり、無酸素銅(OFC)を導体材料とした従来の太陽電池用はんだめっき線と同等又はそれ以下の0.2%耐力を実現できるため、加熱を必要とする配線工程及び太陽電池使用時における温度変化に起因した熱膨張・収縮率の差異による歪の影響を最小限に抑えることが可能となる。   As described above, according to the solar cell solder-plated wire 2 according to the present embodiment, the proof stress is 0.2% lower than that of the conventional solar cell solder-plated wire using tough pitch copper (TPC) as a conductive material, 0.2% proof stress equivalent to or lower than that of conventional solder plated wires for solar cells using oxygen copper (OFC) as the conductor material can be realized, so it can be used in wiring processes that require heating and temperature changes when using solar cells. It is possible to minimize the influence of distortion due to the difference in thermal expansion / contraction rate.

また、本実施の形態に係る太陽電池用はんだめっき線2の製造方法によれば、導体3の原材料として、高純度銅(6N)などを使用することなく、酸素含有量が10massppm以上のタフピッチ銅を使用するため、導体3の製造工程を、高純度銅(6N)などを使用する場合と比べて簡素化でき、かつ低コスト化を実現できる。   Moreover, according to the manufacturing method of the solar cell solder-plated wire 2 according to the present embodiment, tough pitch copper having an oxygen content of 10 mass ppm or more without using high-purity copper (6N) or the like as the raw material of the conductor 3. Therefore, the manufacturing process of the conductor 3 can be simplified as compared with the case where high purity copper (6N) or the like is used, and the cost can be reduced.

さらに、太陽電池用はんだめっき線のはんだめっき4のはんだ組成については、これまで導体にCuを用いたものでは、シリコンセルとの熱膨張整合を考慮して低温接続が可能なものが求められていたが、本実施の形態に係る太陽電池用はんだめっき線2においては、前述した銅材で構成される導体3を用いることで、シリコンセルの反りが小さくなることから、接続温度が高いSn−Ag−Cu系の組成のはんだを用いることが可能となる。   Furthermore, as for the solder composition of the solder plating wire 4 of the solar cell solder plating wire, it has been required to use Cu as the conductor so that it can be connected at low temperature in consideration of thermal expansion matching with the silicon cell. However, in the solar cell solder-plated wire 2 according to the present embodiment, the use of the conductor 3 made of the above-described copper material reduces the warpage of the silicon cell, so that the connection temperature is high. It is possible to use a solder having an Ag-Cu composition.

さらに、導体の被覆に用いるはんだは、Sn−Ag−Cu系の組成のはんだに限られず、第2成分としてPb、In、Bi、Sb、Ag、Zn、Ni、Cuから選択される少なくとも1種の元素を0.1wt%以上含むSn系合金はんだであればいずれでも良く、第3成分として1000ppm以下の微量元素を含んでいるものを用いてもよい。   Furthermore, the solder used for covering the conductor is not limited to a Sn—Ag—Cu-based solder, and at least one selected from Pb, In, Bi, Sb, Ag, Zn, Ni, and Cu as the second component. Any Sn-based alloy solder containing 0.1 wt% or more of the above element may be used, and a solder containing a trace element of 1000 ppm or less as the third component may be used.

また、本発明に係る太陽電池セル接続用配線導体およびはんだめっき線は、セルとの接続がなされた複数箇所に変形しやすい加工部を含んでいても良く、加工方法としてエッチング、プレス、曲げ成形のうちのいずれか、あるいは、複数を併用してもよい。さらに、その加工は素材線材、素材線材を圧延成形した圧延線材、板状素材にスリットをいれた箔状線材のいずれに施してもよい。   Moreover, the wiring conductor for connecting solar cells and the solder plating wire according to the present invention may include a deformed portion that is easily deformed at a plurality of locations connected to the cell, and etching, pressing, and bending as processing methods. Any one or a plurality of them may be used in combination. Further, the processing may be applied to any of a material wire, a rolled wire obtained by rolling the material wire, and a foil-like wire obtained by slitting a plate material.

(実施例1、試料1)
シャフト炉と連結したSCR方式の連続鋳造圧延装置を用い、タフピッチ銅(酸素含有量:300massppm)を主成分とする直径φ8mmの荒引き線を製造した。荒引き線の構成材は、タフピッチ銅溶湯に硫黄親和性金属としてNbを0.006mass%添加したものである。この荒引き線をφ2.6mmまで伸線した後に600℃×1hr熱処理し、それを91%の加工度で冷間減面加工し、直径φ0.8mmの銅線を作製した。これを圧延して平角銅線(厚さ0.16mm、幅2.0mm)を作製し、500℃×1hrの軟化焼鈍処理を施し、その後、150mmに切断して芯材(導体)とした。
この芯材を溶融はんだめっき浴(Sn−3mass%Ag−0.5mass%Cu系の鉛フリーはんだ)に浸漬して速やかに引き上げ、芯材の表面に溶融はんだめっき層(厚さ0.03mm)を形成し、はんだ被覆銅平角線(太陽電池用はんだめっき線)を作製した。
(実施例2、試料2)
荒引き線の構成材を、タフピッチ銅溶湯にNbを0.012mass%添加したこと以外は、実施例1と同様である。
(実施例3、試料3)
荒引き線の構成材を、タフピッチ銅溶湯にNbを0.04mass%添加したこと以外は、実施例1と同様である。
(実施例4、試料4)
荒引き線の構成材を、タフピッチ銅溶湯にTiを0.003mass%添加したこと以外は、実施例1と同様である。
(実施例5、試料5)
荒引き線の構成材を、タフピッチ銅溶湯にFeを0.003mass%添加したこと以外は、実施例1と同様である。
(実施例6、試料6)
荒引き線の構成材を、タフピッチ銅溶湯にMgを0.003mass%添加したこと以外は、実施例1と同様である。
(実施例7、試料7)
荒引き線の構成材を、タフピッチ銅溶湯にZrを0.003mass%添加したこと以外は、実施例1と同様である。
(実施例8、試料8)
荒引き線の構成材を、タフピッチ銅溶湯にTaを0.04mass%添加したこと以外は、実施例1と同様である。
(実施例9、試料9)
荒引き線の構成材を、タフピッチ銅溶湯にTaを0.006mass%添加したこと以外は、実施例1と同様である。
(実施例10、試料10)
荒引き線の構成材を、タフピッチ銅溶湯にNiを0.005mass%添加したこと以外は、実施例1と同様である。
(実施例11、試料11)
荒引き線の構成材を、タフピッチ銅溶湯にNiを0.01mass%添加したこと以外は、実施例1と同様である。
(実施例12、試料12)
荒引き線の構成材を、タフピッチ銅溶湯に、Niを0.01mass%とTiを0.001mass%添加したこと以外は、実施例1と同様である。
(実施例13、試料13)
荒引き線の構成材を、タフピッチ銅溶湯に、Niを0.01mass%とMnを0.001mass%添加したこと以外は、実施例1と同様である。
(実施例14、試料14)
荒引き線の構成材を、タフピッチ銅溶湯に、Niを0.01mass%とCaを0.0005mass%添加したこと以外は、実施例1と同様である。
(実施例15、試料15)
荒引き線の構成材を、タフピッチ銅溶湯に、Niを0.01mass%とVを0.001mass%添加したこと以外は、実施例1と同様である。
(実施例16、試料16)
荒引き線の構成材を、タフピッチ銅溶湯に、Nbを0.012mass%とTiを0.003mass%添加したこと以外は、実施例1と同様である。
(実施例17、試料17)
荒引き線の構成材を、タフピッチ銅溶湯に、Nbを0.012mass%とZrを0.006mass%添加したこと以外は、実施例1と同様である。
(実施例18、試料18)
荒引き線の構成材を、タフピッチ銅溶湯に、Nbを0.012mass%とHfを0.01mass%添加したこと以外は、実施例1と同様である。
(実施例19、試料19)
荒引き線の構成材を、タフピッチ銅溶湯に、Nbを0.012mass%とVを0.03mass%添加したこと以外は、実施例1と同様である。
(実施例20、試料20)
荒引き線の構成材を、タフピッチ銅溶湯に、Nbを0.012mass%とTaを0.02mass%添加したこと以外は、実施例1と同様である。
(実施例21、試料21)
荒引き線の構成材を、タフピッチ銅溶湯に、Nbを0.012mass%とFeを0.003mass%添加したこと以外は、実施例1と同様である。
(実施例22、試料22)
荒引き線の構成材を、タフピッチ銅溶湯に、Nbを0.012mass%とBを0.002mass%添加したこと以外は、実施例1と同様である。
(実施例23、試料23)
荒引き線の構成材を、タフピッチ銅溶湯に、Nbを0.012mass%とCaを0.002mass%添加したこと以外は、実施例1と同様である。
(実施例24、試料24)
荒引き線の構成材を、タフピッチ銅溶湯に、Nbを0.012mass%とMgを0.002mass%添加したこと以外は、実施例1と同様である。
(実施例25、試料25)
荒引き線の構成材を、タフピッチ銅溶湯に、Nbを0.012mass%とMM(ミッシュメタル)を0.002mass%添加したこと以外は、実施例1と同様である。
(従来例1、試料26)
荒引き線の構成材を、タフピッチ銅溶湯に硫黄親和性金属を添加していないこと以外は、実施例1と同様である。
(従来例2、試料27)
荒引き線の構成材を、無酸素銅(OFC)の溶湯を採用した点、および硫黄親和性金属を添加していない点を除いて、実施例1と同様である。
(比較例1、試料28)
荒引き線の構成材を、タフピッチ銅溶湯にTiを0.0003mass%添加したこと以外は、実施例1と同様である。
(比較例2、試料29)
荒引き線の構成材を、タフピッチ銅溶湯にTiを0.06mass%添加したこと以外は、実施例1と同様である。
(比較例3、試料30)
荒引き線の構成材を、タフピッチ銅溶湯にNbを0.06mass%添加したこと以外は、実施例1と同様である。
(比較例4、試料31)
荒引き線の構成材を、タフピッチ銅溶湯にNbを0.0005mass%添加したこと以外は、実施例1と同様である。
(比較例5、試料32)
荒引き線の構成材を、タフピッチ銅溶湯にNiを0.0005mass%添加したこと以外は、実施例1と同様である。
(比較例6、試料33)
荒引き線の構成材を、タフピッチ銅溶湯にNiを0.05mass%添加したこと以外は、実施例1と同様である。
(Example 1, Sample 1)
Using an SCR-type continuous casting and rolling apparatus connected to a shaft furnace, a rough drawn wire having a diameter of φ8 mm mainly composed of tough pitch copper (oxygen content: 300 mass ppm) was produced. The constituent material of the rough drawing wire is obtained by adding 0.006 mass% of Nb as a sulfur affinity metal to a tough pitch copper melt. The rough drawn wire was drawn to φ2.6 mm and then heat-treated at 600 ° C. for 1 hr, and cold-reduced at a workability of 91% to produce a copper wire having a diameter of φ0.8 mm. This was rolled to produce a flat copper wire (thickness 0.16 mm, width 2.0 mm), subjected to a softening annealing treatment at 500 ° C. × 1 hr, and then cut to 150 mm to obtain a core material (conductor).
This core material is immersed in a molten solder plating bath (Sn-3 mass% Ag-0.5 mass% Cu-based lead-free solder) and quickly pulled up, and a molten solder plating layer (thickness 0.03 mm) is formed on the surface of the core material. Was formed, and a solder-coated copper rectangular wire (solder-plated wire for solar cell) was produced.
(Example 2, sample 2)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.012 mass% of Nb is added to the tough pitch copper molten metal.
(Example 3, Sample 3)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.04 mass% of Nb is added to the tough pitch copper molten metal.
(Example 4, sample 4)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.003 mass% of Ti is added to the tough pitch copper molten metal.
(Example 5, sample 5)
The constituent material of the rough drawn wire is the same as that of Example 1 except that 0.003 mass% of Fe is added to the tough pitch copper molten metal.
(Example 6, sample 6)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.003 mass% of Mg is added to the tough pitch copper molten metal.
(Example 7, Sample 7)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.003 mass% of Zr is added to the tough pitch copper molten metal.
(Example 8, sample 8)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.04 mass% of Ta is added to the tough pitch copper molten metal.
(Example 9, sample 9)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.006 mass% of Ta is added to the tough pitch copper molten metal.
(Example 10, sample 10)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.005 mass% of Ni is added to the tough pitch copper molten metal.
(Example 11, sample 11)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.01 mass% of Ni is added to the tough pitch copper molten metal.
(Example 12, sample 12)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.01 mass% of Ni and 0.001 mass% of Ti are added to the tough pitch copper molten metal.
(Example 13, sample 13)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.01 mass% of Ni and 0.001 mass% of Mn are added to the tough pitch copper molten metal.
(Example 14, sample 14)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.01 mass% of Ni and 0.0005 mass% of Ca are added to the tough pitch copper molten metal.
(Example 15, sample 15)
The constituent material of the rough drawing wire is the same as in Example 1 except that 0.01 mass% of Ni and 0.001 mass% of V are added to the tough pitch copper molten metal.
(Example 16, sample 16)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.012 mass% of Nb and 0.003 mass% of Ti are added to the tough pitch copper molten metal.
(Example 17, sample 17)
The constituent material of the rough drawing wire is the same as in Example 1 except that 0.012 mass% of Nb and 0.006 mass% of Zr are added to the tough pitch copper melt.
(Example 18, sample 18)
The constituent material of the rough drawing wire was the same as that of Example 1 except that 0.012 mass% of Nb and 0.01 mass% of Hf were added to the tough pitch copper melt.
(Example 19, sample 19)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.012 mass% of Nb and 0.03 mass% of V are added to the tough pitch copper molten metal.
(Example 20, sample 20)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.012 mass% of Nb and 0.02 mass% of Ta are added to the tough pitch copper molten metal.
(Example 21, Sample 21)
The constituent material of the rough drawing wire was the same as that of Example 1 except that 0.012 mass% of Nb and 0.003 mass% of Fe were added to the tough pitch copper molten metal.
(Example 22, sample 22)
The constituent material of the rough drawing wire was the same as that of Example 1 except that 0.012 mass% of Nb and 0.002 mass% of B were added to the tough pitch copper molten metal.
(Example 23, sample 23)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.012 mass% of Nb and 0.002 mass% of Ca are added to the tough pitch copper molten metal.
(Example 24, sample 24)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.012 mass% of Nb and 0.002 mass% of Mg are added to the tough pitch copper molten metal.
(Example 25, sample 25)
The constituent material of the rough drawing wire was the same as that of Example 1 except that 0.012 mass% of Nb and 0.002 mass% of MM (Misch metal) were added to the tough pitch copper molten metal.
(Conventional example 1, sample 26)
The constituent material of the rough drawn wire is the same as that of Example 1 except that no sulfur-affinity metal is added to the tough pitch copper melt.
(Conventional example 2, sample 27)
The constituent material of the rough drawing wire is the same as that of Example 1 except that a melt of oxygen-free copper (OFC) is used and a sulfur-affinity metal is not added.
(Comparative Example 1, Sample 28)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.0003 mass% of Ti is added to the tough pitch copper molten metal.
(Comparative Example 2, Sample 29)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.06 mass% of Ti is added to the tough pitch copper molten metal.
(Comparative Example 3, Sample 30)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.06 mass% of Nb is added to the tough pitch copper molten metal.
(Comparative Example 4, Sample 31)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.0005 mass% of Nb is added to the tough pitch copper molten metal.
(Comparative Example 5, Sample 32)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.0005 mass% of Ni is added to the tough pitch copper molten metal.
(Comparative Example 6, Sample 33)
The constituent material of the rough drawing wire is the same as that of Example 1 except that 0.05 mass% of Ni is added to the tough pitch copper molten metal.

(評価方法)
上述した各はんだ被覆Cu平角線を縦150mm×横150mm、厚さ200μmのシリコンセルにはんだ接続したものの耐クラックとシリコンセルの反りを調べた。
(Evaluation methods)
Each solder-coated Cu rectangular wire was solder-connected to a silicon cell having a length of 150 mm × width of 150 mm and a thickness of 200 μm, and the crack resistance and warpage of the silicon cell were examined.

実施例1〜実施例25、従来例1,2と、比較例1〜比較例6の各はんだ被覆Cu平角線の0.2%耐力(MPa)、結晶粒径、シリコン基板の反りの発生を測定した結果を表1に示す。   Example 1 to Example 25, Conventional Examples 1 and 2 and Comparative Examples 1 to 6 of each solder-coated Cu rectangular wire 0.2% proof stress (MPa), crystal grain size, warp of silicon substrate The measured results are shown in Table 1.

表1において、シリコン基板の反りの発生の欄における評価印の×は、2.1mmを超える反りが発生した場合を、○は反りが2.1mm以下であった場合を意味する。   In Table 1, “x” of the evaluation mark in the column of warpage occurrence of the silicon substrate indicates a case where warpage exceeding 2.1 mm occurs, and “◯” indicates a case where warpage is 2.1 mm or less.

また、はんだ被覆Cu平角線の0.2%耐力σは、導体に0.2%の歪を与える引張試験における荷重(外力)Fを、はんだを除く導体の断面積Aで除算して求めている。式で示せば、次の通りである。   The 0.2% yield strength σ of the solder-coated Cu rectangular wire is obtained by dividing the load (external force) F in a tensile test that gives a strain of 0.2% to the conductor by the cross-sectional area A of the conductor excluding the solder. Yes. This can be expressed by the following formula.

σ=F/A
さらに、ここで言う結晶粒径とは、はんだ被覆Cu平角線の断面において、結晶粒の大きい方から例えば10個選び、それらの結晶粒の粒径を平均化したものである。
σ = F / A
Further, the crystal grain size referred to here is, for example, 10 grains selected from the larger crystal grains in the cross section of the solder-coated Cu rectangular wire, and the grain diameters of those crystal grains are averaged.

Figure 2008182171
Figure 2008182171

表1によると、実施例1〜実施例24の太陽電池用はんだめっき線(試料1〜試料24)は、いずれもめっき前のCu芯材の0.2%耐力が49MPa以下、めっき後のはんだ被覆Cu平角線の0.2%耐力が69MPa以下、かつ、結晶粒径は19μm以上であった。これらは、いずれもタフピッチ銅の特性(試料26、めっき前のCu芯材の0.2%耐力:70MPa、めっき後のはんだ被覆Cu平角線の0.2%耐力:90MPa、結晶粒径:18μm)及び無酸素銅の特性(試料27、めっき前のCu芯材の0.2%耐力:50MPa、めっき後のはんだ被覆Cu平角線の0.2%耐力:70MPa、結晶粒径:25μm)よりも優れており、200μmの薄型シリコン基板にはんだ接続した際のシリコン基板の反り量は、許容範囲内(2.1mm以下)であった。   According to Table 1, the solder plating wires for solar cells of Examples 1 to 24 (Samples 1 to 24) all have a 0.2% proof stress of the Cu core material before plating of 49 MPa or less, and the solder after plating. The 0.2% yield strength of the coated Cu rectangular wire was 69 MPa or less, and the crystal grain size was 19 μm or more. These are all characteristics of tough pitch copper (sample 26, 0.2% proof stress of Cu core material before plating: 70 MPa, 0.2% proof stress of solder-coated Cu rectangular wire after plating: 90 MPa, crystal grain size: 18 μm) ) And oxygen-free copper characteristics (sample 27, 0.2% proof stress of Cu core material before plating: 50 MPa, 0.2% proof stress of solder-coated Cu rectangular wire after plating: 70 MPa, crystal grain size: 25 μm) The amount of warpage of the silicon substrate when solder-connected to a 200 μm thin silicon substrate was within an allowable range (2.1 mm or less).

また、実施例25の太陽電池用はんだめっき線(試料25)については、めっき前のCu芯材の0.2%耐力が50MPa、めっき後のはんだ被覆Cu平角線の0.2%耐力が70MPa、かつ、結晶粒径が25μmであり、前述したタフピッチ銅の特性(試料26)よりも優れており、前述した無酸素銅の特性(試料27)と同等であり、シリコン基板の反り量は、許容範囲内であった。   Moreover, about the solder plating wire for solar cells (sample 25) of Example 25, the 0.2% yield strength of the Cu core material before plating is 50 MPa, and the 0.2% yield strength of the solder-coated Cu rectangular wire after plating is 70 MPa. In addition, the crystal grain size is 25 μm, which is superior to the above-described characteristics of tough pitch copper (sample 26), and is equivalent to the characteristics of oxygen-free copper (sample 27) described above. It was within an acceptable range.

一方、比較例の太陽電池用はんだめっき線(試料28〜33)は、いずれもめっき前のCu芯材の0.2%耐力が70MPaよりも大きく、めっき後のはんだ被覆Cu平角線の0.2%耐力が90MPaよりも大きく、かつ、結晶粒径は19μm未満であるため、タフピッチ銅の特性(試料26)及び無酸素銅の特性(試料27)よりも劣っており、シリコン基板の反り量は、許容範囲(2.1mm)を超えていた。   On the other hand, in the solder plating wires for solar cells (samples 28 to 33) of the comparative example, the 0.2% proof stress of the Cu core material before plating is larger than 70 MPa. Since the 2% proof stress is greater than 90 MPa and the crystal grain size is less than 19 μm, it is inferior to the characteristics of tough pitch copper (sample 26) and oxygen-free copper (sample 27), and the amount of warpage of the silicon substrate Exceeded the allowable range (2.1 mm).

次に、試料1(本発明品)、試料26(TPC)、試料27(OFC)において、φ2.6mmまで伸線した荒引き線に、複数の熱処理条件で熱処理を試みた場合の軟化特性の結果を図1に示す。この図1は、各荒引き線を所定の温度に1時間保持した後、取り出して水冷したものについて、それぞれ0.2%耐力の評価を行ったものである。   Next, in sample 1 (product of the present invention), sample 26 (TPC), and sample 27 (OFC), softening characteristics when heat treatment was attempted under a plurality of heat treatment conditions on the rough drawn wire drawn to φ2.6 mm. The results are shown in FIG. FIG. 1 shows an evaluation of 0.2% proof stress for each of the roughing lines held at a predetermined temperature for 1 hour and then taken out and water-cooled.

図1に示すように、各試料ともに熱処理前(図1中の温度20℃の場合)は400MPa程度の高い0.2%耐力を有しているが、軟化焼鈍温度を上昇させるにつれて0.2%耐力が低下し、300℃付近では100MPa以下の水準まで下がり、400℃付近では、本発明品の試料1のみが50MPaを下回る結果となった。各材料(試料1、試料26、試料27)を比較すると、試料1(本発明品)が最も小さい値を示し、ついで試料26(TPC)、試料27(OFC)の順番となった。   As shown in FIG. 1, each sample has a high 0.2% proof stress of about 400 MPa before heat treatment (when the temperature is 20 ° C. in FIG. 1). % Proof stress decreased, and it decreased to a level of 100 MPa or less near 300 ° C., and only sample 1 of the present invention was below 50 MPa near 400 ° C. When each material (sample 1, sample 26, sample 27) was compared, sample 1 (product of the present invention) showed the smallest value, followed by sample 26 (TPC) and sample 27 (OFC).

次に、本発明品である実施例1の太陽電池用はんだめっき線(試料1)の熱処理条件(温度、時間)を変化させた場合の、結晶粒径、0.2%耐力(MPa)、耐クラック、シリコン基板の反りを調べた。その結果を表2に示す。   Next, the crystal grain size, 0.2% proof stress (MPa), when the heat treatment conditions (temperature, time) of the solder plated wire for solar cells (sample 1) of Example 1 which is the present invention product are changed, The crack resistance and warpage of the silicon substrate were examined. The results are shown in Table 2.

ここで言う「耐クラック」とは、シリコン基板に接続した後における太陽電池用はんだめっき線に生じる破断を意味する。表2において、耐クラックの欄における評価印の○、×は、それぞれ太陽電池用はんだめっき線に亀裂が生じなかったこと、亀裂が生じたことを意味する。また、表2において、シリコンセルの反りの欄における評価印の○、×は、表1と同様の基準によるものである。   The term “crack-resistant” as used herein means a break that occurs in a solder plating wire for solar cells after being connected to a silicon substrate. In Table 2, “◯” and “x” of the evaluation mark in the column of crack resistance mean that no crack occurred in the solder plating wire for solar cell and that a crack occurred. In Table 2, the evaluation marks ◯ and X in the warp column of the silicon cell are based on the same criteria as in Table 1.

Figure 2008182171
Figure 2008182171

表2に示すように、熱処理条件を800℃で60分とした場合、結晶粒径が300μmとなり、変形が簡単に進んでしまい、耐クラックが悪くなるため、大きな伸びを与える前に材料に亀裂が生じてしまい、脆い材料であることが確認された。   As shown in Table 2, when the heat treatment condition is 800 ° C. for 60 minutes, the crystal grain size becomes 300 μm, the deformation progresses easily, and the crack resistance deteriorates. It was confirmed that the material was brittle.

一方、熱処理条件を190℃で60分、180℃で60分とした場合、結晶粒径が18、16μm、めっき前のCu芯材の0.2%耐力が70、78MPa、めっき後のはんだ被覆Cu平角線の0.2%耐力が90、98MPaであり、表1に示した試料26と同等又はそれより劣る結果となり、シリコン基板の反り量は、許容範囲(2.1mm)を超えていた。   On the other hand, when the heat treatment conditions are 190 ° C. for 60 minutes and 180 ° C. for 60 minutes, the crystal grain size is 18, 16 μm, the 0.2% proof stress of the Cu core material before plating is 70, 78 MPa, and the solder coating after plating The 0.2% yield strength of the Cu rectangular wire is 90, 98 MPa, which is the same as or inferior to that of the sample 26 shown in Table 1, and the warpage amount of the silicon substrate exceeded the allowable range (2.1 mm). .

以上の結果から、熱処理条件を750℃(×30〜90分)〜200℃(×30〜90分)とした場合に、試料26よりも優れた特性を得ることができ、太陽電池用はんだめっき線にクラックが生じることもなく、シリコン基板の反り量は、許容範囲内(2.1mm以下)となった。より良好な熱処理条件は、熱処理条件を750℃(×30〜90分)〜400℃(×30〜90分)とした場合であり、この時に、表1に示した試料27よりも優れた特性又は試料27とほぼ同等の特性を得ることができ、太陽電池用はんだめっき線にクラックが生じることもなく、シリコン基板の反り量は、許容範囲内となった。   From the above results, when the heat treatment conditions are 750 ° C. (× 30 to 90 minutes) to 200 ° C. (× 30 to 90 minutes), characteristics superior to those of the sample 26 can be obtained, and the solder plating for solar cells The warp amount of the silicon substrate was within an allowable range (2.1 mm or less) without causing cracks in the wires. Better heat treatment conditions are when the heat treatment conditions are 750 ° C. (× 30 to 90 minutes) to 400 ° C. (× 30 to 90 minutes). At this time, characteristics superior to those of the sample 27 shown in Table 1 are obtained. Or the characteristic substantially equivalent to the sample 27 was acquired, the crack was not produced in the solder plating wire for solar cells, and the curvature amount of the silicon substrate became in the tolerance | permissible_range.

(実施例26、試料34)
シャフト炉と連結したSCR方式の連続鋳造圧延装置を用い、酸素濃度30massppmを含有した銅を主成分とする直径φ8mmの荒引き線を製造した。荒引き線の構成材は、銅溶湯に硫黄親和性金属としてNbを0.006質量%(mass%)添加したものである。この荒引き線をφ2.6mmまで伸線した後に600℃×1hr熱処理し、それを91%の加工度で冷間減面加工し、直径φ0.8mmの銅線を作製した。これを圧延して平角銅線(厚さ0.16mm、幅2.0mm)を作製し、500℃×1hrの軟化焼鈍処理を施し、その後、150mmに切断して芯材(導体)とした。
この芯材を溶融はんだめっき浴(Sn−3mass%Ag−0.5mass%Cu系の鉛フリーはんだ)に浸漬して速やかに引き上げ、芯材の表面に溶融はんだめっき層(厚さ0.03mm)を形成し、はんだ被覆銅平角線(太陽電池用はんだめっき線)を作製した。
(実施例27、試料35)
荒引き線の構成材を、銅溶湯にNbを0.012質量%添加したこと以外は、実施例26と同様である。
(実施例28、試料36)
荒引き線の構成材を、銅溶湯にNbを0.04質量%添加したこと以外は、実施例26と同様である。
(実施例29、試料37)
荒引き線の構成材を、銅溶湯にTiを0.003質量%添加したこと以外は、実施例26と同様である。
(実施例30、試料38)
荒引き線の構成材を、銅溶湯にFeを0.003質量%添加したこと以外は、実施例26と同様である。
(実施例31、試料39)
荒引き線の構成材を、銅溶湯にMgを0.003質量%添加したこと以外は、実施例26と同様である。
(実施例32、試料40)
荒引き線の構成材を、銅溶湯にZrを0.003質量%添加したこと以外は、実施例26と同様である。
(実施例33、試料41)
荒引き線の構成材を、銅溶湯にTaを0.04質量%添加したこと以外は、実施例26と同様である。
(実施例34、試料42)
荒引き線の構成材を、銅溶湯にTaを0.006質量%添加したこと以外は、実施例26と同様である。
(実施例35、試料43)
荒引き線の構成材を、銅溶湯にNiを0.005質量%添加したこと以外は、実施例26と同様である。
(実施例36、試料44)
荒引き線の構成材を、銅溶湯にNiを0.01質量%添加したこと以外は、実施例26と同様である。
(実施例37、試料45)
荒引き線の構成材を、銅溶湯にNiを0.01質量%とTiを0.001質量%添加したこと以外は、実施例26と同様である。
(実施例38、試料46)
荒引き線の構成材を、銅溶湯にNiを0.01質量%とMnを0.001質量%添加したこと以外は、実施例26と同様である。
(実施例39、試料47)
荒引き線の構成材を、銅溶湯にNiを0.01質量%とCaを0.0005質量%添加したこと以外は、実施例26と同様である。
(実施例40、試料48)
荒引き線の構成材を、銅溶湯にNiを0.01質量%とVを0.001質量%添加したこと以外は、実施例26と同様である。
(実施例41、試料49)
荒引き線の構成材を、銅溶湯にNbを0.012質量%とTiを0.003質量%添加したこと以外は、実施例26と同様である。
(実施例42、試料50)
荒引き線の構成材を、銅溶湯にNbを0.012質量%とZrを0.006質量%添加したこと以外は、実施例26と同様である。
(実施例43、試料51)
荒引き線の構成材を、銅溶湯にNbを0.012質量%とHfを0.01質量%添加したこと以外は、実施例26と同様である。
(実施例44、試料52)
荒引き線の構成材を、銅溶湯にNbを0.012質量%とVを0.03質量%添加したこと以外は、実施例26と同様である。
(実施例45、試料53)
荒引き線の構成材を、銅溶湯にNbを0.012質量%とTaを0.02質量%添加したこと以外は、実施例26と同様である。
(実施例46、試料54)
荒引き線の構成材を、銅溶湯にNbを0.012質量%とFeを0.003質量%添加したこと以外は、実施例26と同様である。
(実施例47、試料55)
荒引き線の構成材を、銅溶湯にNbを0.012質量%とBを0.002質量%添加したこと以外は、実施例26と同様である。
(実施例48、試料56)
荒引き線の構成材を、銅溶湯にNbを0.012質量%とCaを0.002質量%添加したこと以外は、実施例26と同様である。
(実施例49、試料57)
荒引き線の構成材を、銅溶湯にNbを0.012質量%とMgを0.002質量%添加したこと以外は、実施例26と同様である。
(実施例50、試料58)
荒引き線の構成材を、銅溶湯にNbを0.012質量%とMM(ミッシュメタル)を0.002質量%添加したこと以外は、実施例26と同様である。
(比較例7、試料59)
荒引き線の構成材を、銅溶湯にTiを0.0003質量%添加したこと以外は、実施例26と同様である。
(比較例8、試料60)
荒引き線の構成材を、銅溶湯にTiを0.06質量%添加したこと以外は、実施例26と同様である。
(比較例9、試料61)
荒引き線の構成材を、銅溶湯にNbを0.06質量%添加したこと以外は、実施例26と同様である。
(比較例10、試料62)
荒引き線の構成材を、銅溶湯にNbを0.0005質量%添加したこと以外は、実施例26と同様である。
(比較例11、試料63)
荒引き線の構成材を、銅溶湯にNiを0.0005質量%添加したこと以外は、実施例26と同様である。
(比較例12、試料64)
荒引き線の構成材を、銅溶湯にNiを0.05質量%添加したこと以外は、実施例26と同様である。
(評価方法)
評価方法は実施例1〜実施例25、従来例1、2、比較例1〜比較例6と同様の基準により評価した。その結果を表3に示す。
(Example 26, sample 34)
Using an SCR-type continuous casting and rolling apparatus connected to a shaft furnace, a rough drawn wire having a diameter of φ8 mm mainly composed of copper containing an oxygen concentration of 30 mass ppm was manufactured. The constituent material of the rough drawing wire is obtained by adding 0.006 mass% (mass%) of Nb as a sulfur-affinity metal to the molten copper. The rough drawn wire was drawn to φ2.6 mm and then heat-treated at 600 ° C. for 1 hr, and cold-reduced at a workability of 91% to produce a copper wire having a diameter of φ0.8 mm. This was rolled to produce a flat copper wire (thickness 0.16 mm, width 2.0 mm), subjected to a softening annealing treatment at 500 ° C. × 1 hr, and then cut to 150 mm to obtain a core material (conductor).
This core material is immersed in a molten solder plating bath (Sn-3 mass% Ag-0.5 mass% Cu-based lead-free solder) and quickly pulled up, and a molten solder plating layer (thickness 0.03 mm) is formed on the surface of the core material. Was formed, and a solder-coated copper rectangular wire (solder-plated wire for solar cell) was produced.
(Example 27, Sample 35)
The constituent material of the rough drawn wire is the same as that of Example 26 except that 0.012% by mass of Nb is added to the molten copper.
(Example 28, Sample 36)
The constituent material of the rough drawing wire is the same as that of Example 26 except that 0.04% by mass of Nb is added to the molten copper.
(Example 29, Sample 37)
The constituent material of the rough drawing wire is the same as that of Example 26 except that 0.003% by mass of Ti is added to the molten copper.
(Example 30, sample 38)
The constituent material of the rough drawing wire is the same as that of Example 26 except that 0.003% by mass of Fe is added to the molten copper.
(Example 31, sample 39)
The constituent material of the rough drawing wire is the same as that of Example 26 except that 0.003% by mass of Mg is added to the molten copper.
(Example 32, sample 40)
The constituent material of the rough drawing wire is the same as that of Example 26 except that 0.003% by mass of Zr is added to the molten copper.
(Example 33, Sample 41)
The constituent material of the rough drawing wire is the same as that of Example 26 except that 0.04% by mass of Ta is added to the molten copper.
(Example 34, sample 42)
The constituent material of the rough drawing wire is the same as that of Example 26 except that 0.006% by mass of Ta is added to the molten copper.
(Example 35, Sample 43)
The constituent material of the rough drawn wire is the same as that of Example 26 except that 0.005 mass% of Ni is added to the molten copper.
(Example 36, Sample 44)
The constituent material of the rough drawn wire is the same as that of Example 26 except that 0.01% by mass of Ni is added to the molten copper.
(Example 37, sample 45)
The roughening wire was the same as in Example 26 except that 0.01 mass% Ni and 0.001 mass% Ti were added to the molten copper.
(Example 38, Sample 46)
The constituent material of the rough drawn wire is the same as that of Example 26 except that 0.01 mass% of Ni and 0.001 mass% of Mn are added to the molten copper.
(Example 39, sample 47)
The roughening wire was the same as in Example 26 except that 0.01 mass% Ni and 0.0005 mass% Ca were added to the molten copper.
(Example 40, sample 48)
The constituent material of the rough drawing wire is the same as that of Example 26 except that 0.01% by mass of Ni and 0.001% by mass of V are added to the molten copper.
(Example 41, sample 49)
The constituent material of the rough wire was the same as that of Example 26 except that 0.012 mass% of Nb and 0.003 mass% of Ti were added to the molten copper.
(Example 42, sample 50)
The constituent material of the rough wire was the same as that of Example 26 except that 0.012 mass% of Nb and 0.006 mass% of Zr were added to the molten copper.
(Example 43, Sample 51)
The constituent material of the rough drawing wire was the same as that of Example 26 except that 0.012 mass% of Nb and 0.01 mass% of Hf were added to the molten copper.
(Example 44, Sample 52)
The constituent material of the rough drawing wire was the same as that of Example 26 except that 0.012 mass% of Nb and 0.03% by mass of V were added to the molten copper.
(Example 45, Sample 53)
The constituent material of the rough drawing wire was the same as that of Example 26 except that 0.012 mass% of Nb and 0.02 mass% of Ta were added to the molten copper.
(Example 46, Sample 54)
The constituent material of the rough drawn wire is the same as that of Example 26 except that 0.012 mass% of Nb and 0.003 mass% of Fe are added to the molten copper.
(Example 47, sample 55)
The constituent material of the rough drawing wire is the same as that of Example 26 except that 0.012 mass% of Nb and 0.002 mass% of B are added to the molten copper.
(Example 48, Sample 56)
The constituent material of the rough drawing wire was the same as that of Example 26 except that 0.012 mass% of Nb and 0.002 mass% of Ca were added to the molten copper.
(Example 49, Sample 57)
The constituent material of the rough drawn wire is the same as that of Example 26 except that 0.012 mass% of Nb and 0.002 mass% of Mg are added to the molten copper.
(Example 50, Sample 58)
The constituent material of the rough drawing wire is the same as that of Example 26 except that 0.012 mass% of Nb and 0.002 mass% of MM (Misch metal) are added to the molten copper.
(Comparative Example 7, Sample 59)
The constituent material of the rough drawing wire is the same as that of Example 26 except that 0.0003 mass% of Ti is added to the molten copper.
(Comparative Example 8, Sample 60)
The constituent material of the rough drawing wire is the same as that of Example 26 except that 0.06% by mass of Ti is added to the molten copper.
(Comparative Example 9, Sample 61)
The constituent material of the rough drawn wire is the same as that of Example 26 except that 0.06% by mass of Nb is added to the molten copper.
(Comparative Example 10, Sample 62)
The constituent material of the rough drawing wire is the same as that of Example 26 except that 0.0005 mass% of Nb is added to the molten copper.
(Comparative Example 11, Sample 63)
The constituent material of the rough drawing wire is the same as that of Example 26 except that 0.0005 mass% of Ni is added to the molten copper.
(Comparative Example 12, Sample 64)
The roughening wire was the same as in Example 26 except that 0.05% by mass of Ni was added to the molten copper.
(Evaluation methods)
The evaluation method was evaluated according to the same criteria as in Examples 1 to 25, Conventional Examples 1 and 2, and Comparative Examples 1 to 6. The results are shown in Table 3.

Figure 2008182171
Figure 2008182171

表3によると、実施例26〜実施例50の太陽電池用はんだめっき線(試料34〜試料58)は、いずれもめっき前のCu芯材の0.2%耐力が48MPa以下、めっき後のはんだ被覆Cu平角線の0.2%耐力が68MPa以下、かつ、結晶粒径は25μm以上であった。これらは、いずれもタフピッチ銅の特性(試料26、めっき前のCu芯材の0.2%耐力:70MPa、めっき後のはんだ被覆Cu平角線の0.2%耐力:90MPa、結晶粒径:18μm)及び無酸素銅の特性(試料27、めっき前のCu芯材の0.2%耐力:50MPa、めっき後のはんだ被覆Cu平角線の0.2%耐力:70MPa、結晶粒径:25μm)よりも優れており、200μmの薄型シリコン基板にはんだ接続した際のシリコン基板の反り量は、許容範囲内(2.1mm以下)であった。   According to Table 3, the solder plating wires for solar cells of Examples 26 to 50 (Sample 34 to Sample 58) all have a 0.2% proof stress of the Cu core material before plating of 48 MPa or less, and the solder after plating. The 0.2% yield strength of the coated Cu rectangular wire was 68 MPa or less, and the crystal grain size was 25 μm or more. These are all characteristics of tough pitch copper (sample 26, 0.2% proof stress of Cu core material before plating: 70 MPa, 0.2% proof stress of solder-coated Cu rectangular wire after plating: 90 MPa, crystal grain size: 18 μm) ) And oxygen-free copper characteristics (sample 27, 0.2% proof stress of Cu core material before plating: 50 MPa, 0.2% proof stress of solder-coated Cu rectangular wire after plating: 70 MPa, crystal grain size: 25 μm) The amount of warpage of the silicon substrate when solder-connected to a 200 μm thin silicon substrate was within an allowable range (2.1 mm or less).

また、実施例1と実施例26とを比較すると、実施例1では、めっき前のCu芯材の0.2%耐力:41MPa、めっき後のはんだ被覆Cu平角線の0.2%耐力:61MPa、結晶粒径:30μmであるのに対し、実施例26では、めっき前のCu芯材の0.2%耐力:39MPa、めっき後のはんだ被覆Cu平角線の0.2%耐力:59MPa、結晶粒径:30μmであり、実施例26の銅材の方が0.2%耐力値がより低い銅材であることがわかる。   Further, comparing Example 1 and Example 26, in Example 1, 0.2% proof stress of the Cu core material before plating: 41 MPa, and 0.2% proof stress of the solder-coated Cu rectangular wire after plating: 61 MPa. In Example 26, while the crystal grain size is 30 μm, the 0.2% proof stress of the Cu core material before plating: 39 MPa, the 0.2% proof stress of the solder-coated Cu rectangular wire after plating: 59 MPa, crystals It can be seen that the particle size is 30 μm, and the copper material of Example 26 is a copper material having a lower 0.2% proof stress.

このことは実施例2〜実施例25と、実施例27〜実施例50とを比較した場合にも同様であり、銅母材における酸素含有量を低くすると(例えば、酸素含有量10〜50massppm)、0.2%耐力値がより低く、かつ結晶粒径が大きい銅材が得られることがわかる。   This is the same when Example 2 to Example 25 and Example 27 to Example 50 are compared. When the oxygen content in the copper base material is lowered (for example, the oxygen content is 10 to 50 massppm). It can be seen that a copper material having a lower 0.2% proof stress and a large crystal grain size can be obtained.

次に、本発明品である実施例26の太陽電池用はんだめっき線(試料34)の熱処理条件(温度、時間)を変化させた場合の、結晶粒径、0.2%耐力(MPa)、耐クラック、シリコン基板の反りを調べた。その結果を表4に示す。「耐クラック」および「シリコ基板の反り」の欄における評価については、実施例1〜実施例25と同様の基準によるものとした。   Next, the crystal grain size, 0.2% proof stress (MPa) when the heat treatment conditions (temperature, time) of the solar cell solder-plated wire (sample 34) of Example 26 which is the present invention product are changed, The crack resistance and warpage of the silicon substrate were examined. The results are shown in Table 4. The evaluations in the “crack resistance” and “warp of the silicon substrate” columns were based on the same criteria as in Examples 1 to 25.

Figure 2008182171
Figure 2008182171

表4に示すように、熱処理条件を800℃で60分とした場合、結晶粒径が307μmとなり、変形が簡単に進んでしまい、耐クラックが悪くなるため、大きな伸びを与える前に材料に亀裂が生じてしまい、脆い材料であることが確認された。   As shown in Table 4, when the heat treatment condition is 800 ° C. for 60 minutes, the crystal grain size becomes 307 μm, the deformation progresses easily, and the crack resistance deteriorates. It was confirmed that the material was brittle.

一方、熱処理条件を180℃で60分とした場合、結晶粒径が18μm、めっき前のCu芯材の0.2%耐力が75MPa、めっき後のはんだ被覆Cu平角線の0.2%耐力が95MPaであり、表1に示した試料26と同等又は試料27より劣る結果となり、シリコン基板の反り量は、許容範囲(2.1mm)を超えていた。   On the other hand, when the heat treatment condition is 180 ° C. for 60 minutes, the crystal grain size is 18 μm, the 0.2% proof stress of the Cu core material before plating is 75 MPa, and the 0.2% proof stress of the solder-coated Cu rectangular wire after plating is The result was 95 MPa, which was equivalent to or inferior to sample 27 shown in Table 1, and the warpage amount of the silicon substrate exceeded the allowable range (2.1 mm).

以上の結果から、熱処理条件を190℃〜750℃とした場合に、試料26よりも優れた特性を得ることができ、太陽電池用はんだめっき線にクラックが生じることもなく、シリコン基板の反り量は、許容範囲内(2.1mm以下)となった。より良好な熱処理条件は、熱処理条件を750℃(×30〜90分)〜400℃(×30〜90分)とした場合であり、この時に、表1に示した試料27よりも優れた特性を得ることができ、太陽電池用はんだめっき線にクラックが生じることもなく、シリコン基板の反り量は、許容範囲内となった。   From the above results, when the heat treatment conditions are 190 ° C. to 750 ° C., it is possible to obtain characteristics superior to those of the sample 26, without causing cracks in the solar cell solder plated wires, and the amount of warpage of the silicon substrate Was within an allowable range (2.1 mm or less). Better heat treatment conditions are when the heat treatment conditions are 750 ° C. (× 30 to 90 minutes) to 400 ° C. (× 30 to 90 minutes). At this time, characteristics superior to those of the sample 27 shown in Table 1 are obtained. The crack amount of the silicon substrate was not allowed to crack, and the warpage amount of the silicon substrate was within the allowable range.

銅導体の熱処理温度と0.2%耐力の関係を示す図である。It is a figure which shows the relationship between the heat processing temperature of a copper conductor, and 0.2% yield strength. 太陽電池セルへのはんだめっき平角線の接続状態を示す図である。It is a figure which shows the connection state of the solder plating rectangular wire to a photovoltaic cell. 一般的な太陽電池用はんだめっき線の横断面図である。It is a cross-sectional view of a general solder plating wire for solar cells. Siセルと太陽電池用はんだめっき線の接続状態を示す図であり、図4(a)ははんだ接続前の状態、図4(b)ははんだ接続後に反りが発生した状態を示している。It is a figure which shows the connection state of the Si cell and the solder plating wire for solar cells, Fig.4 (a) has shown the state before solder connection, FIG.4 (b) has shown the state which the curvature generate | occur | produced after solder connection.

符号の説明Explanation of symbols

1 太陽電池セル(Siセル)
2 太陽電池用はんだめっき線(はんだめっき平角線)
3 導体
4 はんだめっき
1 Solar cell (Si cell)
2 Solder-plated wire for solar cells (Solder-plated flat wire)
3 Conductor 4 Solder plating

Claims (7)

太陽電池セルに接合すべく、断面平角状に形成された導体の表面の一部又は全部にはんだめっきが被覆された太陽電池用はんだめっき線において、
上記導体を、Nb、Ti、Zr、V、Ta、Fe、Ca、Mg又はNiから選択される1種又は2種以上の硫黄親和性金属を含有し、残部が酸素含有量が10massppmを超える銅及び不可避的不純物である銅材で構成したことを特徴とする太陽電池用はんだめっき線。
In a solder plating wire for a solar battery in which a part or all of the surface of a conductor formed in a rectangular cross section is coated with a solder plating to be joined to a solar battery cell,
Copper containing one or more sulfur-affinity metals selected from Nb, Ti, Zr, V, Ta, Fe, Ca, Mg, or Ni, with the remainder having an oxygen content of more than 10 massppm And a solder-plated wire for a solar cell, characterized by comprising a copper material which is an inevitable impurity.
上記導体が、上記硫黄親和性金属を0.0007〜0.04質量%含有する請求項1記載の太陽電池用はんだめっき線。   The solder plating wire for solar cells according to claim 1, wherein the conductor contains 0.0007 to 0.04 mass% of the sulfur affinity metal. 上記導体の結晶粒径が270μm以下である請求項1又は2記載の太陽電池用はんだめっき線。   The solder-plated wire for a solar cell according to claim 1 or 2, wherein the conductor has a crystal grain size of 270 µm or less. 請求項1から3いずれかに記載の太陽電池用はんだめっき線と、太陽電池セルをはんだ接続したことを特徴とする太陽電池。   A solar battery comprising the solar battery solder-plated wire according to claim 1 and a solar battery cell connected by soldering. 連続鋳造圧延装置を用いて、銅溶湯から太陽電池用はんだめっき線を製造する方法であって、
上記連続鋳造圧延装置の溶湯貯溜手段に貯溜され、酸素含有量が10massppmを超える銅溶湯に、Nb、Ti、Zr、V、Ta、Fe、Ca、Mg又はNiから選択される1種又は2種以上の硫黄親和性金属を添加し、銅溶湯中に含まれる該硫黄親和性金属の割合を0.0007〜0.04質量%に調整し、その銅溶湯を用いて荒引き材を製造した後、その荒引き材に減面率30%以上の冷間伸線加工を施し、この冷間加工材に190〜750℃で熱処理を施すことを特徴とする太陽電池用はんだめっき線の製造方法。
A method for producing a solar cell solder-plated wire from molten copper using a continuous casting and rolling device,
One or two kinds selected from Nb, Ti, Zr, V, Ta, Fe, Ca, Mg, or Ni in the molten copper stored in the molten metal storage means of the continuous casting and rolling apparatus and having an oxygen content exceeding 10 massppm. After adding the above sulfur-affinity metal, adjusting the ratio of the sulfur-affinity metal contained in the molten copper to 0.0007 to 0.04 mass%, and manufacturing the roughing material using the molten copper A method for producing a solder-plated wire for a solar cell, comprising subjecting the roughened material to cold drawing with a reduction in area of 30% or more, and subjecting the cold-worked material to heat treatment at 190 to 750 ° C.
上記冷間加工材に、400〜750℃で熱処理を施す請求項5記載の太陽電池用はんだめっき線の製造方法。   The manufacturing method of the solder plating wire for solar cells of Claim 5 which heat-processes at 400-750 degreeC to the said cold work material. 上記熱処理を、ヒータによるバッチ式加熱方式もしくは通電加熱方式により行う請求項5又は6記載の太陽電池用はんだめっき線の製造方法。   The manufacturing method of the solder plating wire for solar cells of Claim 5 or 6 which performs the said heat processing by the batch type heating system or electric current heating system with a heater.
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