【発明の詳細な説明】[Detailed description of the invention]
本発明は銅一窒化物系の封入用電気接点材料に
係る。従来、封入用電気接点材料としては、銀系
合金、金系合金、パラジウム系合金などの貴金属
系例えば銀―酸化カドミウム12重量%より成る複
合電気接点材料が小電流乃至中電流域で優れた接
点特性を示すものとして各方面で広く用いられて
きた。然し乍ら、近時電気機器及び電子機器の小
型化により電気接点材料に要求される接点特性が
苛酷になつてきており、従来の銀―酸化カドミウ
ム系の複合電気接点材料では耐溶着性に劣り、使
用に耐えなくなつてきた。この為更に耐溶着性に
優れた封入用電気接点材料が要望されている。
一方貴金属の使用をおさえ安価な接点材料を供
給する為に電気伝導度が銀についで大きく銀より
融点の高い銅に着目し、これを母合金とする接点
材料を使用しようとする試みがなされはじめた。
銅を接点材料として使用する場合銅の耐蝕性が問
題となるが、この問題は銅を真空中あるいは中性
ガス中で使用することにより解決され貴金属を母
合金として用いた場合に比較して何ら遜色のない
特性を示すものである。特に窒化物は融点の高い
材料が多くこれら高融点材料を銅の分散強化材と
して使用した場合、消耗量が小さくまた、溶着力
についても優れた特性を示すことが期待される。
本発明は上記諸事情に鑑みなされたものであり
従来の銀―酸化物系の複合電気接点材料よりも優
れた接点性能、とりわけ優れた消耗特性及び耐溶
着性を有する複合電気接点材料を提供せんとする
ものである。
本発明の封入用電気接点材料は銅中に窒化アル
ミニウム0.3〜11重量%を添加して成るものであ
る。銅中に窒化アルミニウムを添加した理由は窒
化アルミニウムが2200℃という高い融点を有し、
苛酷な条件で使用される接点を強化する充分な性
質を有するからである。
本発明の電気接点材料に於いて、銅中に添加す
る窒化アルミニウムを0.3〜11重量%としたのは、
0.3重量%以下では銅の地が充分に強化されない
為に耐消耗特性、あるいは耐溶着特性に関しては
良好な結果は得られない。また11重量%以上の組
成では加工が困難となり、材料の導電率も低くな
るので良好な結果は得られない。以上の理由によ
り特許請求の範囲に記載した組成を限定したもの
である。
なおこれらの銅―窒化物材料を窒素雰囲気中で
使用した場合さらにすぐれた耐溶着特性を示すも
のである。
実施例・比較例
平均粒径4μの銅粉と窒化アルミニウム粉をV
型混合器により3時間混合した後粉末をルツボに
充てんし所定の密度に達するまで焼結圧縮を繰り
返した材料を熱間で押出した。これを伸線機によ
り線材とした後、ヘツダー機により加工し下表に
示す、実施例1,2,3および比較例1の組成を
有する頭部径4φmm、頭高1.1mm、脚部径2.8φmm、
脚長1.6mmのリベツト型接点を得た。
従来例
銀―カドミウム合金を鋳造後引ぬき伸線加工を
行ないこれをヘツダー機により頭部径4φmm、頭
高1.1mm、脚部径2.8φmm、脚長1.6mmのリベツト形
状に成形した後5気圧800℃で内部酸化を行ない
銀酸化カドミウム12重量%とした。
然して上記実施例1,2,3、従来例、比較例
1の電気接点を下記の試験条件にて開閉試験を行
い、溶着発生までの開閉回数を測定し且つ接触抵
抗、消耗を測定したところ、下記の表の右欄に示
すような結果を得た。
試験条件
電 圧 A.C.100V 50Hz
電 流 投入電流 40A、定常電流 10A
開閉頻度 20回/分
負 荷 抵抗
開閉回数 溶着発生まで
雰囲気 窒素覆囲気
The present invention relates to a copper mononitride-based encapsulating electrical contact material. Conventionally, as electrical contact materials for encapsulation, composite electrical contact materials made of precious metals such as silver alloys, gold alloys, and palladium alloys, such as silver and cadmium oxide at 12% by weight, have been used as contacts that are excellent in the small to medium current range. It has been widely used in various fields to indicate characteristics. However, with the recent miniaturization of electrical and electronic devices, the contact characteristics required of electrical contact materials have become more severe, and conventional silver-cadmium oxide composite electrical contact materials have poor welding resistance and are no longer used. I've become unable to bear it. For this reason, there is a need for an electrical contact material for encapsulation that has even better welding resistance. On the other hand, in order to reduce the use of precious metals and provide inexpensive contact materials, attention has been paid to copper, which has the second highest electrical conductivity after silver and a higher melting point than silver, and attempts have been made to use copper as a mother alloy for contact materials. Ta.
When copper is used as a contact material, corrosion resistance of copper becomes a problem, but this problem is solved by using copper in a vacuum or neutral gas, and it is no more expensive than using precious metals as the mother alloy. It shows comparable characteristics. In particular, many nitrides have high melting points, and when these high melting point materials are used as dispersion reinforcing materials for copper, they are expected to exhibit small consumption and excellent welding strength. The present invention has been made in view of the above-mentioned circumstances, and aims to provide a composite electrical contact material that has superior contact performance, especially superior wear characteristics and welding resistance, than conventional silver-oxide composite electrical contact materials. That is. The electrical contact material for encapsulation of the present invention is made by adding 0.3 to 11% by weight of aluminum nitride to copper. The reason for adding aluminum nitride to copper is that aluminum nitride has a high melting point of 2200℃.
This is because it has sufficient properties to strengthen contacts used under harsh conditions. In the electrical contact material of the present invention, the aluminum nitride added to the copper is 0.3 to 11% by weight.
If it is less than 0.3% by weight, the copper matrix will not be sufficiently strengthened, and good results will not be obtained in terms of wear resistance or welding resistance. In addition, if the composition exceeds 11% by weight, processing becomes difficult and the conductivity of the material becomes low, making it difficult to obtain good results. For the above reasons, the compositions described in the claims are limited. Furthermore, when these copper-nitride materials are used in a nitrogen atmosphere, they exhibit even better welding resistance. Examples/Comparative Examples Copper powder and aluminum nitride powder with an average particle size of 4μ
After mixing in a mold mixer for 3 hours, the powder was filled into a crucible, and the material was hot extruded after repeated sintering and compression until it reached a predetermined density. This was made into a wire with a wire drawing machine, and then processed with a header machine to have the compositions of Examples 1, 2, 3 and Comparative Example 1 as shown in the table below, with a head diameter of 4φmm, a head height of 1.1mm, and a leg diameter of 2.8mm. φmm,
A rivet type contact with a leg length of 1.6 mm was obtained. Conventional example: After casting a silver-cadmium alloy, it was drawn and wire-drawn, and then formed into a rivet shape with a head diameter of 4φmm, head height of 1.1mm, leg diameter of 2.8φmm, and leg length of 1.6mm using a header machine, and then heated to 5 atm 800 Internal oxidation was carried out at ℃ to give 12% by weight of silver cadmium oxide. However, the electrical contacts of Examples 1, 2, 3, Conventional Example, and Comparative Example 1 were subjected to opening and closing tests under the following test conditions, and the number of openings and closings until welding occurred was measured, as well as contact resistance and wear. The results shown in the right column of the table below were obtained. Test conditions Voltage AC100V 50Hz Current Supply current 40A, steady current 10A Switching frequency 20 times/min Load Resistance Switching frequency Until welding occurs Atmosphere Nitrogen surrounding atmosphere
【表】
上記の表の右欄の数値で明らかなように実施例
の電気接点材料にて作つた電気接点は、従来例の
電気接点材料に比し耐消耗性、耐溶着性が優ると
も劣らずかつ安定した低接触抵抗を示すことがわ
かる。
以上詳記した通り本発明による複合電気接点材
料は、従来の銀―酸化カドミウム電気接点材料に
較べ耐溶着性、耐消耗性に優れた性能を示すので
最近の電気及び電子機器の小型化に伴なう苛酷な
使用条件にも対応できる接点性能を備えた画期的
な封入用電気接点材料と言える。[Table] As is clear from the values in the right column of the table above, the electrical contacts made with the electrical contact materials of the examples have superior wear resistance and welding resistance compared to the conventional electrical contact materials. It can be seen that the contact resistance is low and stable. As detailed above, the composite electrical contact material according to the present invention exhibits superior performance in welding resistance and abrasion resistance compared to conventional silver-cadmium oxide electrical contact materials, and is therefore used in conjunction with the recent miniaturization of electrical and electronic equipment. It can be said to be an innovative electrical contact material for encapsulation with contact performance that can withstand even the harshest operating conditions.