【発明の詳細な説明】[Detailed description of the invention]
本発明は封入型マグネツトスイツチ、封入型ブ
レーカー、封入型リレー等の電気接点に用いる材
料に関する。
従来、マグネツトスイツチ、ブレーカー、リレ
ー等の電気接点材料としては、耐溶着性、耐消耗
性に優れた銀−酸化カドミウム系が使用されてき
たが、何分にも材料が高価である為、低廉な銅−
酸化カドミウムの使用が考えられていた。
然し、銅−酸化カドミウムは耐溶着性について
は問題無いが、接触抵抗は銀−酸化カドミウム系
に比べ著しく劣いた。これは接点開閉時のアーク
により、酸化カドミウムが、カドミウムと酸素に
分解し、分解した酸素が地の銅を酸化させてしま
い、このため、接触抵抗が高く、不安定になる。
そしてこのような接触抵抗が高く、不安定な状態
は10〜400Aという中電流域での使用に於いて顕
著に現われる。
本発明はかかる問題を解消すべくなされたもの
であり、高価な銀−酸化カドミウム系より成る電
気接点材料と同等の低接触抵抗、耐溶着性に優れ
た封入用電気接点材料として、前記銅−酸化カド
ミウムより成る封入用電気接点材料にかわる封入
用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、酸化クロム3
〜15w/oと残部銅より成るものである。
本発明の封入用電気接点材料は、従来考えられ
ていた銅−酸化カドミウムより成る封入用電気接
点材料中の酸化カドミウムを酸化クロムに代えた
もので、その添加量を酸化クロム3〜15w/oと
した理由は、接点開閉時のアークにより、酸化カ
ドミウムよりも分解しにくい酸化クロムを用い、
銅の地の酸化を防止し、接触抵抗を安定させる為
で、酸化クロム3w/o未満では耐溶着性不充分
であり、また酸化クロム15w/oを超えると酸化
クロムにより接触抵抗が高く、不安定になるから
である。上記成分範囲内であれば、銅−酸化クロ
ムに更に少量の鉄、ニツケル、コバルト、マンガ
ン、チタニウム又はこれらの酸化物を添加しても
特性は阻害されないものである。
以下本発明の封入用電気接点材料の効果を明瞭
ならしめる為に、その具体的な実施例の封入用電
気接点材料と従来例の封入用電気接点材料により
作つた封入用電気接点の耐溶着性、接触抵抗につ
いて述べる。
実施例 1
重量比で銅粉末95%、酸化クロム粉末5%を混
合圧縮して30mm口×150mmの圧粉体を作り、こ
れを真空中900℃で焼結し、然る後溝ロール加圧
と真空中900℃の熱処理を繰返し、100mm口の棒に
なつたところで真空中900℃で熱処理し、スエジ
ング加工と真空中900℃の熱処理を繰返して5.0mm
φの銅−酸化クロム5.0w/oより成る線材とな
し、更にこの線材を旋盤加工により頭部4mmφ×
1.2mmtのリベツトとなした。
実施例 2
重量比で銅粉末90%、酸化クロム粉末10%、を
混合圧縮して30mm口×150mmの圧粉体を作り、
これを窒素ガス雰囲気中900℃で焼結し、然る後
溝ロール加工と窒素ガス雰囲気中900℃の熱処理
を繰返し、10mm口の棒になつたところで、窒素ガ
ス雰囲気中900℃で熱処理し、スエージング加工
と窒素ガス雰囲気中900℃の熱処理を繰返して5.0
mmφの銅−酸化クロム10w/oより成る線材とな
し、更にこの線材を旋盤加工により頭部4mmφ×
1.2mmtのリベツトとなした。
従来例 1
Cu粉末88w/oとCdO粉末12w/oを混合圧縮
して30mm口×150mmの圧粉体を作り、これを窒
素ガス雰囲気中830℃で焼結し、然る後溝ロール
加工と窒素ガス雰囲気中830℃の熱処理を繰返し、
10mm口の棒になつたところで、窒素ガス雰囲気中
830℃で熱処理し、スエージング加工と窒素ガス
雰囲気中830℃の熱処理を繰返して5mmφのCu−
CdO12w/oより成る線材となし、更にこの線材
を旋盤加工により頭部4φmm×1.2mmtのリベツト
となした。
従来例 2
Ag中にCd11w/o溶解してAg−Cd合金の2.3
mmφ×2.3mmの粒を作り、これを酸素ガス雰囲
気中7気圧800℃で内部酸化してAg−CdO12w/
oの粒となし、然る後この粒を圧縮、焼結、押圧
加工し、次いで線引加工と大気中700℃の熱処理
を繰返して2mmφのAg−CdO12w/oより成る
線材となし、更にこの線材をヘツダー加工により
頭部4mmφ×1.2mmtのリベツトとなした。而し
て市販のヒンジ型リレーに固定、可動接点をベー
スにかしめ付け、試験用リレーを作りこれを夫々
真空又は不活性ガス(N2、Ar、N2−H2、Ar−
H2、He、N2−O2、Ar−O2、CO2、N2−CO2、
Ar−CO2、CO2−O2)充填容器、本例ではArガ
ス充填容器中に封入して、下記の試験条件にて開
閉試験を行ない電気接点の溶着回数及び接触抵抗
を測定した処、下記の表に示すような結果を得
た。
試験条件
負 荷 抵抗2段切換
電 圧 100V
周波数 50Hz
電 流 投入電流40A
定常電流10A
開閉頻度 20回/分
通電時間 0.62秒
休止時間 2.35秒
接触力 20g
開離力 40g
開閉回数 5万回
The present invention relates to materials used in electrical contacts such as encapsulated magnetic switches, encapsulated breakers, encapsulated relays, and the like. Conventionally, silver-cadmium oxide based materials have been used as electrical contact materials for magnetic switches, breakers, relays, etc. due to their excellent welding and abrasion resistance, but since the materials are extremely expensive, Cheap copper
The use of cadmium oxide was considered. However, although copper-cadmium oxide had no problem in welding resistance, its contact resistance was significantly inferior to that of silver-cadmium oxide. This is because cadmium oxide decomposes into cadmium and oxygen due to the arc generated when the contacts are opened and closed, and the decomposed oxygen oxidizes the underlying copper, resulting in high contact resistance and instability.
Such high contact resistance and unstable conditions become noticeable when used in the medium current range of 10 to 400 A. The present invention has been made to solve this problem, and uses the copper-cadmium oxide-based electrical contact material as an encapsulating electrical contact material that has the same low contact resistance and excellent adhesion resistance as the expensive silver-cadmium oxide electrical contact material. It is an object of the present invention to provide an encapsulating electrical contact material that can replace the encapsulating electrical contact material made of cadmium oxide. The electrical contact material for encapsulation of the present invention is chromium 3 oxide
It consists of ~15w/o and the balance copper. The electrical contact material for encapsulation of the present invention replaces the cadmium oxide in the electrical contact material for encapsulation made of copper-cadmium oxide, which was conventionally considered, with chromium oxide, and the amount of chromium oxide added is 3 to 15 w/o. The reason for this is that chromium oxide is used, which is more difficult to decompose than cadmium oxide due to arcing when the contacts are opened and closed.
This is to prevent oxidation of the copper base and stabilize the contact resistance. If the content is less than 3w/o of chromium oxide, the welding resistance will be insufficient, and if it exceeds 15w/o of chromium oxide, the contact resistance will be high due to the chromium oxide, resulting in failure. This is because it becomes stable. As long as the components are within the above range, the properties will not be impaired even if a small amount of iron, nickel, cobalt, manganese, titanium, or oxides thereof are added to the copper-chromium oxide. In order to clarify the effects of the electrical contact material for encapsulation of the present invention, the welding resistance of electrical contacts for encapsulation made from the electrical contact material for encapsulation of specific examples and the electrical contact material for encapsulation of the conventional example will be described below. , we will discuss contact resistance. Example 1 95% copper powder and 5% chromium oxide powder by weight were mixed and compressed to make a 30mm opening x 150mm green compact, which was sintered at 900°C in a vacuum and then pressed with a trailing groove roll. Heat treatment at 900℃ in vacuum is repeated, and when the rod has a diameter of 100 mm, it is heat treated at 900℃ in vacuum, swaging processing and heat treatment at 900℃ in vacuum are repeated, and the length is 5.0 mm.
A wire rod made of copper-chromium oxide 5.0w/o with a diameter of 5.0 w/o is made, and then this wire is machined on a lathe to a head size of 4 mmφ
Made with 1.2mmt rivets. Example 2 90% copper powder and 10% chromium oxide powder by weight were mixed and compressed to make a green compact with a diameter of 30 mm x 150 mm.
This was sintered at 900°C in a nitrogen gas atmosphere, followed by repeated groove rolling and heat treatment at 900°C in a nitrogen gas atmosphere, and when it became a rod with a diameter of 10 mm, it was heat treated at 900°C in a nitrogen gas atmosphere. 5.0 by repeating swaging processing and heat treatment at 900℃ in a nitrogen gas atmosphere.
A wire rod made of copper-chromium oxide 10w/o of mmφ is made, and then this wire is lathed to a head of 4mmφ×
Made with 1.2mmt rivets. Conventional example 1 Cu powder 88w/o and CdO powder 12w/o are mixed and compressed to make a 30mm opening x 150mm green compact, which is sintered at 830℃ in a nitrogen gas atmosphere, followed by subsequent groove rolling. Repeated heat treatment at 830℃ in nitrogen gas atmosphere,
When the rod has a 10 mm opening, place it in a nitrogen gas atmosphere.
Heat treated at 830℃, swaging process and heat treatment at 830℃ in a nitrogen gas atmosphere were repeated to form a 5mmφ Cu-
A wire rod made of CdO12w/o was made, and this wire rod was further processed on a lathe to form a rivet with a head size of 4φmm x 1.2mmt. Conventional example 2 2.3% of Ag-Cd alloy is made by dissolving Cd11w/o in Ag.
Ag-CdO12w/
The particles were then compressed, sintered, and pressed, and then wire drawn and heat treated at 700°C in the atmosphere were repeated to produce a wire rod of 2 mmφ made of Ag-CdO12w/o. The wire rod was processed into a rivet with a head size of 4 mmφ x 1.2 mmt by header processing. The fixed and movable contacts were then caulked to the base of a commercially available hinge-type relay, and a test relay was made, and each relay was exposed to vacuum or inert gas (N 2 , Ar, N 2 −H 2 , Ar−
H2 , He, N2 - O2 , Ar- O2 , CO2 , N2 - CO2 ,
Ar-CO 2 , CO 2 -O 2 ) was sealed in a container filled with Ar gas (in this example, an Ar gas-filled container), and an opening/closing test was conducted under the following test conditions to measure the number of times the electrical contacts were welded and the contact resistance. The results shown in the table below were obtained. Test conditions Load 2-step resistance switching Voltage 100V Frequency 50Hz Current Closing current 40A Steady current 10A Opening/closing frequency 20 times/minute Energizing time 0.62 seconds Rest time 2.35 seconds Contact force 20g Breaking force 40g Number of opening/closing 50,000 times
【表】
上記の表で明らかなように実施例1、2のリレ
ーに於ける電気接点は、従来例1のリレーに於け
る電気接点よりも溶着回数が少なく且つ接触抵抗
が低く、また従来例2のリレーに於ける高価な電
気接点と同等に溶着回数が少なく且つ接触抵抗が
低く、耐溶着性及び接触抵抗特性に優れているこ
とが判る。
以上詳記した通り本発明の封入用電気接点材料
は、貴金属を全く使用しない安価な材料であつ
て、しかも銀−酸化カドミウムより成る高価な封
入用電気接点材料と同等の優れた耐溶着性及び低
接触抵抗特性を有するので、これにとつて代わる
ことのできる画期的な封入用電気接点材料と言え
る。[Table] As is clear from the table above, the electrical contacts in the relays of Examples 1 and 2 have fewer welding times and lower contact resistance than the electrical contacts in the relay of Conventional Example 1. It can be seen that the number of times of welding is small and the contact resistance is as low as the expensive electrical contacts in relay No. 2, and the welding resistance and contact resistance characteristics are excellent. As detailed above, the electrical contact material for encapsulation of the present invention is an inexpensive material that does not use any precious metals, and has excellent welding resistance and properties equivalent to the expensive electrical contact material for encapsulation made of silver-cadmium oxide. Since it has low contact resistance characteristics, it can be said to be an innovative electrical contact material for encapsulation that can replace this.