EP0365879B1

EP0365879B1 - Electric contact with base metal

Info

Publication number: EP0365879B1
Application number: EP19890118329
Authority: EP
Inventors: Mitsuo C/O Fuji Electric Co. Ltd. Sunaga; Kiyoshi C/O Fuji Electric Co. Ltd. Sekiguchi; Hisaji C/O Fuji Electric Co. Ltd. Shinohara; Akihiro C/O Fuji Electric Co. Ltd. Takahashi; Hiroshi C/O Fuji Electric Co. Ltd. Hikita; Takashi C/O Tokuriki Honten Co. Ltd. Nara; Sadao C/O Tokuriki Honten Co. Ltd. Sato
Original assignee: Tokuriki Honten Co Ltd; Fuji Electric Co Ltd
Current assignee: Tokuriki Honten Co Ltd; Fuji Electric Co Ltd
Priority date: 1988-10-03
Filing date: 1989-10-03
Publication date: 1996-01-03
Anticipated expiration: 2009-10-03
Also published as: DE68925337D1; EP0365879A2; DE68925337T2; EP0365879A3

Description

BACKGROUND OF THE INVENTION

Field of the Invention

The present invention relates to an electric contact with a base metal for use in a current switch, such as an electromagnetic contactor.

Description of the Related Art

As is known, so-called non-oxide contact materials of Ag and Ag-Ni, or Ag-oxide contact materials in which an oxide including Cd, Sn, Sb, In, zn, Hn, Te, or the like is dispersed in Ag can be used as an electric contact (hereinafter referred to as "contact") with a base metal in a current switch. In particular, the Ag-oxide contact material exhibits excellent contact characteristics in view of deposition- and wear-resistance and, therefore, is employed mainly in a medium load range.
With the marked progress of rationalization and automation in every industrial field, mechanical equipment tends to be large and complicated. The requirements for switches for governing control over such machinery, on the other hand, include being compact in size, large in capacity, and able to withstand frequent operation. Because of frequent switching operation of equipment, the switch contact dramatically heats up to the extent that the contact is locally fused by arc and electrically-induced heat. Then, when it is out of operation, the contact is cooled down to the room temperature. The contact is, therefore, subjected to repetitions of heating and cooling cycles.
Normally, the contact is joined to a base metal when used for a switch. The contact is joined metallurgically by brazing or resistance welding.
When the contact is formed by brazing, the base metal is softened since the base metal and the contact have to be heated at high temperatures. The thickness of the base metal also has to be increased. Using the brazing method, therefore, is undesirable for reducing the switch in size. Moreover, the brazing method is unfit for mass production of switches because the automated operation of joining contacts and base metals is difficult.
A resistance welding method is superior to the brazing method because with resistance welding the base metal in lees affected by heat, and the operation can be automated. Current is passed across the joint between the contact material and the base metal, and causes the material to be joined instantaneously. The contact material joined to the base metal by resistance welding is subsequently compression-molded vertically into a round or square contact.
Fig. 34 shows a process of joining a contact material to a base metal by resistance welding. Fig. 35 shows a contact formed by die forging of the contact material thus joined by resistance welding. In Fig. 34, a contact material 1 prepared by cutting a circular wire is laid in place on a base metal 2. Current then flows between electrodes 4A and 4B with the contact material 1 and the base metal 2 held therebetween. Due to contact resistance, electrically-induced heat is generated in the joint between the contact material 1 and the base metal 2. Thus, the joint is fused so as to weld the contact material 1 to the base metal 2 within a range of weld metal zone 3. The contact material 1 joined to the base metal 2 by resistance welding is vertically compressed by means of a mold (not shown) into a disc-like contact 5 shown in Fig. 35.
Despite the advantage over the brazing method in being more easily automated anti highly productive, it is still difficult to join the whole surface of the contact to the base metal by resistance welding. As is obvious from Fig. 35, the weld metal zone 3 exists only in the central portion of the contact 5 subjected to die forging. Therefore, if a large current is repeatedly turned on and off through the contact joined by resistance welding incorporated in an electromagnetic contactor, the contact 5 peels off the base metal 2, as shown in Fig. 36.
in Fig. 36, numerals 5 and 6 designate a fixed and a moving contact, respectively. The contact 5 is heated by an arc 7 when the contacts 5 and 6 are separated and contact 5 is cooled after the arc 7 is extinguished. However, the surface of the contact contracts during the course of cooling and consequently the force resulting from the concentration of the heat at the center is applied to the outer periphery of the contact 5 in such a direction as to make the outer periphery thereof peel off. Once the peeling starts, transmission of heat to the base metal 2 diminishes and this causes the contact 5 to be increasingly heated and peeled off. Ultimately, the contact may undergo abnormal wear or drop off from the basemetal 2. The arc is often driven by a magnetic force in a fixed direction (e.g., in the direction of arrow P of Fig. 36) during the period between its generation and ternination. In this case, contact peeling tends to be biased toward the terminal end of the movement of the arc.
One solution to the problem of increasing the contact area is to use a large welding current. If, however, the welding current is increased, the wear of the electrodes used to supply the current also increases. As a result, the electrodes will need frequent repairs and high productivity will deteriorate.
Contact materials of Ag-oxide, such as Ag-CdO and Ag-SnO₂ are preferred materials. These Ag-oxide contact materials feature high arc-resistance and, therefore, high adaptability for use against a large current. Thus, the joint strength is much lower than that of non-oxide contact materials because of the presence of an interfacial oxide formed with the base metal by the Ag-oxide materials. However, Ag-oxide materials tend to readily allow contacts to peel off. The peeling may be reduced by providing a silver backing layer for a contact chip to which a base metal is joined by brazing. However, this method is difficult and cannot be automated.
A method of bonding silver-based contact is known from US-PS 4 523 711. Hereby the contact made of an Ag-CdO layer and an unoxidised Ag-Cd layer is placed on a support and the contact and the support are heated in a nitrogen atmosphere at 750°C.
A method of manufacturing an electric contact having the features of the first part of claim 1 is known from US-PS 4 099 043.
Accordingly, the object of the present invention is to provide a method of manufacturing a peeling-resistant electric contact made by joining a contact material to a base metal, having a contact promoting shape, by resistance welding which less thermally affects the base metal but yields excellent automated production capabilities.
Another object of the present invention is to provide a peeling-resistant electric contact made by joining to a base metal, having a contact promoting shape, a contact material made of Ag-oxide contact material which exhibits excellent electrical characteristics.
To achieve the foregoing objects, and in accordance with the purposes of the invention as embodied and broadly described herein, there is provided an electric contact with a base metal, having a contact promoting shape, the combination of which is formed by die forging of a contact material joined to the base metal by resistance welding the contact material to the contact promoting shape of the base metals at least one side of the contact material in contact with the base metal is formed of non-oxide contact material and bites into the base metal.
Additional objects and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objects and advantages of the invention may be realized and obtained by means of the instrumentalities and combinations particularly pointed out in the appended claims.
The contact material subjected to die forging fills a groove or hole preformed in the base metal close to a weld zone where the base metal and the contact material are welded together. The groove may be a series of dots.
The contact material also may be welded to protrusions preformed in a weld zone of the base metal to which the contact material is welded. In another embodiment, the contact material may be welded to the bottom of a cut preformed in and laterally across the base metal. Thus, each periphery of the contact material subjected to die forging will contact the interior wall of the cut that is most vertical and the peel resistance effect of the contact is improved. Finally, the contact material may be welded to bottoms of recesses preformed in the contact-fitting portion of the base metal. As with the previous example, each periphery of the contact material subjected to die forging will contact the interior wall of the recess that is most vertical.
A composite wire may be employed as the contact material to improve deposition- and wear-resistance. The composite wire is prepared by coating the outer periphery of a core material made of Ag-metallic oxide contact material with the non-oxide contact material. The sectional area of the non-oxide contact material may account for 5% to 35% of the total sectional area of the composite wire, as will be discussed later. Moreover, the surface layer for switching purposes should be ground after die forging to expose the core material.
Only the central portion of the contact subjected to die forging is joined to the base metal after the contact material has been welded by resistance welding. The non-welded peripheral portion of the contact peels off if the thermal distortion of the surface causes it to deform in the form of a concave contact element. If part of the periphery of the central weld zone bites into the base metal, however, the periphery is prevented from peeling off as that portion biting into the base metal hooks when the bending deformation occurs. In order to make the periphery of the contact bite into the base metal, part of the contact material should be pressed to fill holes or grooves preformed in the base metal close to a weld zone where the base metal and the contact material are welded together.
The joint surface of the contact material that joins the base metal should at least be formed of non-oxide contact material of Ag, Ag-Ni, or the like. This will secure the welding strength of the central portion of the contact. The portion biting into the base metal on the periphery of the contact resists the force applied in the direction in which it is to deform around the weld zone. However, that portion shows no resistance against the force applied in the axial direction in which it slips out after the weld zone has peeled off. If the surface of the contact material that joins the base metal is formed of a flexible Ag or Ag alloy, however, the contact material will readily fill the grooves or holes formed in the base metal, and the biting performance will be improved.
Only a non-oxide contact material of Ag, Ag-Ni, or the like may be used as the contact material to form the contact. Although the intended joint strength of the contact is improved, the electric switching performance is adversely affected. Restriction as to operating conditions, therefore, must be taken into consideration.
In view of the above, the making-breaking surface of the contact is formed of Ag-oxide contact material such as Ag-CdO, Ag-SnO₂, or the like and the joint surface with the base metal is formed of non-oxide contact material such as Ag, Ag-Ni, or the like. Thus, both the electric switching performance and joint strength are improved.
As explained earlier, a composite wire dray be used as the contact material. It is preferred to use a composite wire prepared by coating the outer periphery of a core material made of Ag-oxide contact material as the contact material with the non-oxide contact material. The provision of such a composite wire improves weldability of the contact to the base metal because of the Ag or Ag alloy on the outer periphery of the core material and further the contact material after welding is easily bitten into the base metal at die forging. The composite wire also facilitates the fabrication of the contact since the outer periphery of the hard Ag-oxide contact material is coated and protected with the Ag or Ag alloy.
The sectional area of the non-oxide contact material is set at 5% to 35%, If the percentage is set at not higher than 5%, the core material may be exposed at the time of welding. Furthermore, decreasing the amount of contact material biting into the base metal decreases the joint strength. On the other hand, if the percentage is set at not lower than 35%, the excessive Ag or Ag alloy content decreases the deposition-resistance contact characteristics. With the percentage of non-oxide material set at 5% to 35%, the surface layer for switching purposes is ground to have the core material exposed after the contact material is subjected to die forging. Moreover, the deposition-resistance is further improved when composite wire is employed.
The provision of protrusions in the weld zone where the contact material is welded to the base metal assures that the point at which an electric current starts to flow is constant. Therefore, the welding strength is stabilized.
The contact material may be welded to the bottom of a cut preformed in and laterally across the contact-fitting portion of the base metal or to recesses preformed therein so that each periphery of the compression-molded contact material is forced to contact the inner wall of the recess. This arrangement is advantageous in that the peeling of the contact material is prevented because each peripheral edge is pressed by the wall face when it is forced to curve in the form of a bow.
The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate the presently preferred embodiments of the invention and, together with the general description given above and the detailed description of the preferred embodiments given below, serve to explain the principles of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1(A) is a section view of example 1 of the present invention;
Fig. 1(B) is an enlarged view of a portion B of Fig, 1(A);
Fig. 2 is a sectional view of the contact material of the contact of Fig. 1 joined to a base metal by resistance welding;
Fig. 3(A) is a sectional view of example 2 of the present invention;
Fig. 3(B) is an enlarged view of portion B of Fig. 3(A);
Fig. 4 is a sectional view of the contact material of the contact of Fig. 3 joined to the base metal by resistance welding;
Fig. 5 is an enlarged photograph illustrating metal composition of the groove in section B of Fig. 3;
Fig. 6 is a perspective view of the principal part of a base metal of example 3 of the present invention;
Fig. 7 is a perspective view of the principal of a base metal of example 4 of the present invention;
Fig. 8 is a perspective view of the principal part of a base metal of example 5 of the present invention;
Fig. 9 is a perspective view of the principal part of a base metal of example 6 of the present invention;
Fig. 10 is a sectional view of a contact material of example 7 of the present invention;
Fig. 11 is a sectional view of the compression-molded contact material of Fig. 10;
Fig. 12 is a perspective view of the base metal of Fig. 10;
Fig. 13 is a perspective view of the principal part of a base metal of example 8;
Fig. 14 is a perspective view of the principal part of a base metal of example 9;
Fig. 15 is a perspective view of the principal part of a base metal of example 10;
Fig. 16 is a perspective view of the principal part of a base metal of example 11;
Fig. 17 is a perspective view of the principal part of a base metal of example 12;
Fig. 18 is a sectional view of the contact material of example 13 joined to a base metal by welding according to the present invention;
Fig. 19 is a sectional view of the compression-molded contact material of Fig. 18;
Fig. 20 is a perspective view of the principal part of the base metal of Fig. 18;
Fig. 21 is a perspective view of the principal part of a base metal of example 14;
Fig. 22 is a perspective view of the principal part of a base metal of example 15;
Fig. 23 is a perspective view of the principal part of a base metal of example 16;
Fig. 24 is a sectional view of a contact material of example 17 joined to the base metal,
Fig. 25(A) is a sectional view of the compression-molded contact material of Fig. 24;
Fig. 25(B) is an enlarged view of portion B of Fig. 25(A);
Fig. 26 is a perspective view of the principal part of a base metal of Fig. 24 and example 19 according to the present invention;
Fig. 27 is a perspective view of the principal part of the base metal of examples 18 and 20 according to the present invention,
Fig. 28 is a perspective view of the principal part of the base metal of examples 21 and 23 according to the present invention;
Fig. 29 is a perspective view of the principal part of the base metal of examples 22 and 24 according to the present invention;
Fig. 30 is a sectional view of a contact material of example 25 joined to the base metal according to the present invention;
Fig. 31 is a sectional view of the compression-molded contact material of Fig. 30;
Fig. 32 is a perspective view of the principal part of the base metal of example 27 according to the present invention;
Fig. 33 is a perspective view of the principal part of the base metal of examples 26 and 28 according to the present invention;
Fig. 34 is a sectional view illustrating the contact material joined by resistance welding;
Fig. 35 is a sectional view of the compression-molded contact material of Fig. 34; and
Fig. 36 is a side view illustrating the condition in which a conventional contact is caused to peel off the base metal.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Reference will now be made in detail to the present preferred embodiments of the invention as illustrated in the accompanying drawings.

Example 1

As shown in Fig. 2, contact material 1 is prepared by cutting an Ag-Ni wire 2.6 mm in diameter to a length of 2.6 mm and laying it on a base metal 2 of 1.5 mm thick and 7.0 mm wide with grooves 8 provided close to a weld zone where the contact material 1 is welded. Contact material 1 is welded to the base metal 2 within a range of weld zone 3 by supplying power between electrodes 4A, 4B, as shown in Fig. 2. Contact material 1 is then subjected to die forging by means of a mold to make round contact 9 of 4.7 mm diameter having a flat surface as shown if Fig. 1. In Fig. 1, the contact material 1 after die forging bites into the groove 8, by pressing the contact material to fill the groove 8.
Two kinds of grooves 8 are provided in the base metal 2 as follows: two V-shaped grooves, each being 0.4 mm deep and 0.8 mm wide, are provided on both sides of contact material 1 at an interval of 3 mm as shown, and a ring-like V-shaped groove similar in depth and width and having a diameter of 3 mm is provided around the contact material 1. In addition, a base metal similar in dimensional conditions to the aforementioned samplers, but free of grooves, are prepared at the same time.
These three kinds of contacts were incorporated as fixed contacts in their respective electromagnetic contactors having a rated current of 20 A and subjected to testing at 200 V, 115A. A contact having no grooves was similarly tested. The contact having no grooves started falling off at about 20,000 switchings, whereas the examples of the present invention, having the grooves, did not fall off until after 35,000 switchings.

Example 2

Figs. 3 and 4 correspond to Example 2. Plus, Fig. 5 is an enlarged photograph illustrating the metal composition of the groove in section. Unlike Example 1, a composite wire of 2.6 mm in diameter, prepared by joining a silver covering material 1b 0.1 mm thick to a core material 1a of Ag-CdO, is used as contact material 1. Base metal 2, grooves 8, and contact 9 after die forging are similar to those in Example 1 in dimensions and shapes, etc.
As shown in the photograph of the groove in section, part of contact material 1, particularly silver covering material 1b is seen to have completely bitten into groove 8.
In Examples 1 and 2, the outer wall surface of groove 8 shown in Fig. 1(B) and Fig. 3(B), respectively, makes an angle of α, which is approximately 90° to the surface of the base metal. The derivation of angle α from 90° should be as small as possible to increase the peel resistant effect. If the angle α exceeds 90°, the groove may readily be formed by punching. On the other hand, if the angle α is not greater than 90°, the contact material becomes virtually impossible to process. The peel resistant force of the contact generated at the time of current switching is affected by the size of current, the switching frequency, the size of contact, the material quality of the contact and so on. The angle α, therefore, should be determined in consideration of the relationship between those conditions and the processability of the groove.
Although two parallel grooves and a ring-like groove are shown in Examples 1 and 2, the provision of only one groove on the side where the driven arc is terminated, is still effective, provided the direction of the driven arc is constant. Whether the number of grooves is increased should be determined after considering what the angle α will be. Moreover, silver is used in Examples 1 and 2 as coating 1b of the non-oxide contact material. However, silver alloy, which is weldable and softer than core material 1a also may be used because coating 1b is used mainly to improve the weldability of contact material 1 and to help it to bite into the groove 8.
Combinations of various composite contact materials and base metals in different shapes will be now discussed to compare the use of Ag-oxide contact material.

Composite Material (i)

A total of 10,000 g, 8,670 g of Ag and 1,330 g of Cd, are melted in a high-frequency dissolver and the molten material is reduced by water-atomizing to a powder 86.7% Ag-Cd alloy. The resulting powdor is subjected to internal oxidation and formed into a round bar 80 mm in diameter and 200 mm long before being sintered.
This billet is heated at 800°C in the atmosphere and then extruded by a hot extruder into a round bar 20 mm in diameter. The quantitative analysis value of Ag at this time is approximately 85,0% (85Ag-CdO) because of an increase in oxygen.
The round bar of Ag-CdO is fitted into an Ag pipe 1.0 mm thick and 20.1 mm in inner diameter before being heated at 800°C. Hot working is then employed to join Ag and Ag-CdO into a composite round bar.
This round composite bar is repeatedly annealed and swagged to prepare a composite wire 3.0 mm in diameter. The ratio of the Ag layer area to the total sectional area of the composite wire will be approximately 17%.
This composite wire is cut to a length of 3 mm to provide composite contact material (i).

Composite Material (ii)

A total of 10,000 g, 9,000 g of Ag powder and 1,000 g of oxidized Sn powder, are mixed by a V-type mill and the mixture is formed into a round bar 80 mm in diameter and 200 mm long before being sintered.
This billet is heated at 850°C in the atmosphere and then extruded by a hot extruder into a round bar 20 mm in diameter (90Ag-SnO₂).
The round bar of Ag-SnO₂ is fitted into a 99.8 wt% Ag-Ni alloy pipe 2 mn thick and 20.1 mm inner diameter before being heated at 850°C. Hot working is then employed to join Ag and Ag-SnO₂.
This round composite bar is repeatedly annealed and swagged to prepare a composite wire 3.0 mm in diameter. The ratio of the Ag alloy layer area to the total sectional area of the composite wire will be approximately 30%. This composite wire is cut to a length of 3 mm to provide composite contact material (ii).

Composite Material (iii)

A total of 10,000 g, 9,120 g of Ag and 880 g of Cd, are melted in a high-frequency dissolver and the molten material is reduced by water-atomizing to powder 91.2% Ag-Cd alloy. The resulting powder is subjected to internal oxidation and formed into a round bar 80 mm in diameter and 200 mm in length before being sintered.
This billet is heated at 800°C in the atmosphere and then extruded by a hot extruder into a round bar 20 mm in diameter. The quantitative analysis value of Ag at this time will be approximately 90% (90Ag-CdO) because of an increase in oxygen.
The round bar of Ag-CdO is fitted into an Ag pipe 1.5 mm thick and 20.1 mm in inner diameter before being heated at 800°C. Hot working is then employed to join Ag and Ag-CdO in to a composite round bar.
This round composite bar is repeatedly annealed and swagged to prepare a composite wire 3.0 mm in diameter. The ratio of the Ag layer area to the total sectional area of the composite wire will be approximately 24%.
This composite wire is cut to a length of 3 mm to provide a composite contact material (iii).

Composite Material (iv)

A total of 10,000 g, 8,800 g of Ag of powder, 800 g of oxidized Cd powder and 400 g of oxidized Sn powder, are mixed by the V-type mill and the mixture is formed into a round bar 80 mn in diameter and 200 mm long before being sintered. This billet is heated at 850°C in the atmosphere and then extruded by a hot extruder into a round bar 20 mm in in diameter (88Ag-8CdO-SnO₂).
The round bar of Ag-CdO-SnO₂ is fitted into a 99.5 wt% Ag-Cu alloy pipe 0.5 mm thick and 20.1 mm in inner diameter before being heated at 850°C. Hot working is then employed to join Ag-Cu and Ag-CdO-SnO₂.
This round composite bar is repeatedly annealed and swagged to prepare a composite wire 3.0 mm in diameter. The ratio of the Ag alloy layer area to the total sectional area of the composite wire will be approximately 9%.
This composite wire is cut to a length of 3 mm to provide composite contact material (iv).

Composite Material (v)

A total of 10,000 g, 8,800 g of Ag and 1,200 g of Cd, are melted in a high-frequency dissolver and the molten material is reduced by water-atomizing to powder 88.0% Ag-Cd alloy. The resulting powder is subjected to internal oxidation and formed into a round bar 80 mm in diameter and 200 mm in length before being sintered.
This billet is heated at 800°C in the atmosphere and then extruded by a hot extruder into a round bar 20 mm in diameter. The quantitative analysis value of Ag at this time is approximately 86.5% (86.5Ag-CdO) because of an increase in oxygen
The round bar of Ag-CdO is fitted into an Ag pipe 1.0 mm thick and 20.1 mm in inner diameter before being heated at 800°C.
This round composite bar is repeatedly annealed and swagged to prepare a composite wire 3.0 mm in diameter. The ratio of the Ag layer area to the total sectional area of the composite wire will be approximately 9%.
This composite wire is cut to a length of 3 mm to provide composite contact material (v).

Composite Material (vi)

A total of 10,000 g, 8,800 g of Ag powder and 1,200 g of oxidized Sn powder, are mixed by the V-type mill and the mixture is formed into a round bar 80 nm in diameter and 200 mm long before being sintered. This billet is heated at 850°C in the atmosphere and then extruded by a hot extruder into a round bar 20 mm in diameter (88Ag-SnO₂).
The round bar of Ag-SnO₂ is fitted into a 99.5 wt% Ag-Ni alloy pipe 2 mm thick and 20.1 mm in inner diameter before being heated at 850°C. Hot working is then employed to join Ag-Ni and Ag-SnO₂.
This round composite bar is repeatedly annealed and swagged to prepare a composite wire 3.0 mm in diameter. The ratio of the Ag alloy layer area to the total sectional area of the composite wire is approximately 30%. This composite wire is cut to a length of 3 mm to provide a composite contact material (vi).
Although Ag-Cdo and Ag-SnO₂ are discussed as the core materials for the contact materials i-vi, use can be made of Ag-oxide contact materials containing various oxides including Cd, Sn, Sb, In, zn, Mn, Te, Bi, etc.

Comparative Contact Materials

In the preparation of the aforementioned composite materials (i)-(vi), core materials made of Ag-oxide contact material were made into comparative contacts a, b, c, d, e, and f in the form of a wire 3 mm in diameter. The comparative examples were made by repeatedly annealing and extruding the material into the round bar 20 mm in diameter of 85Ag-CdO as a, 90Ag-SnO₂ as b, 90Ag-CdO as c, 88Ag-8CdO-SnO₂ as d, 86.5 Ag-CdO as e, Or 88Ag-SnO₂ as f and cutting to a length of 3 mm. As will be discussed, Examples 3-6 using contact material (i)-(iv) were compared with examples using comparative contact material a-f.

Example 3

As shown in Fig. 6, two V-shaped grooves 8, 0.5 mn deep x 1.0 mm wide x 3.0 mm long are made in the base metal 2, 1.5 mm thick x 7.0 mm wide at a 3 mm interval. The aforementioned contact material (i) is joined to the base metal by resistance welding and the contact material is subjected to die forging into a substantially square contact 0.8 mm thick x 5.0 mm wide. Further, the switching surface of the contact is ground to expose the Ag-CdO layer.

Example 4

As shown in Fig. 7, two pairs of V-shaped grooves 8, 0.1 mn deep x 0.75 mm wide x 5,0 mm long are made in the base metal 2, 1.5 mm thick x 7.0 mm wide at a 2 mm interval. The aforementioned contact material (ii) is joined to the base metal by resistance welding and the material is subjected to die forging into a substantially square contact 0.8 mm thick x 5.0 mm wide. Further, the switching surface of the contact is ground to expose the Ag-SnO₂ layer.

Example 5

As shown in Fig. 8, four V-shaped grooves 8, 0.7 mm deep x 0.2 mm wide x 3.0 mm long are made in the base metal 2, 1.5 mm thick x 7.0 mm wide at a 2 mm interval in a square form. The aforementioned contact material (iii) is joined to the base metal by resistance welding and the material is subjected to die forging into a substantially square contact 0.8 mm thick x 5.0 mm wide. Further, the switching surface of the contact is ground to expose the Ag-CdO layer.

Example 6

As shown in Fig. 9, four V-shaped grooves 8, 0.5 mm deep x 1.2 mm wide x 2.8 mm long are made in the base metal 2, 1.5 mm thick x 7.0 mm wide at a 2 mm interval in a ring form. The aforementioned contact material (iv) is joined to the base metal by resistance welding and the material is subjected to die forging into a substantially square contact 0.8 mm thick x 5.0 mm wide per side. Further, the switching surface of the contact is ground to expose the Ag-CdO-SnO₂ layer.

Comparative Example 3

A comparative example of a contact material a was welded to a base metal 2 of Fig. 6 and ground as in the case of Example 3.

Comparative Example 4

A comparative example of a contact material b was was welded to the base metal 2 of Fig. 7 and ground as in the case of Example 4.

Comparative Example 5

A comparative example of a contact material c was welded to the base metal 2 of Fig. 8 and ground as in the case of Example 3.

Comparative Example 6

A comparative example of a contact material d was welded to the base metal 2 of Fig. 9 and ground as in the case of Example 4.
The contacts thus obtained were incorporated in commercially available electromagnetic contactors (read at 20 A), and switched on and off 20,000 times under the conditions including voltage at AC 220 V, current at 120 A, power factor at 0.35, and switching frequency at 600 times per hour. Examples 3-6 were made as discussed above and used in a similar fashion to the comparative examples in order to compare wear condition. Table 1 shows the results obtained. As is obvious from Table 1, the oomparative examples deformed in the form of a bow because every one of them had not sufficient joint strength and fell off at about 10,000 switchings. The examples of the present invention were free from curved deformation and showed normal wear.

Example 7

As shown in Fig. 10, contact material I made of composite contact material (i) is welded by projection welding to the base metal 2 of Fig. 12. One protrusion 10 is provided in the contact material welding zone of Fig. 6. The material is subjected to die forging into a substantially square contact 0.8 mm thick x 5.0 mm wide per side as shown in Fig. 11.

Example 8

Composite contact material (ii) is welded by projection welding to the base metal 2 of Fig. 13. Two protrusions 10 are provided in the contact material welding zone of Fig. 7. The material is subjected to die forging as in the case of Example 7.

Example 9

Composite contact material (iii) is welded by projection welding to the base metal 2 of Fig. 14. One protrusion 10 is provided in the contact material welding zone of Fig. 8. The material is subjected to die forging.

Example 10

Composite contact material (iv) is welded by projection welding to the base metal 2 of Fig. 15. One protrusion 10 is provided in the contact material welding zone of Fig. 9. The material is subjected to die forging.
In order to test Examples 7-10, Comparative Examples 7-10 were prepared by joining comparative contact materials a-d by projection welding to the base metals 2 of Figs. 2-15 and they are subjected to die forging into substantially square contacts 0.8mm thick x 5.0 mm wide per side. Table 2 shows the test results under the same conditions as that of Examples 3-6. Examples 7-10 of the present invention were free from curved deformation and showed normal wear.

Example 11

As shown in Fig. 16, a cut 11, 1.5 mm thick x 7.0 mm wide is preformed by cutting in and laterally across the contact-fitting portion of the base metal. V-shaped grooves 8 similar to those shown in Fig. 6 are provided in the bottom of the base metal. In the meantime, contact material (v) is welded to the base metal by resistance welding and the material is subjected to die forging into a substantially square contact 0.8 mm thick x 5.0 mm wide per side. At this time, each peripheral edge of the contact is then forced to contact the wall surface 11a of the cut 11.

Example 12

As shown in Fig. 17, a cut 11, 1.5 mm thick x 7.0 mm wide is preformed by extrusion melding laterally across the contact-fitting portion of the base metal. V-shaped grooves 8 similar to those shown in Fig. 7 are provided in the bottom of the base metal. Contact material (vi) is welded to the base metal by resistance welding and the material is subjected to die forging. Each peripheral edge of the contact is then forced to contact the wall surface 11a of the cut 11.
In order to test Examples 11 and 12, Comparative Examples 11 and 12 were prepared by joining comparative contact materials e and f by welding to the base metals 2 of Figs. 16 and 17 and they are subjected to die forging so that each peripheral edge was in contact with the wall surface 11a of cut 11. Table 3 shows the test results under the same condition as that of Examples 3-6. Examples 11-12 of the present invention were free from curved deformation and showed normal wear.

Example 13

As shown in Fig. 20, a recess 12, 1.5 mm thick x 7.0 mm wide is preformed by extrusion molding in and laterally across the contact-fitting portion of the base metal. V-shaped grooves 8 similar to those shown in Fig. 6 are provided in the bottom of the case metal. Contact material (i) made of the contact material 1 is welded to the base metal by resistance welding as shown in Fig. 18 and the material is subjected to die forging into a substantially square contact 0.8 mm thick x 5.0 mm wide per side. Each peripheral edge of the contact 9 is then forced to contact the wall surface 12a of the recess 12.

Example 14

As shown in Fig. 21, the composite contact material (ii) provided with grooves 8 similar to those shown in Fig. 7 is welded to the base metal 2 having a recess 12 similar to what is shown in Fig. 20. The material is subjected to die forging and each peripheral edge of the contact 9 is forced to touch the wall surface 12a of the recess 12.

Example 15

As shown in Fig. 22, a recess 12 similar to that shown in Fig. 20 is preformed in the base metal 2 and V-shaped grooves 8 similar to those shown in Fig. 8 are provided in the bottom thereof. The composite contact material (iii) is welded to the base metal having the grooves and each peripheral edge of the contact is forced to touch the wall surface 12a of the recess 12.

Example 16

As shown in Fig. 23, a recess 12 similar to that shown in Fig. 20 is preformed in base metal 2 and V-shaped grooves 8 similar to those shown in Fig. 9 are provided in the bottom thereof. The composite contact material (iv) is welded to the base metal having the grooves and each peripheral edge of the contact is forced to touch the wall surface 12a of the recess 12.
In order to test Examples 13-16, Comparative Examples 13-16 were prepared by joining comparative contact materials a-d by welding to the base metals 2 of Figs. 20-23 and they are subjected to die forging likewise to have each peripheral edge contact the wall surface 12a of the recess 12. Table 4 shows the test results under the same condition as that of Examples 13-16. Examples 13-16 of the present invention were free from curved deformation and showed normal wear, whereas Comparative Examples 13-16 deformed in the form of a bow and fell off at not greater than 10,000 switchings.

Example 17

As shown in Fig. 26, the two square through-holes 13, each being 1.0 mm wide x 2.0 mm long, are provided in the base metal 2, 0.6 mm thick x 6.0 mm wide. Contact material 1 made of composite material of 2.6 mm in both diameter and length and made of the same material as the composite contact material (i) are joined to the base metal 2 by resistance welding as shown in Fig. 24. The material is subjected to die forging into a substantially square contact 9 of 0.7 mm thick x 4.5 mm wide per side as shown in Fig. 25.

Example 18

As shown in Fig. 27, four circular through-holes 14, each being 1.0 mm in diameter, are provided, in the base metal, 0.6 mm thick x 6.0 mm wide. The contact material 1 made of composite material of 2.6 mm in both diameter and length and made of the same material as the composite contact material (ii) are joined to the base metal 2 by resistance welding. The material is subjected to die forging into a substantially square contact of 0.7 mm thick x 4.5 mm wide per side.

Example 19

Two square through-holes 13, each being 1.0 mm wide x 2.0 mm long, are provided in the base metal 2, 0.6 mm thick x 6.0 mm wide (Fig. 26). The contact material 1 made of composite material of 2.6 mm in both diameter and length and made of the same material as the composite contact material (iii) are joined to the base metal 2 by resistance welding. The material is subjected to die forging into a substantially square contact of 0.7 mm thick x 4.5 mm wide per side.

Example 20

Four circular through-holes 14, each being 1.0 mm in diameter, are provided in the base metal 2, 0.6 mm thick x 6.0 mm wide (Fig. 27). The contact material 1 made of composite material of 2.6 mm in both diameter and length and made of the same material as the composite contact material (iv) are joined to the base metal 2 by resistance welding. The material is subjected to die forging into a substantially square contact of 0.7 mm thick x 4.5 mm wide per side.
In order to test Examples 17-20, Comparative Examples 17-20 were prepared by joining comparative contact materials a-d of 2.6 mm in both diameter and length by welding to the base metals 2 of Figs. 26 and 27 and compression-molding them likewise.
The contacts thus obtained were incorporated in commercially available electromagnetic contactors (rated at 20 A) and switched on and off 20,000 times under the conditions including voltage at AC 220 V, current at 78 A, power factor at 0.35, and switching frequency at 600 times per hour. Examples 17-20 were made as discussed above and used in a similar fashion to the comparative examples in order to compare wear condition. Table 5 shows the results obtained. As is obvious from Table 5, Comparative Examples 17-20 deformed in the form of a bow and fell off at less than 10,000 switchings. Examples 17-20 of the present invention were free from curved deformation and showed normal wear.

Example 21

As shown in Fig. 28, a cut 11 is preformed by cutting in and laterally across the contact-fitting portion of the base metal 2, 0.6 mm thick x 6.0 mm wide and square holes 13 similar to those shown in Fig. 26 are provided in the bottom thereof. The contact material made of composite material of 2.6 mm in both diameter and length and made of the same material as the contact material (i) is joined to the base metal 2 by resistance welding and the material is subjected to die forging into a substantially square contact 0.7 mm thick x 4.5 mm wide per side. Each peripheral edge of the contact is then forced to touch the wall surface 11a of the cut 11.

Example 22

As shown in Fig. 29, a cut 11 is preformed by extrusion melding in and laterally across the contact-fitting portion of the base metal 2, 0.6 mm thick x 6.0 mm wide and circular holes 14 similar to those shown in Fig. 27 are provided in the bottom thereof. The contact material made of composite material of 2.6 mm in both diameter and length and made of the some material as the contact material (ii) is joined to the base metal 2 by resistance welding and the material is subjected to die forging. Each peripheral edge of the contact is then forced to touch the wall surface 11a of the cut 11.

Example 23

Contact material made of composite material of 2.0 mm in both diameter and length and made of the same material as the contact material (iii) is joined to the base metal of Fig. 28 by welding and the material is subjected to die forging. Each peripheral edge of the contact is then forced to touch the wall surface 11a of the cut 11.

Example 24

Contact material made of composite material of 2.6 mm in both diameter and length and made of the same material as the contact material (iv) is joined to the base metal of Fig. 29 by welding and the material is subjected to die forging. Each peripheral edge of the contact is then forced to touch the wall surface 11a of the cut 11.
In order to test Examples 21-24, Comparative Examples 21-24 were prepared by joining comparative contact materials a-d of 2.6 mm in both diameter and length by welding to the base metals 2 of Figs. 28 and 29 and they are subjected to die forging likewise.
The contacts thus obtained were tested under the same conditions as those in the case of Examples 17-20. Table 6 shows the results obtained. As is obvious from Table 6, Comparative Examples 21-24 deformed in the form of a bow and fell off at less than 10,000 switchings. Examples 21-24 of the present invention were free from curved deformation and showed normal wear.

Example 25

As shown in Fig. 32, a recess 12 is preformed by extrusion molding in the contact-fitting portion of the base metal 2, 0.6 mm thick x 6.0 mm wide and square holes 13 similar to those shown in Fig. 26 are provided in the bottom thereof. The contact materials 1 made of composite material 2.6 mm in both diameter and length made of the same material as the composite contact material (i) is joined to the base metal 2 by resistance welding and the material is subjected to die forging into a substantially square contact 9, 0.7 mm thick x 4.5 mm wide per side as shown in Fig. 31. Each peripheral edge of the contact in then forced to touch the wall surface 12a of the recess 12 of the contact 9.

Example 26

As shown in Fig. 33, a recess 12 is preformed likewise in the base metal 2 and circular holes 14 similar to those shown in Fig. 27 are provided. The contact material made of composite material of 2.6 mm in both diameter and length and made of the same material as the composite contact material (ii) is joined to the base metal 2 by welding and the material is subjected to die forging. Each peripheral edge of the contact is then forced to touch the wall surface 12a of the recess 12 of the contact.

Example 27

Contact material made of composite material of 2.6 mm in both diameter and length and made of the same material as the composite contact material (iii) is joined to the base metal of Fig. 32 by welding and the material is subjected to die forging. Each peripheral edge of the contact is then forced to touch the wall surface 12a of the recess 12 of the contact.

Example 28

Contact material made of composite material of 2.6 mm in both diameter and length and made of the same material as the composite contact material (iv) is joined to the base metal of Fig. 33 by welding and the material is subjected to die forging. Each peripheral edge of the contact is then forced to touch the wall surface 12a of the recess 12 of the contact.
In order to test Examples 25-28, Comparative Examples 25-28 were prepared by joining comparative contact materials a-d of 2.6 mm in both diameter end length by welding to the base metals 2 of Figs. 32 and 33 and the material are subjected to die forging.
The contacts thus obtained were tested under the same conditions as those in the case of Examples 17-20. Table 7 shows the results obtained. As is obvious from Table 7, Comparative Examples 25-28 deformed in the form of a bow and fell off at less than 10,000 switchings. Examples 25-28 of the present invention were free from curved deformation and showed normal wear.
As set forth above, the central portion of the contact is firmly welded to the base metal and the peripheral portion is prevented from bending upwardly. The contact is kept from wearing abnormally and, therefore, effectively prevented from falling off in the examples of the present invention.

It will be apparent to those skilled in the art that modifications and variations can be made to the electric contact with a base metal of the present invention within the scope of the accompanying claims. The invention in its broader aspects is, therefore, not limited to the specific details, representative methods and apparatus, and illustrated examples shown and described herein. Thus, it is intended that all matter contained in the foregoing description and shown in the accompanying drawings shall be interpreted as illustrative and not in a limiting sense.

TABLE 1

Test Piece	Percentage of Ag Layer	Shape of Base Metal	Amount of Wear (mg)	Wearing Condition
Comparative Example:
3	-	Fig. 6	Fell off at 6,000 switchings	Bow-like bending
4	-	Fig. 7	Fell off at 4,000 switchings	Bow-like bending
5	-	Fig. 8	Fell off at 7,000 switchings	Bow-like bending
6	-	Fig. 9	Fell off at 6,000 switchings	Bow-like bending
Invention:
3	17	Fig. 6	227	Normal
4	30	Fig. 7	201	Normal
5	24	Fig. 8	233	Normal
6	9	Fig. 9	206	Normal

TABLE 2

Test Piece	Percentage of Ag Layer	Shape Of Base Metal	Amount of Wear (mg)	Wearing Condition
Comparative Example:
7	-	Fig. 12	Fell off at 7,000 switchings	Bow-like bending
8	-	Fig. 13	Fell off at 7,000 switchings	Bow-like bending
9	-	Fig. 14	Fell off at 6,000 switchings	Bow-like bending
10	-	Fig. 15	Fell off at 8,000 switchings	Bow-like bending
Invention:
7	17	Fig. 12	198	Normal
8	30	Fig. 13	206	Normal
9	24	Fig. 14	210	Normal
10	9	Fig. 15	225	Normal

TABLE 3

Test Piece	Percentage of Ag Layer	Shape Of Base Metal	Amount of Wear (mg)	Wearing Condition
Comparative Example:
11	-	Fig. 16	Fell off at 7,000 switchings	Bow-like bending
12	-	Fig. 17	Fell off at 7,000 switchings	Bow-like bending
Invention:
11	9	Fig. 16	215	Normal
12	30	Fig. 17	225	Normal

TABLE 4

Test Piece	Percentage of Ag Layer	Shape Of Base Metal	Amount of Wear (mg)	Wearing Condition
Comparative Example:
13	-	Fig. 20	Fell off at 6,000 switchings	Bow-like bending
14	-	Fig. 21	Fell off at 4,000 switchings	Bow-like bending
15	-	Fig. 22	Fell off at 7,000 switchings	Bow-like bending
16	-	Fig. 23	Fell off at 6,000 switchings	Bow-like bending
Invention:
13	17	Fig. 20	205	Normal
14	30	Fig. 21	198	Normal
15	24	Fig. 22	216	Normal
16	9	Fig. 23	195	Normal

TABLE 5

Test Piece	Percentage of Ag Layer	Shape Of Base Metal	Amount of Wear (mg)	Wearing Condition
Comparative Example:
17	-	Fig. 26	Fell off at 7,000 switchings	Bow-like bending
18	-	Fig. 27	Fell off at 8,000 switchings	Bow-like bending
19	-	Fig. 26	Fell off at 8,000 switchings	Bow-like bending
20	-	Fig. 27	Fell off at 6,000 switchings	Bow-like bending
Invention:
17	17	Fig. 26	153	Normal
18	30	Fig. 27	162	Normal
19	24	Fig. 26	158	Normal
20	9	Fig. 27	150	Normal

TABLE 6

Test Piece	Percentage of Ag Layer	Shape Of Base Metal	Amount of Wear (mg)	Wearing Condition
Comparative Example:
21	-	Fig. 28	Fell off at 7,000 switchings	Bow-like bending
22	-	Fig. 29	Fell off at 8,000 switchings	Bow-like bending
23	-	Fig. 28	Fell off at 8,000 switchings	Bow-like bending
24	-	Fig. 29	Fell off at 6,000 switchings	Bow-like bending
Invention:
21	17	Fig. 28	160	Normal
22	30	Fig. 29	158	Normal
23	24	Fig. 28	161	Normal
24	9	Fig. 29	165	Normal

TABLE 7

Test Piece	Percentage of Ag Layer	Shape Of Base Metal	Amount of Wear (mg)	Wearing Condition
Comparative Example:
25	-	Fig. 32	Fell off at 8,000 switchings	Bow-like bending
26	-	Fig. 33	Fell off at 6,000 switchings	Bow-like bending
27	-	Fig. 32	Fell off at 8,000 switchings	Bow-like bending
28	-	Fig. 33	Fell off at 6,000 switchings	Bow-like bending
Invention:
25	17	Fig. 32	162	Normal
26	30	Fig. 33	145	Normal
27	24	Fig. 32	163	Normal
28	9	Fig. 33	148	Normal

Claims

A method of manufacturing an electric contact with a base metal, wherein
said electric contact is made of a contact material (1),

said base metal (2) to which said contact material (1) is joined by resistance welding and in which at least one engagement portion (8) and a weld zone (3) of said base metal (2) is provided and

said joined contact material (1) is formed into said electric contact of a required shape by die forging and bites into said engagement portion (8) at the die forging,

characterized in that

said engagement portion (8) is provided close but separately to said weld zone (3), whereby said engagement portion (8) is formed as a recess in the plane of the weld zone and is spaced from said weld zone, said contact material being composed of a non-oxide metal or of an oxide metal and a non-oxide metal and at least one side of said contact material (1) in contact with said base metal (2) is formed of said non-oxide metal.
A method as claimed in claim 1, wherein said engagement portion is a groove (8) preformed in said base metal (2) close to said weld zone (3), and said contact material (1) is pressed at the die forging to fill said groove.
A method as claimed in claim 1, wherein said engagement portion is a hole preformed in said base metal (2) close to said weld zone (3), and said contact material (1) is pressed at the die forging to fill said hole.
A method as claimed in claim 1, wherein said contact material (1) is a composite wire prepared by coating an outer periphery of a core material made of Ag-metallic oxide metal with said non-oxide metal.
A method as claimed in claim 4, wherein the sectional area of said non-oxide contact material is 5% to 35% of the total sectional area of said composite wire.
A method as claimed in claim 4, wherein a surface layer of said electric contact for switching purposes is ground after the die forging to expose said core material.
A method as claimed in claim 1, wherein said contact material (1) is welded to protrusions preformed in said weld zone (3).
A method as claimed in claim 1, wherein said contact material (1) is welded to abottom of a cut preformed in and laterally across said base metal (2), and wherein each periphery of said contact material (1) is in contact with an inner wall of said cut after the die forging.
A method as claimed in claim 1, wherein said contact material (1) is welded to a bottom of a recess preformed in said base metal (2), and wherein each periphery of said contact material (1) is in contact with an inner wall of said recess after the die forging.