Indirect spot welding method

Abstract

An oval nugget can reliably be obtained with this indirect spot welding method. In this indirect spot welding method, an electrode end portion of a welding electrode includes a tip of the welding electrode, and as viewed from the tip, the electrode end portion has a two-step dome shape formed by a first curved surface with a curvature radius r.sub.1 (mm) located within a range of a circle of radius R (mm) centering on the tip and a second curved surface with a curvature radius r.sub.2 (mm). 2tR6t (1), 30r.sub.1 (2), and 6r.sub.212 (3), where t is the sheet thickness (mm) of a thinner metal sheet.

Claims

1. A method of indirect spot welding for welding a member composed of two overlapping metal sheets, the method comprising: holding a spot welding electrode against the two overlapping metal sheets while applying pressure with the spot welding electrode from one side of the member; attaching a feeding point to the other side of the member at a location remote from the spot welding electrode; and allowing current to indirectly flow between the spot welding electrode and the feeding point to form an oval nugget, wherein an electrode end portion of the welding electrode includes a tip of the welding electrode, and as viewed from the tip, the electrode end portion has a two-step dome shape formed by a first curved surface with a curvature-radius r.sub.1 (mm) located within a range of a circle of radius R (mm) centering on the tip and a second curved surface with a curvature-radius r.sub.2 (mm) located at edge of the tip and around the first curved surface, and
2tR6t(1)
30r.sub.170(2)
6r.sub.210(3) where t is a sheet thickness (mm) of a thinner metal sheet of the two metal sheets in the member.

2. The method of claim 1, wherein the method further comprising: maintaining a constant current from turning on to turning off power supply; and with respect to electrode force, a duration of the indirect spot welding of the member is divided into two time periods t.sub.1 and t.sub.2, wherein the method includes applying electrode force set at F.sub.1 in a first time period t.sub.1, and applying electrode force set at F.sub.2 lower than the electrode force F.sub.1 in a second time period t.sub.2.

3. The method of claim 1, wherein, with respect to electrode force and the current, a duration of the indirect spot welding of the member is divided into two time periods t.sub.1 and t.sub.2, wherein the method includes applying electrode force set at F.sub.1 and current set at C.sub.1 in a first time period t.sub.1, and applying electrode force set at F.sub.2 lower than the electrode force F.sub.1 and current set at C.sub.2 higher than the current C.sub.1 in a second time period t.sub.2.

4. The method of claim 1, wherein with respect to electrode force, a duration of the indirect spot welding of the member is divided into two time periods t.sub.F1 and t.sub.F2, wherein the method includes applying electrode force set at F.sub.1 in a first time period t.sub.F1, and applying electrode force set at F.sub.2 lower than the electrode force F.sub.1 in a second time period t.sub.F2, and with respect to the current, a duration of the indirect spot welding of the member is divided, independent of time periods t.sub.F1 and t.sub.F2, into two time periods t.sub.C1 and t.sub.C2, wherein the method includes applying current set at C.sub.1 in a first time period t.sub.C1, and applying current set at C.sub.2 higher than the current C.sub.1 in a second time period t.sub.C2.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1(A) illustrates welding with a direct spot welding method, and FIG. 1(B) illustrates welding with an indirect spot welding method.

(2) FIG. 2 illustrates the shape of the electrode end portion of the welding electrode in one of the disclosed examples.

(3) FIG. 3(A) illustrates the relationship between welding time and electrode force, and FIG. 3(B) illustrates the relationship between welding time and current in one of the disclosed examples.

(4) FIG. 4 illustrates welding in Examples 1 and 2.

REFERENCE SIGNS LIST

(5) 1, 2 Steel sheet 3, 4 Electrode 5 Weld 6, 7 Force controller 8 Current controller 21, 22 Steel sheet 23 Welding electrode 24 Feeding point 25 Weld 30 Electrode end portion 31 First curved surface 32 Second curved surface

DETAILED DESCRIPTION

(6) The following provides a detailed explanation in accordance with the drawings.

(7) In our indirect spot welding method, a member composed of two overlapping metal sheets is welded by holding a spot welding electrode against the metal sheet at one side of the member while applying pressure with the spot welding electrode, attaching a feeding point to the metal sheet at the other side of the member at a location remote from the spot welding electrode, and allowing current to flow between the spot welding electrode and the feeding point. As described below in the Examples with reference to FIG. 4, when the member composed of the overlapping metal sheets is placed on a concave metal jig, a ground electrode is attached to the bottom of the jig, pressure is applied to the overlapping metal sheets with the welding electrode from only one side, and the other side is unsupported in midair, then the combination of the metal jig and the earth electrode corresponds to the feeding point.

(8) One feature of our method is the shape of the electrode end portion of the welding electrode. FIG. 2 illustrates the shape of the electrode end portion of the welding electrode in one of the disclosed examples of our method. An electrode end portion 30 of the welding electrode includes a tip of the welding electrode, and as viewed from the tip, the electrode end portion 30 has a two-step dome shape formed by a first curved surface 31 with a curvature radius r.sub.1 (mm) located within a range of a circle of radius R (mm) centering on the tip and a second curved surface 32 with a curvature radius r.sub.2 (mm) located around the first curved surface. Expressions (1) to (3) below are satisfied.

(9) By having the electrode end portion 30 form a two-step dome shape and setting the first curved surface 31 to be a curved surface with a larger curvature radius than that of the second curved surface 32, a high current density can be maintained between the overlapping metal sheets directly below the electrode even if the electrode sinks into the metal sheets during application of current. Furthermore, by setting the first curved surface 31 to have a larger curvature radius than that of the second curved surface 32, the area of contact between the electrode and the metal sheet can be sufficiently guaranteed at the time of turning on electricity, and it is possible to resolve problems such as the current density becoming excessively large, causing fused metal to splatter from the metal sheet at the side in contact with the electrode. Also, the second curved surface 32 has a smaller curvature radius than that of the first curved surface 31. Therefore, when the electrode sinks into the metal sheet during application of current and the second curved surface 32 begins to be in contact with the metal sheet in addition to the first curved surface 31, an increase in the area of contact between the electrode and the metal sheet can be suppressed.

(10) One feature of our method is that the radius R (mm) that determines the boundary between the first curved surface 31 and the second curved surface 32 is determined by employing an integer multiple of the square root of the sheet thickness t (mm) of the metal sheet, between the overlapping metal sheets to be welded, that serves as the standard for the nugget diameter. The sheet thickness t of the metal sheet that serves as the standard for the nugget diameter is the sheet thickness of the thinner metal sheet when spot welding a member composed of two overlapping metal sheets. When the two sheets are of the same thickness, the sheet thickness t is the sheet thickness of each sheet.

(11) In general, in a sheet combination formed by a member composed of two overlapping metal sheets, the required value of the nugget diameter is determined by an integer multiple of the square root of the sheet thickness of the thinner sheet. On the other hand, when the radius R is an appropriate size, then, during the process of the area of contact between the electrode and the metal sheet increasing during welding, the nugget diameter can be prevented from increasing to a range exceeding the radius R, thereby yielding a good nugget diameter. The radius R and the nugget diameter are correlated. Therefore, when obtaining a required nugget diameter in any sheet combination to set the radius R appropriately, it suffices to restrict the radius R using an integer multiple of the square root of the sheet thickness of the thinner sheet.

(12) If the radius R is in a range of less than 2t (mm), at the time of turning on electricity, the area of contact between the electrode and the metal sheet is restricted to an extremely small range. The current density therefore becomes excessive, leading to problems such as fused metal splattering from the metal sheet at the side in contact with the electrode. On the other hand, if the radius R exceeds 6t (mm), then when the electrode sinks into the metal sheet during application of current and the second curved surface 32 begins to be in contact with the metal sheet in addition to the first curved surface 31 as described above, the effect of suppressing an increase in the area of contact between the electrode and the metal sheet cannot be sufficiently obtained. Therefore, the radius R (mm) is restricted to Expression (1) below:
2tR6t(mm)(1).
t is the sheet thickness (mm) of the above-described thinner metal sheet.

(13) To more reliably obtain the above-described effects, the radius R is more preferably 3tR5t (mm).

(14) With regard to the curvature radius r.sub.1 (mm) of the first curved surface 31, by setting r.sub.1 to be 30 mm or more, the area of contact between the electrode and the metal sheet can be sufficiently guaranteed at the time of turning on electricity, and it is possible to resolve problems such as the current density becoming excessively large, causing fused metal to splatter from the metal sheet at the side in contact with the electrode. Therefore, the curvature radius r.sub.1 (mm) is Expression (2) below:
30r.sub.1(2).

(15) To more reliably obtain the above-described effects, r.sub.1 is more preferably 40 mm or more. The curvature radius may be also considered infinity, and the first curved surface may be set to a flat surface.

(16) With regard to the curvature radius r.sub.2 (mm) of the second curved surface 32, if r.sub.2 is less than 6 mm, the electrode sinks into the metal plate excessively during application of current, causing unnecessary deformation of the weld between the metal sheets and becoming the cause of a crack. Setting r.sub.2 to less than 6 mm is therefore not preferable. On the other hand, if r.sub.2 exceeds 12 mm, then when the electrode sinks into the metal sheet during application of current and the second curved surface 32 begins to be in contact with the metal sheet in addition to the first curved surface 31, the effect of suppressing an increase in the area of contact cannot be sufficiently obtained. Therefore, the curvature radius r.sub.2 (mm) is restricted to Expression (3) below:
6r.sub.212(3).

(17) To more reliably obtain the above-described effects, the curvature radius r.sub.2 (mm) is more preferably 8r.sub.210.

(18) The electrode radius of the bottom of the electrode end portion 30 of the welding electrode may, for example, be set to 8 mm as in FIG. 2 and may be suitably set to approximately 4.0 mm to 12.5 mm.

(19) As described above, in our indirect spot welding method, the first curved surface 31 and the second curved surface 32 that constitute the end portion 30 of the welding electrode satisfy Expressions (1) to (3) above. Therefore, the current density between the metal sheets can be made appropriate. Hence, an oval nugget formed after fusion between the metal sheets can more reliably be obtained even when current flow between the metal sheets at a location other than the weld, i.e., shunt current, is large.

(20) Any metal sheets may be used with our method such as steel metal sheets. The sheet thickness t of the thinner metal sheet that is targeted in our method is approximately 0.5 mm to 1.8 mm, and the total sheet thickness of the member composed of the overlapping metal sheets is approximately 1 mm to 4 mm.

(21) In indirect spot welding according to our method, the time period from turning on to turning off electricity, control of the electrode force F, and control of the current C are not restricted and may be selected appropriately. For example, a suitable nugget can be stably obtained even if the electrode force F and the current C are kept constant from the start to the end of application of current. In this case, the welding time may be approximately 0.06 s to 0.60 s, the electrode force F may be approximately 100 N to 1500 N, and the current C may be approximately 4 kA to 12 kA.

(22) As described above, in our method, the time period from turning on to turning off electricity, control of the electrode force F, and control of the current C are not restricted. In addition to using a welding electrode such that the shape of the electrode end portion satisfies Expressions (1) to (3) above, however, the welding time is preferably divided, and the electrode force of the welding electrode and the current are preferably controlled. In another one of the disclosed examples, the basic relationship between the welding time and the electrode force and between the welding time and the current are respectively illustrated in FIGS. 3(A) and 3(B). By performing such control, a more pronounced effect may be obtained. The suitable relationship between the welding time and the electrode force and between the welding time and the current in this example are described below.

(23) In this example, with regard to the electrode force of the welding electrode and the current that is applied, preferably the time from turning on electricity is simultaneously or independently divided into two time periods, in each of which one or both of an electrode force F of the welding electrode and a current C are controlled. When the electrode force F and/or the current C are to be simultaneously controlled, the divided time periods are denoted by t.sub.1 and t.sub.2. When both the electrode force F and the current C are to be independently controlled, the time periods that divide the electrode force F are denoted by t.sub.F1 and t.sub.F2, and the time periods that divide the current C are denoted by t.sub.C1 and t.sub.C2. In the respective time periods, the electrode forces are denoted by F.sub.1 and F.sub.2, and the currents are denoted by C.sub.1 and C.sub.2.

(24) In this example, the electrode force F.sub.1 and the current C.sub.1 are applied in time period t.sub.1.

(25) The time period t.sub.1 is a time period in which electricity is turned on while the welding electrode is being held against the overlapping metal sheets by applying pressure with the welding electrode, and formation of a fused portion is started by heat generated due to contact resistance between the metal sheets. When performing indirect spot welding in which the overlapping metal sheets are pressed by the welding electrode from only one side, with the other side of the metal sheets being unsupported in midair, the electrode force F.sub.1 cannot be as high as the electrode force applied in direct spot welding where metal sheets are sandwiched by electrodes on both sides. However, if the electrode force F.sub.1 is too low, the area of contact between the electrode and the metal sheet becomes extremely small, and the current density increases excessively. This results in fusion and splattering of the metal sheet surface and causes considerable damage to the surface shape. Therefore, to prevent such a problem, the electrode force F.sub.1 is preferably selected appropriately.

(26) The current C.sub.1 needs to be high enough to allow fusion to begin due to heat generated between the metal sheets. An excessively high current C.sub.1, however, results in fusion and splattering of the metal sheet surface, as described above. This not only causes surface cavities and considerable damage to the appearance, but also causes degradation in joint strength. To prevent such problems, it is preferable to select the current C.sub.1 appropriately.

(27) In this example, the electrode force F.sub.2 and the current C.sub.2 are applied in time period t.sub.2, which follows time period t.sub.1.

(28) The time period t.sub.2 is a stage of further developing the fused portion that started to form in time period t.sub.1. When indirect spot welding is performed in a state where the metal sheets are softened around the electrode by heat generated by application of current, with the opposite side from the electrode being unsupported in midair, the electrode end portion sinks into the metal sheet due to softening of the metal sheets. This increases the area of contact between the electrode and the metal sheet and between the metal sheets, thus reducing the current density. As a result, it is not possible to generate heat sufficient to develop a nugget. Therefore, in the time period t.sub.2, to prevent the electrode end portion from sinking into the metal sheet, the electrode force F.sub.2 is preferably set to be lower than the electrode force F.sub.1.

(29) Conversely, the current C.sub.2 is preferably set to be higher than the current C.sub.1 to prevent a decrease in current density resulting from an increase in the area of contact caused by sinking of the electrode as described above. However, an excessively high current results in splattering and burn-through of the fused metal from the metal sheet surface opposite the electrode, which not only causes considerable damage to the appearance, but also causes degradation in joint strength. Therefore, to prevent such a problem, the current C.sub.2 is preferably selected appropriately.

(30) In the example described above, the time from turning on electricity is divided into two time periods, and the electrode force F and current C are both controlled simultaneously. However, another of the examples may be configured to control only the electrode force, or more preferably to control both the electrode force F and current C independently.

(31) In other words, similar effects can be achieved by setting the currents C.sub.1 and C.sub.2 to be equal and the electrode force F.sub.2 to be lower than the electrode force F.sub.1 in time periods t.sub.1 and t.sub.2. However, as described above, a more significant effect can be achieved by setting the electrode force F.sub.2 to be lower than the electrode force F.sub.1 and the current C.sub.2 to be higher than the current C.sub.1 in time periods t.sub.1 and t.sub.2.

(32) Furthermore, with regard to the electrode force F, the time from turning on electricity is preferably divided into time periods t.sub.F1 and t.sub.F2, and the electrode force F.sub.2 is preferably set to be lower than the electrode force F.sub.1. With respect to the current C, the time from turning on electricity is preferably divided into time periods t.sub.C1 and t.sub.C2 independent of time periods t.sub.F1 and t.sub.F2, and the current C.sub.2 is preferably set to be higher than the current C.sub.1. A more significant effect can be achieved by thus optimally varying the electrode force and current in time periods that are independent of each other.

(33) When the time from turning on electricity is divided into two time periods t.sub.1 and t.sub.2 and both the electrode force F and current C are controlled simultaneously, the time period t.sub.1 is preferably in the range of approximately 0.02 s to 0.30 s, and the time period t.sub.2 is preferably in the range of approximately 0.10 s to 0.60 s. In the time period t.sub.1, preferably the electrode force F.sub.1 is set to approximately 300 N to 2000 N and the current C.sub.1 to approximately 2.0 kA to 10.0 kA, and in the time period t.sub.2, preferably the electrode force F.sub.2 to set to approximately 100 N to 1500 N, and the current C.sub.2 to approximately 2.5 kA to 12.0 kA.

(34) In the time periods t.sub.1 and t.sub.2, when the currents C.sub.1 and C.sub.2 are set to be equal and the electrode force F.sub.2 is set to be lower than the electrode force F.sub.1, the constant current is preferably set to be approximately 2.5 kA to 10 kA.

(35) When both the electrode force F and current C are controlled independently, it is preferable that, with respect to the electrode force F, the time period t.sub.F1 be approximately 0.02 s to 0.30 s and the time period t.sub.F2 be approximately 0.10 s to 0.60 s, and that the electrode force F.sub.1 in the time period t.sub.F1 be approximately 300 N to 2000 N and the electrode force F.sub.2 in the time period t.sub.F2 be approximately 100 N to 1500 N. It is also preferable that, with respect to the current C, the time period t.sub.C1 be approximately 0.02 s to 0.30 s and the time period t.sub.C2 be approximately 0.10 s to 0.60 s, and that the current C.sub.1 in the time period t.sub.C1 be approximately 2.0 kA to 10.0 kA and the current C.sub.2 in the time period t.sub.C2 be approximately 2.5 kA to 12.0 kA.

EXAMPLES

Example 1

(36) An indirect spot welding method was performed with a configuration like the one illustrated in FIG. 4.

(37) A member composed of two overlapping steel sheets was produced by combining an upper steel sheet and a lower steel sheet that were SPC 270 steel sheets having a tensile strength of 270 MPa or more and the chemical composition shown in Table 1. The sheet thickness of the upper steel sheet was 1.0 mm, and the sheet thickness of the lower steel sheet was 1.2 mm. This member was placed on a concave metal jig such as the one illustrated in FIG. 4. The support distance was 30 mm, and a ground electrode was attached to the bottom of the jig. The member was welded by applying pressure with a welding electrode from above. The overlapping upper and lower steel sheets were brought into close contact with each other by fastening them, at both ends, on the jig with clamps so that shunt current would be more likely to occur between the steel sheets during application of current. Hence, conditions that impede the formation of a nugget directly below the electrode were intentionally established.

(38) A direct-current inverter power supply was used for the welding. The electrodes used for the welding were made of chromium-copper alloy. The electrode end portion of each welding electrode included a tip of the welding electrode, and as viewed from the tip, the electrode end portion had a two-step dome shape formed by a first curved surface with a curvature radius r.sub.1 (mm) located within a range of a circle of radius R (mm) centering on the tip and a second curved surface with a curvature radius r.sub.2 (mm) located around the first curved surface. Table 2 lists the dimensions of R, r.sub.1, and r.sub.2. Table 2 also lists the electrode radius of the bottom of the electrode end portion of each welding electrode. Furthermore, Table 2 lists the conditions on the time period from turning on to turning off electricity and on the electrode force and current in each time period. Indirect spot welding was performed for Nos. 1 to 16 under the conditions listed in Table 2.

(39) TABLE-US-00001 TABLE 1 Chemical Composition C Si Mn P S (mass %) 0.003 Tr 0.09 0.016 0.004

(40) TABLE-US-00002 TABLE 2 Electrode force/Current/Time Electrode shape First stage Second stage electrode Top: electrode force (N)/time (s) Top: electrode force (N)/time (s) No. Standard R (mm) r.sub.1 (mm) r.sub.2 (mm) radius (mm) Bottom: current (kA)/time (s) Bottom: current (kA)/time (s) 1 Comparative 1.5 20 6 6 800/0.36 Example 9.0/0.36 2 Example 2 40 6 6 800/0.36 9.0/0.36 3 Example 3 60 8 8 800/0.36 9.0/0.36 4 Example 4 70 8 8 800/0.36 9.0/0.36 5 Example 5 60 9.5 9.5 800/0.36 9.0/0.36 6 Example 6 60 8 8 800/0.36 9.0/0.36 7 Comparative 8 60 8 9.5 800/0.36 Example 9.0/0.36 8 Comparative 2 40 4 4 800/0.36 Example 9.0/0.36 9 Comparative 2 40 12.5 12.5 800/0.36 Example 9.0/0.36 10 Comparative 2 10 8 8 800/0.36 Example 9.0/0.36 11 Comparative 12 40 8 12.5 400/0.36 Example 9.0/0.36 12 Comparative 1.5 20 8 8 800/0.18 400/0.18 Example 9.0/0.18 9.0/0.18 13 Comparative 1.5 20 8 6 800/0.18 400/0.36 Example 4.0/0.18 9.0/0.36 14 Example 4 40 9 8 800/0.18 400/0.18 9.0/0.18 9.0/0.18 15 Example 5 30 10 8 800/0.18 400/0.36 4.0/0.18 9.0/0.36 16 Example 6 40 8 8 800/0.12 400/0.42 4.0/0.18 9.0/0.36

(41) The electrode shape of the welding electrode used in Nos. 2 to 6 and 14 to 16 in Table 2 satisfies the requirements of our method. On the other hand, the electrode shape of the welding electrode used in Nos. 1 and 7 to 13 does not satisfy the requirements of our method. The electrode force F and the current C are constant in Nos. 1 to 11 in Table 2. For Nos. 12 and 14, the time period for application of current was divided into time periods t.sub.1 and t.sub.2, and while keeping the current constant, the electrode force F was controlled. For Nos. 13 and 15, the time period was divided into time periods t.sub.1 and t.sub.2, and the electrode force F and the current C were controlled simultaneously. For No. 16, with respect to the electrode force, the time from turning on electricity was divided into two time periods t.sub.F1 and t.sub.F2, and with respect to the current, the time from turning on electricity was divided into two time periods t.sub.C1 and t.sub.C2 independent of the time periods t.sub.F1 and t.sub.F2. The electrode force F and the current C were thus controlled independently.

(42) Table 3 shows the nugget diameter, nugget thickness, and nugget thickness/diameter of each joint, and also shows observations of defects in appearance, for the welding performed in accordance with the electrode shapes and current application patterns shown in Table 2.

(43) In Table 3, the nugget diameter was taken to be the length, in a cross-section taken along the center of the weld, of the fused portion formed along the mating line between the upper and lower steel sheets. The nugget thickness was taken to be the maximum thickness, in a cross-section taken along the center of the weld, of the fused portion formed between the upper and lower steel sheets. The nugget thickness/diameter was obtained by dividing the above nugget thickness by the above nugget diameter. If the nugget diameter is 4 mm or more and the nugget thickness/diameter is 0.22 or more, the nugget may be judged as being suitable.

(44) As for defects in appearance caused by fusion and scattering of the weld, the occurrence of splattering and dropping occurring at the lower steel sheet of the weld was disclosed in Table 3 as burn-through.

(45) Furthermore, overall evaluation was made based on the following criteria: Pass: nugget diameter of 4 mm or more, nugget thickness/diameter of 0.22 or more, and no defect in appearance Fail: satisfaction of any one of the conditions of nugget diameter of less than 4 mm, nugget diameter thickness/diameter of less than 0.22, or a defect in appearance.

(46) TABLE-US-00003 TABLE 3 Nugget diameter Nugget thickness Nugget Defect in Overall No. Standard (mm) (mm) thickness/diameter appearance evaluation 1 Comparative 0 0 burn through fail Example 2 Example 4.1 1.5 0.37 none pass 3 Example 5.5 1.5 0.27 none pass 4 Example 4.9 1.1 0.22 none pass 5 Example 4.5 1.1 0.24 none pass 6 Example 4.4 1.0 0.23 none pass 7 Comparative 4.5 0.5 0.11 none fail Example 8 Comparative 0 0 burn through fail Example 9 Comparative 3.8 1.6 0.42 none fail Example 10 Comparative 0 0 burn through fail Example 11 Comparative 3.5 1.5 0.43 none fail Example 12 Comparative 0 0 burn through fail Example 13 Comparative 0 0 burn through fail Example 14 Example 5.8 2.0 0.34 none pass 15 Example 6.2 2.3 0.37 none pass 16 Example 5.4 1.5 0.28 none pass

(47) As shown in Table 3, for Nos. 2 to 6 and 14 to 16, in which indirect spot welding was performed using a welding electrode satisfying the requirements of our method with respect to a sheet thickness of 1.0 mm for the thinner steel sheet, a fused nugget with a sufficient nugget diameter and sufficient thickness for the diameter were obtained, and no defect in appearance whatsoever was observed, even under the intentionally established conditions that impeded formation of a nugget directly below the electrode.

(48) By contrast, for No. 7, in which a welding electrode not satisfying the requirements of our method was used, the nugget thickness/diameter did not satisfy the condition of being less than 0.22. For Nos. 9 and 11, the nugget diameter was insufficient. Furthermore, for Nos. 1, 8, 10, 12, and 13, nugget formation was not observed, and burn-through occurred.

Example 2

(49) Indirect spot welding was performed under the same conditions as Example 1 for Nos. 1 to 6, except that the sheet thickness of the upper steel sheet was 1.0 mm, the sheet thickness of the lower sheet was 0.7 mm, and the conditions on the electrode shape of the welding electrode, the time periods from turning on to turning off electricity, and the electrode force and current in each time period were set as shown in Table 4.

(50) TABLE-US-00004 TABLE 4 Electrode shape Electrode force/Current/Time electrode Top: electrode force (N)/time (s) No. Standard R (mm) r.sub.1 (mm) r.sub.2 (mm) radius (mm) Bottom: current (kA)/time (s) 1 Comparative 1.5 20 6 6 200/0.18 Example 8.0/0.18 2 Example 2 40 6 6 200/0.18 8.0/0.18 3 Example 3 60 8 8 200/0.18 8.0/0.18 4 Example 4 70 8 8 200/0.18 8.0/0.18 5 Example 5 60 9.5 9.5 200/0.18 8.0/0.18 6 Comparative 6 60 8 8 200/0.18 Example 8.0/0.18

(51) The electrode shape of the welding electrode used in Nos. 2 to 5 in Table 4 satisfies the requirements of our method. On the other hand, the electrode shape of the welding electrode used in Nos. 1 and 6 does not satisfy the requirements of our method. The electrode force F and the current C are constant in Nos. 1 to 6 in Table 4.

(52) Table 5 shows the nugget diameter, nugget thickness, and nugget thickness/diameter of each joint, and also shows observations of defects in appearance, for the welding performed in accordance with the electrode shapes and current application patterns shown in Table 4. The nugget diameter and nugget thickness in Table 5 are as described in Example 1. If the nugget diameter is 3.4 mm or more and the nugget thickness/diameter is 0.20 or more, the nugget may be judged as being suitable.

(53) As for defects in appearance caused by fusion and scattering of the weld, the occurrence of splattering and dropping occurring at the lower steel sheet of the weld was disclosed in Table 5 as burn-through.

(54) Furthermore, overall evaluation was made based on the following criteria. Pass: nugget diameter of 3.4 mm or more, nugget thickness/diameter of 0.20 or more, and no defect in appearance Fail: satisfaction of any one of the conditions of nugget diameter of less than 3.4 mm, nugget diameter thickness/diameter of less than 0.20, or a defect in appearance

(55) TABLE-US-00005 TABLE 5 Nugget diameter Nugget thickness Nugget thickness/ Defect in Overall No. Standard (mm) (mm) diameter appearance evaluation 1 Comparative 0 0 burn through Fail Example 2 Example 3.8 1.0 0.26 none pass 3 Example 3.9 0.9 0.23 none pass 4 Example 3.6 0.8 0.22 none pass 5 Example 3.4 0.7 0.21 none pass 6 Comparative 3.2 0.5 0.16 none pass Example

(56) As shown in Table 5, for Nos. 2 to 5, in which indirect spot welding was performed using a welding electrode satisfying the requirements of our method with respect to a sheet thickness of 0.7 mm for the thinner steel sheet, a fused nugget with a sufficient nugget diameter and sufficient thickness for the diameter were obtained, and no defect in appearance whatsoever was observed, even under the intentionally established conditions that impeded the formation of a nugget directly below the electrode.

(57) By contrast, for No. 6, in which a welding electrode not satisfying the requirements of our method was used, the nugget diameter was insufficient, and the nugget thickness/diameter was less than 0.20. For No. 1, nugget formation was not observed, and burn-through occurred.

INDUSTRIAL APPLICABILITY

(58) In our method, a welding electrode with an appropriately shaped electrode end portion is used. Therefore, an oval nugget formed after fusion between metal sheets can more stably be obtained even when current flow between the metal sheets at a location other than the weld, i.e., shunt current, is large.