KR20180007176A - Metal sheets spot welding with inoculation agents - Google Patents

Abstract

The present invention relates to a spot welding method of two sheets, mainly formed by zinc-plated steel sheets. The present invention comprises: a step of predetermining a position area where a welding spot is formed on two sheets coming in contact with each other; a step of applying substances having inoculation particles on at least one surface among the sheets in the preliminarily described position area; and a step of spot-welding the preliminarily described position area by allowing a current to flow through the sheets via a pair of electrodes, wherein the particles comprise at least one substance selected from a group comprising a C + Ti-B alloy (a) and an Al-Ti-B-Re alloy + C (b).

Description

FIELD OF THE INVENTION [0001] The present invention relates to metal sheets having inoculation agents,

The present invention relates generally to spot welding and metal seeding areas, and more particularly to spot welding methods combined with agglomerates inoculated into metal sheets to refine the welded crystal structure, To obtaining welds.

Resistance Spot Welding (RSW) is a process in which the contacting metal surfaces are joined by heat obtained from a resistor. The workpieces are held together under the pressure exerted by the electrodes. Typically, the sheets are in the 0.5 to 3 mm (0.020 to 0.118 in) thickness range. The process uses two types of copper alloy electrodes to concentrate the welding current in a small "spot" and simultaneously hold both sheets together. Applying a large current through the spot will melt the metal and form the weld. An attractive feature of spot welding is that a lot of energy can be delivered to the spot for a very short time (roughly 10-100 ms). It allows welding to occur without undue heating of the rest of the sheet.

The amount of heat (energy) transferred to the spot is determined by the resistance between the electrodes and the magnitude and time of the current. The amount of energy is chosen to match the material properties of the sheet, its thickness, and the type of electrodes. Applying too little energy will not melt the metal or create a bad weld. Applying too much energy will dissolve too much metal, release molten material, and make holes rather than welding. Another feature of spot welding is that the energy delivered to the spot can be controlled to produce reliable welds.

The most common application of spot welding is in the automotive and aircraft manufacturing industries where spot welding is used almost globally to weld sheet metal forming automobiles and aircraft. Spot welding is also used in hospitals of orthodontists, where small size spot welding equipment is used to resize metal "molar bands" used in orthodontics.

Other applications are spot welding straps in nickel-cadmium batteries or nickel-hydrogen batteries for making batteries. The batteries are bonded to thin nickel straps to battery terminals by spot welding. Spot welding ensures that the battery does not get too hot, which can happen if normal soldering is done.

Good design practices must always allow adequate accessibility. Connecting the surfaces must be free from contaminants such as scale, oil, and dust to ensure good welds. Metal thickness is generally not a factor in judging good welds.

Since automotive applications impose periodic stresses on body components over time, it is important that metal welds have adequate metal strength and resistance to fatigue.

To form resistive type spot welds between sheets of metal, the sheets are clamped together under pressure between a pair of welding electrodes, typically copper, and current flows through the area or "spot & And is passed between the electrodes. This current flow heats the metal material to its melting temperature in the spot, producing a molten weld mass which, when the molten chunks are cooled and solidified, forms a fusion weld whereby the metals from the two sheets join together toward each other. The solidification process is caused by the formation of ice crystals and the growth of new phases (solids) in solid / liquid interface evolution within the weld mass. In the molten weld mass, the solid phase is generally caused by the growth of epitaxy from the surfaces of the welded material, and is driven by the competitive growth into the center line of the weld. It tends to push crystals with their easiest growth direction oriented most preferentially according to the heat flow direction slope, crystals whose easy growth directions are not properly oriented (That is, grains with their easy growth direction oriented most preferentially along the direction of the heat flow, tend to crowd out those grains whose growth directions are not as suitably oriented. The crystal structure resulting from the weld is determined by the type of ice crystal formation and the growth of the solid phase. The colder the weld mass, the more solidification starting from the walls of the substrate results in the form of crystals growing against heat flow; These crystals are known as template crystals. Eventually, and depending on the solidification states, the equiaxed crystals form a weld mass in the central region. Temporal crystal structures, i.e., structures in which the crystals are elongated and tend to run parallel to each other, can be formed by welding having a lower mechanical strength compared to welding with equiaxed structures in which the crystals are uniform in size and arranged in any direction ≪ / RTI > In addition, the mechanical strength of the weld will be reduced even if the mold crystal structure is formed at the intersection of the weld mass and at the opening of the sheets in the vicinity of high stress areas. Solidified welds usually contain both template crystals and equiaxed crystals, surrounded by equiaxed crystals arranged in the center of the weld and the outer boundary layer of the template crystals. In order to increase the mechanical strength of the weld as well as the resistance to fatigue, it may be desirable to maximize the amount of equiaxed crystals relative to the amount of template crystals. The present invention is directed toward achieving this objective.

According to an aspect of the invention, there is provided a spot welding method of two sheets formed of mainly galvanized steel sheets, comprising the steps of:

Predetermining a position area where the welding spot is formed in two sheets that are in contact with each other;

Applying materials comprising inoculation particles onto the surface of at least one of the two sheets in the aforementioned location region;

Spot welding the preceding two sheets by passing current through the sheets through a pair of electrodes,

Wherein the particles comprise at least one material selected from the group consisting of (a) a C + Ti-B alloy, and (b) an Al-Ti-B-Re alloy +

An important advantage of the invention is not only to increase the mechanical properties of the metal welding, but also to improve the consistency of the welding quality by introducing a relatively inexpensive inoculation with the welding mass.

Another advantage of the invention is that general resistance welding equipment can be used to carry out the invention without increasing the welding cycle time.

These and other advantages and features of the invention will become apparent or obvious from a reading of the following description of a preferred embodiment of the invention.

The present invention includes fusion bonding, such as welding between two workpieces formed of a metal. Welding is generally referred to as spot welding, which can be produced using conventional resistance welding equipment, which is well known in the art. Such equipment typically includes a power source, and includes a pair of electrodes between which the two sheets are clamped with a predetermined force. Along with the sheets that are in contact with each other under pressure, the power source supplies current flowing through the facing surfaces of the sheets to produce a molten weld lump with the electrodes. Such a weld mass is solidified and cold to ideally form a weld having mechanical strength close to the mechanical strength of the metal sheet material itself.

As the weld mass cools, the molten metal crystallizes as the state changes from liquid to solid. During the cooling process, crystallization of the outer boundary layer occurs first, and solidification proceeds inward toward the center of the weld until the weld is completely crystallized. The crystallization of the outer boundary layer in the weld mass results in a template crystal structure in which individual crystals extend parallel to one another and extend longitudinally along longitudinal axes and tend toward the direction of heat flow. The outer boundary transitions to the central region where the crystal structure is an isostructural structure, that is, the individual crystals have their axes which are of equal size rather than elongate, and which are oriented randomly relative to one another. As discussed later, the equiaxed crystal structure of the central region tends to provide a weld having a superior mechanical strength and fatigue resistance as compared to a predominantly welded casting structure.

It has been found according to the invention that the strength of the weld formed between the workpieces can be improved by inoculating a molten weld lump with specific materials which tends to be particularly effective in promoting ice crystal formation of the equiaxed crystals as the lump solidifies do.

The inoculation is applied to one or both when the facing surfaces of the workpieces are welded. The inoculation may be in the form of a liquid or paste that is sprayed or brushed onto the workpiece surface, or the inoculation may be included in a carrier formed of a film or foil that is sandwiched between the workpiece surfaces before they are clamped and welded have.

The workpieces of metal sheets may be formed from a variety of materials suitable for spot welding including at least mild steel, galvanized steel, quenched steel, stainless steel, aluminum-plated steel, copper alloys, titanium alloys and aluminum alloys. The present invention can also be applied to spot welding other metal sheets.

For example, the position area of two sheets contacting each other where a welding spot is formed is predetermined. A small hole may be formed in the center of the location area of at least one of the two sheets. Inoculation particles can be placed in the hole. The two sheets are joined by flowing current through the sheets through a pair of electrodes. (A) Al + Ti, (b) Al + C,

(c) Ti + C, (d) Ti-B alloy + Al, (e) C + Ti-B alloy, (f) Al- (1) Zr + Al, (m) Na + Al, (n) Si + Na, (o) Al + Ba, (p) Sr + Zr, Al + Si, and (q) Si + Ba.

The diameter of the hole may be 0.1-1 mm. The depth of the hole can be 1 / 20-1 / 5 of the sheet. The particles may be in powder form. The two sheets may have the same or different depths.

The inoculated particles can be applied on the surface of at least one of the two sheets in the location area. The materials can be applied in the form of a film on the surface. The materials can be applied in the form of a paste on the surface. The thickness of the film can be in the range of 0.01-0.1 mm. The two sheets may have the same or different depths.

The method of the invention can be used with any of the inoculated particles listed above, although the ones described in the claims are preferred.

The test series was conducted to compare the characteristics of the welds produced with the inoculation according to the original method and the characteristics of the welds produced without the inoculation. These test results show that the mechanical properties of clearly inoculated welds are superior to those not inoculated.

Table 1 Mechanical properties of various metal sheets with and without inoculation agents.

The results of these tests are shown in Table 1, which clearly shows that the mechanical properties of inoculated welds according to the method of the present invention are significantly superior to those without inoculations. Again it can be seen that the welds provided with the inoculations according to the invention exhibit superior shear strength as compared to those without inoculations.

From the foregoing it can be appreciated that the welding lump inoculum described above provides advantages over previous welding methods as well as providing advantages in an especially effective and economical way. It is, of course, recognized that those skilled in the art can make various modifications or additions selected to illustrate the invention without departing from the spirit and scope of the present contribution to the description. It is therefore to be understood that the protection sought and the provision given herein are to be considered to be extended to all equivalents thereof, within the scope of the claimed subject matter and the invention.

Claims (5)

Predetermining a position area where the welding spot is formed in two sheets that are in contact with each other;
Applying materials comprising inoculation particles on the surface of at least one of the two sheets in the aforementioned location region;
And passing current through the sheets through a pair of electrodes to spot weld the two sheets previously mentioned,
The particles are formed of a sheet of two sheets formed of mainly galvanized steel sheets comprising at least one material selected from the group consisting of (a) C + Ti-B alloy, (b) Al-Ti-B- welding method. The method according to claim 1,
Wherein the materials are formed of mainly galvanized steel sheets which are applied in the form of a film on the aforementioned surface. The method according to claim 1,
The materials are formed from mainly galvanized steel sheets, which are applied in the form of a paste on the aforementioned surface. 3. The method of claim 2,
Wherein the thickness of the film is formed mainly of galvanized steel sheets in the range of 0.01-0.1 mm. The method according to claim 1,
Wherein the two sheets are formed of mainly galvanized steel sheets having the same or different depths.