FR2706139A1 - Material for soldering - Google Patents

Abstract

The subject of the present invention is a material for soldering, such as a solder paste, for mounting electronic components on a printed circuit. The material is composed of tin/lead particles (21) and particles (22) of a material chosen especially for its coefficient of expansion and its elastic modulus, both sets of particles being bound together with a flux (23).

Description

BRAZING MATERIAL
The present invention relates to a material for brazing, such as a solder paste.

 In the field of surface mounting of electronic components, or of boxes containing these components, on substrates of the printed circuit type, there is the problem of the reliability of the solder joints joining these components to the printed circuit. Indeed, a solder joint provides, on the one hand, an electrical connection function between the connection pads of the component and the corresponding connection areas of the printed circuit, but it also has the function, on the other hand, of ensure the mechanical fixing of the component on the printed circuit.

 As is known, difficulties may arise during variations in the surrounding temperature, in particular during rapid temperature variation cycles to which the electronic circuits are subjected during their tests. Indeed, on the one hand, the solder material is chosen for its physical and chemical properties: it must be metallurgically compatible with the copper which generally forms the connection pads, both of the component and of the printed circuit; it must also correctly "wet" the surfaces to be brazed, that is to say have good adhesion to these surfaces, and finally it must have a viscosity adapted to the use which is made of them. The solder materials generally used are based on tin-lead. In addition, the printed circuit is generally either in epoxy or ceramic (alumina, frequently) and the housings are either plastic, or also ceramic. It appears that the coefficients of expansion of these three elements are different and, even in the case where the printed circuit and case are made of ceramic, these differences are sufficient to cause cracks to appear in the solder joint and allow corrosion to occur. install in cracks, corrosion which tends to enlarge the cracks. The whole mechanism can lead to the rupture of the solder joint, with its damaging consequences both electrically and mechanically.

The subject of the present invention is a solder material which makes it possible to avoid, or at least greatly limit, this type of problem, by introducing into a solder material based on tin-lead, distributed grains of a substance. whose physical and chemical properties and proportion are such that:
they bring the coefficient of expansion of the assembly to an intermediate value between that of the component and that of the printed circuit;
the resulting elastic modulus is sufficient to absorb the differences in elongation due to the differences in residual expansion coefficients;
their melting point is higher than that of tin lead,
and finally that these grains do not substantially modify the metallurgical and rheological properties, in particular of wetting and viscosity, of the solder.

Other objects, features and results of the invention will emerge from the following description, given by way of example and illustrated by the appended drawings, which represent:
- Figure la, the diagram of a component mounted on a printed circuit substrate;
- Figure 1b, a detail of the previous figure;
- Figure 2, a sectional view of the material according to the invention.

 In FIG. 1 a, an electrically insulating substrate C1, of the printed circuit type, for example made of epoxy or ceramic, is therefore shown, seen in section, conventionally carrying conductive zones for the connection of components, interconnected by equally conductive tracks. . These zones and tracks are generally made by metallic deposition, most of the time in copper.

According to the so-called flat mounting technique, also called surface mounting, the electronic components or microcircuits, whether or not placed in a housing and symbolized in FIG. 1 a by a rectangle
C, are both mechanically fixed to the substrate and electrically connected to the connection zones provided for this purpose on the substrate, directly using a solder joint J and not by pins or connection lugs.

 Figure lb shows an enlargement of part A of Figure la, containing a solder joint J.

 In this figure, there is shown, in section, a fraction of the printed circuit Cl, a fraction of the component C and the shape that generally affects the seal J, extending under the component and rising slightly along its face. lateral.

 As explained above, the choice of brazing material is made according to its physicochemical properties, in particular compatibility with copper, wetting and viscosity, and results in retaining a tin alloy -lead, with generally a few percent of silver, which has a coefficient of expansion different from that of the materials usually forming the component, its casing or the printed circuit.

 It can be seen that, during temperature variations, the seal J is subjected to mechanical stresses both along an axis Ox, parallel to the plane of the printed circuit Cl, and along an axis Oz, perpendicular to this latter plane.

 FIG. 2 represents a section made in a solder paste according to the invention.

 A solder paste is usually made up of grains 21 of a tin-lead alloy, possibly with the addition of silver, substantially spherical (with a diameter of the order of a few tens of micrometers), linked by a material 23 called flux, so as to constitute a paste.

According to the invention, grains 22 of a substance chosen according to the following criteria are added to this paste:
its coefficient of expansion must be such that, as a function of the proportion of grains 22 relative to grains 21, it brings the coefficient of expansion of the whole of the dough to an intermediate value between that of component C and that of the printed circuit Cl;
its modulus of elasticity must be such that, always as a function of the proportion of the grains 22, it brings the modulus of elasticity of the whole of the dough to a value sufficient to absorb (without the formation of cracks) the differences in elongation that occurs during temperature variations, differences in elongation due to residual differences in the values of the expansion coefficients;
its melting temperature must be higher than that of the tin-lead alloy (- silver), in order not to disturb the properties of the solder and to avoid any modification of the brazing machines and existing processes;
more generally, the substance of the grains 22 and the proportion of the grains must be such that they do not substantially modify the metallurgical and rheological properties, in particular wetting and viscosity of the solder. In particular, substance 22 should preferably not dissolve in tin-lead, nor interact chemically or metallurgically with tin-lead.

 By way of example, the grains 22 may consist of metal, for example nickel or graphite covered with nickel or plastic or plastic covered with a metallic film, nickel for example, or also by a shape memory alloy, for example a copper-zincaluminium alloy, the shape memory alloys generally having a very high elasticity.

 For example, for 22 nickel grains with a diameter of around 40 μm, the elastic limit expressed in Pascals, of the conventional SnPbAg alloy (63-36-2) is notably improved, by around 50%. for a proportion of 10% of nickel grains. Still by way of example, in the case of grains of shape memory alloy (Cu-Zn-Al), the limit of the preceding SnPbAg alloy passes, at 20 "C, from 56 MPa to 140 MPa, while the modulus of elasticity goes from 43 GPa to 78 GPa.

 The invention has been described above in the context of the surface mounting of the components, an area where it is particularly advantageous.

However, it also applies to the case where the components are mounted on the printed circuit by means of lugs. In fact, this case also leads to reliability problems because the elasticity of the tabs may not completely compensate for the mechanical mismatch between the housing and the printed circuit.

Claims (8)

 1. Solder material, intended to form a solder joint between an electronic component (C) and a printed circuit substrate (Cl), comprising grains (21) of a tin-lead alloy bonded by a flux (23), the material being characterized by the fact that it also comprises grains (22) a substance whose physicochemical properties and the proportion are such that:  the coefficient of expansion of the material is brought to an intermediate value between that of the component and that of the substrate  the modulus of elasticity of the material is sufficient to absorb the differences in elongation likely to occur during temperature variations;  the melting point of the substance is higher than that of the alloy;  such does not substantially modify the metallurgical and rheological properties of the material.  2. Material according to claim 1, characterized in that the substance is a metal or a metal alloy.  3. Material according to claim 1, characterized in that the substance is nickel.  4. Material according to claim 1, characterized in that the grains are formed of graphite coated with nickel.  5. Material according to claim 1, characterized in that the substance is a plastic.  6. Material according to claim 5, characterized in that the plastic grains are covered with a metallic film.  7. Material according to claim 1, characterized in that the substance is a shape memory alloy.  8. Material according to claim 7, characterized in that the alloy comprises copper, zinc and aluminum.