Causes of solder ball formation: outgassing is the main culprit, but does not explain them all.Many articles written about post-wave-soldering solder ball In BGA chip packages, it is the tiny globe of solder that provides the contact between the chip package and the printed circuit board. Also called a "solder bump." See BGA. formation cite as the culprit outgassing Outgassing (sometimes called "Offgassing," particularly when in reference to indoor air quality) is the slow release of a gas that was trapped, frozen, absorbed or adsorbed in some material. , or vapor escaping. Generally this is true, but it does not explain the small solder balls often found between leads of wave-soldered connectors or SO-component leads. These are often positioned with a curious regularity. In fact, the physical mechanism behind the solder solder (sŏd`ər), metal alloy used in the molten state as a metallic binder. The type of solder to be used is determined by the metals to be united. Soft solders are commonly composed of lead and tin and have low melting points. Hard solders (i. separation process is responsible for the formation of this specific solder ball pattern. In wave soldering Applying liquid solder to the underside of printed circuit boards in order to bond the chips and discrete components that are placed on top of the board and whose metal leads (pins) extend through the board. , solder balls cannot be completely avoided since they are part of the process of solder separation. The liquid solder bridges all joints when the board is in the solder wave; however, when the board separates from the wave, all solder between the joints and between the wave and leads must separate. This separation process is similar to the behavior of water flowing from a tap that is closing. At first a large, steady liquid column flows from the tap. While closing the tap, this column becomes thinner and thinner. At a certain point during closing, the lower part of the column separates into a string of single droplets. That is how a thinning, freely-moving liquid flow behaves. It ultimately finds its optimal physical equilibrium by separating into single droplets. During separation of the solder, surface tension reduces the liquid surface area for a given liquid volume. This causes the solder to withdraw from the space between joints, both horizontally and vertically. Although this appears to be an uncontrolled process, it still obeys the physical laws. The liquid solder behaves like water. When the separation is almost complete, the thin solder column that exists between the joints on the board, and also between the wave and the lead, will end up in one or more single droplets. Normally, one will not find traces of that process unless the solder has a tendency to adhere to adhere to verb 1. follow, keep, maintain, respect, observe, be true, fulfil, obey, heed, keep to, abide by, be loyal, mind, be constant, be faithful 2. the soldermask. In that case, a specific pattern of solder balls can be found between the joints. This is especially true with closely spaced solder joints, such as between SO-component leads, where these small balls sometimes form with a mathematical regularity. Figure 1 illustrates the formation of water (and by extension solder) globules and thus the formation of solder balls in wave soldering. The thin water flow from the tap was made with a professional camera using a short shutter (1) An opaque window that is moved in one direction to let light in and in another to close off the light. In fixed-lens cameras, one shutter often suffices for aperture and speed. time (1/1600 sec.). Single droplets are formed as the flow drops further from the tap. This cannot be seen with our eyes because the droplets are moving too fast to be seen as distinctly separate. However, when a single droplet droplet very small drop of fluid. droplet nuclei the finite particles of matter which are transmitted from animal to animal. hits a metal sink, one can hear the impact. [FIGURE 1 OMITTED] The soldered Pronounced "sod-erd." Permanently attached by a hard metal bond. In order to replace a chip soldered to a circuit board, it requires heating the soldering joints until they melt. Contrast with socketed. connector joints in Figure 2 show solder balls between the joints. The origin of these solder balls lies in the separation mechanism from the solder as it withdraws to the single joints. Like the water stream, tiny droplets can form, and their adhesive adhesive, substance capable of sticking to surfaces of other substances and bonding them to one another. The term adhesive cement is sometimes used in place of adhesive, especially when referring to a synthetic adhesive. behavior causes the tiny balls to stick to the soldermask. [FIGURE 2 OMITTED] Now the solder ball formation is explained, but why are they found on the board? Solder balls end up on the board surface due to the adhesion adhesion /ad·he·sion/ (ad-he´zhun) 1. the property of remaining in close proximity. 2. the stable joining of parts to one another, which may occur abnormally. 3. of the solder to the soldermask, in combination with flux residues. Refraining from using soldermask will usually eliminate the problem of solder ball adhesion, but is not always a viable option. A good combination of soldermask and flux can prevent this adhesion. The weakening of the soldermask during soldering soldering Process that uses metal alloys with low melting points to join metallic surfaces without melting them. Tin-lead solders, once widely used in the electrical and plumbing industries, are now replaced by lead-free alloys. might have an effect on solder ball adhesion. It is possible to reduce this effect by optimizing machine settings. In general, however, this problem can be solved only through proper material selection. Prevention is always better than trying to find a solution in the solder process settings. For more in-depth information about the physics that affect solder separation during solder drainage, see Chapter 2.2 of Soldering in Electronics, second edition, by R. J. Klein Wassink. Gert Schouten is a senior engineer at Vitronics Soltec (vitronicssoltec.com); gschouten@vsww.com. [ILLUSTRATION OMITTED] |
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