Fine Pitch Microdots Dispensing and Jetting Optimization in SiP Assembly using Welco Solder Paste

Current challenges in printed circuit board (PCB) assembly require high-resolution deposition of ultra-fine pitch components (<0.3 mm and <60 μm respectively), high throughput and compatibility with flexible substrates, which are poorly met by the conventional deposition techniques (e.g., stencil printing). Laser-Induced Forward Transfer (LIFT) constitutes an excellent alternative for assembly of electronic components: it is fully compatible with lead-free soldering materials and offers high-resolution printing of solder paste bumps (<60 μm) and throughput (up to 10,000 pads/s). In this work, the laser-process conditions which allow control over the transfer of solder paste bumps and arrays, with form factors in line with the features of fine pitch PCBs, are investigated. The study of solder paste as a function of donor/receiver gap confirmed that controllable printing of bumps containing many microparticles is feasible for a gap < 100 μm from a donor layer thickness set at 100 and 150 μm. The transfer of solder bumps with resolution < 100 μm and solder micropatterns on different substrates, including PCB and silver pads, have been achieved. Finally, the successful operation of a LED interconnected to a pin connector bonded to a laser-printed solder micro-pattern was demonstrated.

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A Study of the Aperture Filling Process in Solder Paste Stencil Printing

10.1115/imece1999-0920 ◽

1999 ◽

Author(s):

Jianbiao Pan ◽

Gregory L. Tonkay

Keyword(s):

Flip Chip ◽

Deposition Process ◽

Area Ratio ◽

Solder Paste ◽

Stencil Printing ◽

Printing Process ◽

Surface Mount ◽

Fine Pitch ◽

Main Indicator ◽

Advanced Packaging

Abstract Stencil printing has been the dominant method of solder deposition in surface mount assembly. With the development of advanced packaging technologies such as ball grid array (BGA) and flip chip on board (FCOB), stencil printing will continue to play an important role. However, the stencil printing process is not completely understood because 52–71 percent of fine and ultra-fine pitch surface mount assembly defects are printing process related (Clouthier, 1999). This paper proposes an analytical model of the solder paste deposition process during stencil printing. The model derives the relationship between the transfer ratio and the area ratio. The area ratio is recommended as a main indicator for determining the maximum stencil thickness. This model explains two experimental phenomena. One is that increasing stencil thickness does not necessarily lead to thicker deposits. The other is that perpendicular apertures print thicker than parallel apertures.

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Fine Pitch Surface Mount Technology Assembly with Lead‐free, Low Residue Solder Paste

Soldering & Surface Mount Technology ◽

10.1108/eb037896 ◽

1995 ◽

Vol 7 (2) ◽

pp. 27-32 ◽

Cited By ~ 12

Author(s):

I. Artaki ◽

A.M. Jackson ◽

P.T. Vianco

Keyword(s):

Lead Free ◽

Surface Mount Technology ◽

Solder Paste ◽

Surface Mount ◽

Fine Pitch

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Fine Pitch Soldering and Solder Paste

Handbook of Fine Pitch Surface Mount Technology ◽

10.1007/978-1-4684-1437-0_5 ◽

1994 ◽

pp. 161-193

Author(s):

Jennie S. Hwang

Keyword(s):

Solder Paste ◽

Fine Pitch

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Head-on-Pillow Defect Detection: X-Ray Inspection Limitations

Journal of Microelectronics and Electronic Packaging ◽

10.4071/imaps.871613 ◽

2019 ◽

Vol 16 (2) ◽

pp. 91-102

Author(s):

Lars Bruno ◽

Benny Gustafson

Keyword(s):

Solder Joints ◽

Solder Paste ◽

Wafer Level ◽

Reflow Soldering ◽

X Ray ◽

Soldering Process ◽

Irregular Shapes ◽

Fine Pitch ◽

Solder Balls ◽

Ball Grid Array Packages

Abstract Both the number and the variants of ball grid array packages (BGAs) are tending to increase on network printed board assemblies with sizes ranging from a few millimeter die size wafer level packages with low ball count to large multidie system-in-package (SiP) BGAs with 60–70 mm side lengths and thousands of I/Os. One big challenge, especially for large BGAs, SiPs, and for thin fine-pitch BGA assemblies, is the dynamic warpage during the reflow soldering process. This warpage could lead to solder balls losing contact with the solder paste and its flux during parts of the soldering process, and this may result in solder joints with irregular shapes, indicating poor or no coalescence between the added solder and the BGA balls. This defect is called head-on-pillow (HoP) and is a failure type that is difficult to determine. In this study, x-ray inspection was used as a first step to find deliberately induced HoP defects, followed by prying off of the BGAs to verify real HoP defects and the fault detection correlation between the two methods. The result clearly shows that many of the solder joints classified as potential HoP defects in the x-ray analysis have no evidence at all of HoP after pry-off. This illustrates the difficulty of determining where to draw the line between pass and fail for HoP defects when using x-ray inspection.

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Lead Free Paste with under 3um Solder Particles for Fine Pitch C4 bumping and pre-coating solder applications

Additional Conferences (Device Packaging HiTEC HiTEN & CICMT) ◽

10.4071/2013dpc-tp25 ◽

2013 ◽

Vol 2013 (DPC) ◽

pp. 000862-000889

Author(s):

Hironori Uno ◽

Masayuki Ishikawa ◽

Akihiro Masuda ◽

Hiroki Muraoka ◽

Kanji Kuba

Keyword(s):

Chemical Reduction ◽

Average Particle Size ◽

Average Particle ◽

Solder Paste ◽

Chemical Reduction Method ◽

Property Evaluation ◽

Fine Pitch ◽

Solder Bumps ◽

Size Of Particles ◽

Average Size

The work to be detailed in this paper is our development of 96.5mass%Sn-3.0mass%Ag-0.5mass%Cu fine solder particles with an average particle size of under 3um (D50), using a chemical reduction method. An evaluation was conducted on the properties of the particles. The average size of particles appeared to be under 3um with a higher yield compared to particles using the conventional gas atomization method. The melting temperature of fine solder particles using this method was its eutectic temperature, which is same as using the gas–atomized particles. 120um pitch solder bumps from the solder paste using the above mentioned fine solder particles were created on the substrate. As a result of property evaluation, it was turned out that the solder paste created a superior printing shape and coplanarity compared to the conventional paste with gas-atomized particles. In order to investigate the superior printing property generated by the paste with fine solder particles, the rheology of the paste was evaluated.It was verified that the anisotropic shape of particles has contributed to prevent the printed paste from slumping, which has resulted in the improvement of printed shape. It also shows that the filling characteristic of the paste was improved by the smaller particles and the better coplanarity was observed. The importance of finer solder particles for finer pitch assembly will be presented.

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Ultra-Thin, Fine-Pitch Step Stencils For Miniature Component Assembly

Additional Conferences (Device Packaging HiTEC HiTEN & CICMT) ◽

10.4071/2017dpc-poster_vallabhajosyula ◽

2017 ◽

Vol 2017 (DPC) ◽

pp. 1-18

Author(s):

Phani Vallabhajosyula

Keyword(s):

Visual Inspection ◽

Flip Chip ◽

Print Quality ◽

Solder Paste ◽

3D Measurement ◽

Aperture Size ◽

Fine Pitch ◽

Technology Applications ◽

Component Assembly ◽

Special Step

Mixed technology applications for Flip-Chip (FC) / SMT require special step stencil designs where flux is printed first for the FC and SMD paste printed next with a second stencil that has a relief pocket etched or formed in the FC area. Step stencils are used when varying stencil thicknesses are required to print into cavities or on elevated surfaces or to provide relief for certain features on a board. In the early days of SMT assembly, Step Stencils were used to reduce the stencil thickness for 25 mil pitch leaded device apertures. Thick metal stencils that have both relief-etch pockets and reservoir step pockets are very useful for paste reservoir printing. However as SMT requirements became more complex and consequently more demanding so did the requirements for complex Step Stencils. Electroform Step-Up Stencils for ceramic BGA's and RF Shields are a good solution to achieve additional solder paste height on the pads of these components as well as providing exceptional paste transfer for smaller components like uBGAs and 0201s. As the components are getting smaller, for example 0201m, or as the available real estate for component placement on a board is getting smaller – finer is the aperture size and pitch on the stencils. Aggressive distances from step wall to aperture are also required. Ultra-thin stencils with thicknesses in the order of 40um with steps of 13um are used to obtain desired print volume. These applications and the associated stencil design to achieve a solution will be discussed in detail in this paper. Various print experiments will be conducted and print quality will be determined by visual inspection and 3D measurement of the paste deposit to understand the volume transfer efficiency.

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Reliability Study of Solder Paste Alloy for the Improvement of Solder Joint at Surface Mount Fine-Pitch Components

Materials ◽

10.3390/ma7127706 ◽

2014 ◽

Vol 7 (12) ◽

pp. 7706-7721 ◽

Cited By ~ 5

Author(s):

Mohd Rahman ◽

Noor Zubir ◽

Raden Leuveano ◽

Jaharah Ghani ◽

Wan Mahmood

Keyword(s):

Solder Joint ◽

Solder Paste ◽

Reliability Study ◽

Surface Mount ◽

Fine Pitch

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Solder paste characteristics and their effect on fine pitch printing

10.1049/cp:19940914 ◽

1994 ◽

Author(s):

M.A. Currie

Keyword(s):

Solder Paste ◽

Fine Pitch

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A Repeatable and Reliable Rework Process for Lead-Free Fine Pitch BGA’s

Electronic and Photonic Packaging, Electrical Systems Design and Photonics, and Nanotechnology ◽

10.1115/imece2005-83026 ◽

2005 ◽

Author(s):

Deepak Manjunath ◽

Satyanarayan Iyer ◽

Shawn Eckel ◽

Purushothaman Damodaran ◽

Krishnaswami Srihari

Keyword(s):

Primary Objective ◽

Lead Free ◽

Process Window ◽

Solder Paste ◽

Ball Grid Arrays ◽

Joint Reliability ◽

Fine Pitch ◽

Pros And Cons ◽

Free Solder ◽

Rework Process

Fine pitch leadless components, such as Ball Grid Arrays (BGAs) and Chip-Scale Packages (CSPs), are increasingly used in modern day circuitry to aid miniaturization. Assembling these surface mount components using lead-free solder pastes has been a subject of interest for the past several years. Reworking a BGA is complicated as the solder joints are hidden underneath the component. The process window available for the rework process is very narrow and there are number of other critical factors, which complicate and affect the repeatability of the rework process. Consequently, the primary objective of this research endeavor is to develop a reliable and a repeatable process to rework lead-free fine pitch BGAs. The process steps to rework a BGA are component removal, site redressing, solder paste/flux deposition, component replacement and reflow. This experimental study evaluates a number of alternatives for several rework process steps during the course of developing a reliable and repeatable rework process. Two alternatives for site redressing namely, (i) copper wick with soldering iron, and (ii) vacuum de-soldering methods are evaluated. Similarly the application of solder paste versus gel flux is compared. A localized reflow method for replacing the component at the SRT machine is developed and it is compared with forced convection in reflow oven. The pros and cons of using the two reflow methods and the effect of multiple reflows on solder joint reliability is discussed in the paper. A reliability study was conducted on the samples and the results are presented to compare the various alternatives.

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