Elementary, Mr. Watson: Design Data Packages—Circle of Concern or Circle of Influence?
Fresh PCB Concepts: The Power of a Lunch & Learn for PCB Professionals
The Shaughnessy Report: Solving the Data Package Puzzle
Material Witness: Low-Flow Prepregs–Defining the Process
March 19, 2015 | Chet GuilesEstimated reading time: 5 minutes
One of my favorite authors once wrote about perception: “For now we see in a mirror, dimly…” speaking in an era when mirrors were at best polished metal surfaces. In the infancy of low-flow products, we used to speak about “no-flow” prepregs as if “no-flow” was sufficient definition of the product, but as we have recently pointed out in our discussions of rheology, “everything flows.” And as we consider these increasingly essential but sometimes hard-to-define products, much consideration will have to be given to what the products need to do, how they do it, how we test them, what the testing means, and how or if the testing relates meaningfully to how the products work in a PWB rigid-flex production environment.
Let’s try to define “low flow” in terms that will make sense to both suppliers and users of the products. A low-flow prepreg is a prepreg that flows sufficiently to wet out and adhere to bonding surfaces and to fill inner layer copper details, but does not flow so much as to fill in cut-out areas in a heat sink or run unevenly out of the interface between rigid and flexible elements of a rigid-flex PWB. That being said, how to define that flow quantitatively and to control it in such a way that the resulting product has wide applicability in a variety of PWB heat-sink and rigid-flex designs has been an issue with both producers and users of the products since the introduction of the concept. (My personal involvement in low flow materials began in the Early Mesozoic Period.)
How low is low flow compared to “normal” prepregs? Figure 1, the chart labeled as 35N Rheology, and Figure 2, 47N Rheology, are respectively a standard polyimide prepreg—35N—with a minimum viscosity about 800 poise at heat-up rate 5oC/minute, and a standard epoxy low-flow product—47N—with a minimum viscosity about 8000 poise at heat-up rate of 5oC/minute. As you can see, the viscosity of the low-flow product is about an order of magnitude higher than that of the full-flow prepreg.
Note also that as the heat-up rate is adjusted, the minimum viscosity of the low-flow product behaves similar to that of a standard-flow resin. As the heat-up rate increases, the minimum melt viscosity is lower, and hence, the product will flow more, all other conditions being equal. If only it were practical to use a three-temperature ramp rate test to characterize low-flow products during manufacture!
Instead, we have an IPC test procedure (IPC TM-650 2.3.17.2) that defines low flow in terms of average reduction of the diameter of a cut-out circle when the material is tested under “standard” conditions of temperature and pressure. Page 1 of 2
Share on:
Suggested Items
RF PCB Design Tips and Tricks
05/08/2025 | Cherie Litson, EPTAC MIT CID/CID+There are many great books, videos, and information online about designing PCBs for RF circuits. A few of my favorite RF sources are Hans Rosenberg, Stephen Chavez, and Rick Hartley, but there are many more. These PCB design engineers have a very good perspective on what it takes to take an RF design from schematic concept to PCB layout.
Trouble in Your Tank: Causes of Plating Voids, Pre-electroless Copper
05/09/2025 | Michael Carano -- Column: Trouble in Your TankIn the business of printed circuit fabrication, yield-reducing and costly defects can easily catch even the most seasoned engineers and production personnel off guard. In this month’s column, I’ll investigate copper plating voids with their genesis in the pre-plating process steps.
Elephantech: For a Greener Tomorrow
04/16/2025 | Marcy LaRont, PCB007 MagazineNobuhiko Okamoto is the global sales and marketing manager for Elephantech Inc., a Japanese startup with a vision to make electronics more sustainable. The company is developing a metal inkjet technology that can print directly on the substrate and then give it a copper thickness by plating. In this interview, he discusses this novel technology's environmental advantages, as well as its potential benefits for the PCB manufacturing and semiconductor packaging segments.
Trouble in Your Tank: Organic Addition Agents in Electrolytic Copper Plating
04/15/2025 | Michael Carano -- Column: Trouble in Your TankThere are numerous factors at play in the science of electroplating or, as most often called, electrolytic plating. One critical element is the use of organic addition agents and their role in copper plating. The function and use of these chemical compounds will be explored in more detail.
IDTechEx Highlights Recyclable Materials for PCBs
04/10/2025 | IDTechExConventional printed circuit board (PCB) manufacturing is wasteful, harmful to the environment and energy intensive. This can be mitigated by the implementation of new recyclable materials and technologies, which have the potential to revolutionize electronics manufacturing.