Today’s advanced packages for electronics are required to meet a wide range of requirements for reliability,size and cost.
Surface mount technology still prevails in low cost electronics (televisions,VCR’s,washing machines,etc). Most surface
mount IC’s are wire-bonded,molded devices,and not considered “advanced packaging”. The challenges in packaging
increase as the need for portability,performance,or reliability increases. The size and performance constraints of notebook
computers,mobile phones,gaming devices and other handheld portable electronics are drivers,as is automotive electronics.
The mantra “smaller,faster,cheaper” has turned into a fevered battle cry in electronics manufacturing today.
Automated Fluid dispensing is a process found throughout electronics manufacturing. Notable among the applications are die
attach adhesives,wire bond encapsulants,and flip-chip underfills. Materials manufacturers continue to innovate,enabling
new processes to develop,as well as bringing the cost to manufacture down. Traditional needle dispensing is a mature
solution to many of the manufacturing challenges that exist. But a new application method,known as jetting,is breaking
formerly established barriers and enabling new applications that simply were not possible with traditional techniques.
This presentation discusses the physical action of jetting and highlights the fluid parameters that relate to jetting. The main
advantage to jetting arises from the fact that the fluid is imparted with momentum and is actually shot from the nozzle. This
property not only affects the flow rate through the nozzle,but also considerably affects the overall rate of the entire process.
The jetting process is independent of the dispense gap,a highly important parameter in needle dispensing. (The surface of the
substrate is used to pull the fluid deposit from the needle.)
Because proximity to the dispensing surface is a critical parameter of needle dispensing,it is usual for the robot controller to
use precious time moving the needle to the correct Z-location for each deposit. With jetting the robot can literally fly above
the surface and shoot from a distance,eliminating Z-axis motion time as well as many of the dwells and delays used to
account for the flow of the material from the needle.
Additionally,the dimensions of the fluid stream from a jet permit control of the fluid to never-before-possible restricted areas.
Stacked Die,RF shields,and sub-250 micron fillets for underfill are now not only possible but a production reality.
The bulk of underfill processing throughout the semiconductor industry has turned to jetting as a new and improved method
because of its inherent speed and precision. A brief review of the many dispensing applications in electronics will establish
the landscape into which jetting fits. Specific dispensing applications are detailed; with traditional fluid application methods
shown. The impact that the new jetting technology has on cost and productivity is then discussed.
