Large-area, low-cost via formation and metallization in multilayer thin film interconnection on Printed Wiring Boards (PWB)

Li, Weiping

05 1900

No description available.

Integrated circuits

Microelectronics

Electronic circuits

Printed circuits Design and construction

The feasibility of the manufacturing of a printed circuit type heat exchanger produced from graphite / Izak Jacobus Venter de Kock

De Kock, Izak Jacobus Venter

January 2009

The development of high temperature heat exchangers will play a vital part in the success of High Temperature Nuclear Reactors (HTRs). Manufacturing such heat exchangers from metals is becoming increasingly difficult as the operating temperatures keep rising. Above 1000'C most metals loose their strength and have high creep rates, while certain ceramic materials (including graphite, in the absence of oxygen) are able to operate at these temperatures. A literature study was done in order to identify the major problems regarding the use of graphite for heat exchanger construction as well as to investigate to what extent graphite has been used for heat exchanger construction in the past. Following from the literature survey, it was decided to design and manufacture a Printed Circuit Heat Exchanger (PCHE) from isotropic graphite to gain experience regarding the use of graphite as a heat exchanger material. This heat exchanger was then tested in order to learn about the operation of a graphite heat exchanger and to determine its effectiveness. A model ofthe heat exchanger was also constructed in order to determine what the performance of such a heat exchanger should theoretically be. It was found that the single greatest hurdle standing in the way ofgraphite being used as a heat exchanger material is its high gas permeability. This causes mixing between the two fluid streams as well as leakages to the environment, which have a negative effect on the heat exchanger's heat transfer capability. The methods used to establish a seal between the consecutive plates of the PCHE are also affected by the permeability of the graphite. Coatings on the surface of the graphite might be able to reduce its permeability and can also inhibit the high temperature degradation of graphite in the presence of oxygen. Manufacturing very small flow channels for the PCHE is limited by the availability of small enough end mills. Alternative manufucturing techniques is needed to economically construct a graphite PCHE. It was also found that the heat transfer effectiveness of the heat exchanger is influenced negatively by heat losses to the environment through the outer surface ofthe heat exchanger. Effective insulation around the heat exchanger or a graphite material :vith higher heat conductivity perpendicular to the flow direction might solve this problem. This study concluded that if diffusion bonding techniques, effective coatings and a graphite material with increased heat conductivity perpendicular to the flow direction are used, manufacturing a printed circuit heat exchanger from graphite is feasible. / Thesis (M.Ing. (Nuclear Engineering))--North-West University, Potchefstroom Campus, 2010

Graphite

Printed Circuit

Heat Exchanger

Manufucturing

IHX

HTR

The feasibility of the manufacturing of a printed circuit type heat exchanger produced from graphite / Izak Jacobus Venter de Kock

De Kock, Izak Jacobus Venter

January 2009

The development of high temperature heat exchangers will play a vital part in the success of High Temperature Nuclear Reactors (HTRs). Manufacturing such heat exchangers from metals is becoming increasingly difficult as the operating temperatures keep rising. Above 1000'C most metals loose their strength and have high creep rates, while certain ceramic materials (including graphite, in the absence of oxygen) are able to operate at these temperatures. A literature study was done in order to identify the major problems regarding the use of graphite for heat exchanger construction as well as to investigate to what extent graphite has been used for heat exchanger construction in the past. Following from the literature survey, it was decided to design and manufacture a Printed Circuit Heat Exchanger (PCHE) from isotropic graphite to gain experience regarding the use of graphite as a heat exchanger material. This heat exchanger was then tested in order to learn about the operation of a graphite heat exchanger and to determine its effectiveness. A model ofthe heat exchanger was also constructed in order to determine what the performance of such a heat exchanger should theoretically be. It was found that the single greatest hurdle standing in the way ofgraphite being used as a heat exchanger material is its high gas permeability. This causes mixing between the two fluid streams as well as leakages to the environment, which have a negative effect on the heat exchanger's heat transfer capability. The methods used to establish a seal between the consecutive plates of the PCHE are also affected by the permeability of the graphite. Coatings on the surface of the graphite might be able to reduce its permeability and can also inhibit the high temperature degradation of graphite in the presence of oxygen. Manufacturing very small flow channels for the PCHE is limited by the availability of small enough end mills. Alternative manufucturing techniques is needed to economically construct a graphite PCHE. It was also found that the heat transfer effectiveness of the heat exchanger is influenced negatively by heat losses to the environment through the outer surface ofthe heat exchanger. Effective insulation around the heat exchanger or a graphite material :vith higher heat conductivity perpendicular to the flow direction might solve this problem. This study concluded that if diffusion bonding techniques, effective coatings and a graphite material with increased heat conductivity perpendicular to the flow direction are used, manufacturing a printed circuit heat exchanger from graphite is feasible. / Thesis (M.Ing. (Nuclear Engineering))--North-West University, Potchefstroom Campus, 2010

Graphite

Printed Circuit

Heat Exchanger

Manufucturing

IHX

HTR

Inkjet-printed Light-emitting Devices: Applying Inkjet Microfabrication to Multilayer Electronics

Angelo, Peter

02 August 2013

This work presents a novel means of producing thin-film light-emitting devices, functioning according to the principle of electroluminescence, using an inkjet printing technique. This study represents the first report of a light-emitting device deposited completely by inkjet printing. An electroluminescent species, doped zinc sulfide, was incorporated into a polymeric matrix and deposited by piezoelectric inkjet printing. The layer was printed over other printed layers including electrodes composed of the conductive polymer poly(3,4-ethylenedioxythiophene), doped with poly(styrenesulfonate) (PEDOT:PSS) and single-walled carbon nanotubes, and in certain device structures, an insulating species, barium titanate, in an insulating polymer binder. The materials used were all suitable for deposition and curing at low to moderate (<150°C) temperatures and atmospheric pressure, allowing for the use of polymers or paper as supportive substrates for the devices, and greatly facilitating the fabrication process. The deposition of a completely inkjet-printed light-emitting device has hitherto been unreported. When ZnS has been used as the emitter, solution-processed layers have been prepared by spin-coating, and never by inkjet printing. Furthermore, the utilization of the low-temperature-processed PEDOT:PSS/nanotube composite for both electrodes has not yet been reported. Device performance was compromised compared to conventionally prepared devices. This was partially due to the relatively high roughness of the printed films. It was also caused by energy level misalignment due to quantization (bandgap widening) of the small (<10 nm) nanoparticles, and the use of high work function cathode materials (Al and PEDOT:PSS). Regardless of their reduced performance, inkjet printing as a deposition technique for these devices presents unique advantages, the most notable of which are rapidity of fabrication and patterning, substrate flexibility, avoidance of material wastage by using drop-on-demand technology, and the need for only one main unit operation to produce an entire device.

inkjet printing

printed electronics

nanomaterials

pulp & paper

0542

Inkjet-printed Light-emitting Devices: Applying Inkjet Microfabrication to Multilayer Electronics

Angelo, Peter

02 August 2013

This work presents a novel means of producing thin-film light-emitting devices, functioning according to the principle of electroluminescence, using an inkjet printing technique. This study represents the first report of a light-emitting device deposited completely by inkjet printing. An electroluminescent species, doped zinc sulfide, was incorporated into a polymeric matrix and deposited by piezoelectric inkjet printing. The layer was printed over other printed layers including electrodes composed of the conductive polymer poly(3,4-ethylenedioxythiophene), doped with poly(styrenesulfonate) (PEDOT:PSS) and single-walled carbon nanotubes, and in certain device structures, an insulating species, barium titanate, in an insulating polymer binder. The materials used were all suitable for deposition and curing at low to moderate (<150°C) temperatures and atmospheric pressure, allowing for the use of polymers or paper as supportive substrates for the devices, and greatly facilitating the fabrication process. The deposition of a completely inkjet-printed light-emitting device has hitherto been unreported. When ZnS has been used as the emitter, solution-processed layers have been prepared by spin-coating, and never by inkjet printing. Furthermore, the utilization of the low-temperature-processed PEDOT:PSS/nanotube composite for both electrodes has not yet been reported. Device performance was compromised compared to conventionally prepared devices. This was partially due to the relatively high roughness of the printed films. It was also caused by energy level misalignment due to quantization (bandgap widening) of the small (<10 nm) nanoparticles, and the use of high work function cathode materials (Al and PEDOT:PSS). Regardless of their reduced performance, inkjet printing as a deposition technique for these devices presents unique advantages, the most notable of which are rapidity of fabrication and patterning, substrate flexibility, avoidance of material wastage by using drop-on-demand technology, and the need for only one main unit operation to produce an entire device.

inkjet printing

printed electronics

nanomaterials

pulp & paper

0542

Effects of Curing Agents and Drilling Methods on CAF Formation in Halogen-Free Laminates

Chan, Lok Si

January 2012

Increasing demands for more reliability and functionalities in electronic devices have pushed the electronics industry to adopt newly developed materials and reduce interconnect sizes and spacing. These adaptations have led to concerns of reliability failures caused by conductive anodic filament formation (CAF). CAF is a conductive copper-containing salt that forms via an electrochemical process. It is initiated at the anode and grows along the epoxy/glass interface to the cathode, and once CAF reaches the cathode a short circuit will occur. The objective of this research is to evaluate and compare the effects of curing agents (DICY vs. phenolic-cured epoxy) and drilling methods (laser vs. mechanical drilling) on CAF formation using an insulation resistance test at 85 ºC, relative humidity of 85%, and a voltage gradient of 0.4V/µm. Time-to-failure for DICY-cured and phenolic-cured epoxy with laser drilled microvias and mechanically drilled vias were determined using the insulation resistance test. The failed coupons were cross-sectioned and examined using a Scanning Electron Microscope equipped with Energy-dispersive X-ray spectroscopy to verify the existence of CAF. Weibull analysis was used to compare the reliability and identify the failure modes of the failed coupons. Test results show that DICY-cured epoxy is a better CAF resistant material than phenolic-cured epoxy. It is believed that the brittleness of phenolic-cured material might enhance the damage to the epoxy/glass fiber interface during drilling; and hence, facilitate subsequent CAF formation. The study also shows that laser drilled microvias are less prone to CAF formation than mechanically drilled vias, because there is less mechanical damage and lower glass fiber content. Finally, using Weibull analysis, it is determined that laser drilled microvias experienced infant-mortality failure, whereas mechanically drilled vias exhibited a wear-out type failure.

laminates

printed circuit boards

curing agents

drilling methods

Mechanical Engineering

De kan, de vill och de orkar, men... : Studier av närstående till personer drabbade av stroke samt granskning av informationsmaterial från svenska strokeenheter / They can, they want to and they have the strength, but... : A Study of Relatives of Persons Affected by Stroke and an Exploration of Printed Education Materials from Swedish Stroke Units

Wallengren Gustafsson, Catarina

January 2009

Aim: The overall purpose of this thesis was to increase the understanding of relatives’ changing life situation during the first six months of a person’s onset of stroke, with focus on learning. Furthermore, the purpose was to evaluate theprinted education materials (PEM) targeted at relatives at Swedish stroke units. Method: In paper I, 16 relatives were interviewed about the meaning of becoming a relative of a person affected by stroke. In paper II, 9 relatives were reinterviewed about what it meant to be a relative of a person affected by stroke. The interviews took place six months after the stroke survivors’ onset of stroke. Data from the two studies were analyzed by Lindseth and Norberg’s hermeneutic phenomenological method of analysis, inspired by Ricoeur. In paper III, 16 and 9 relatives were interviewed about what they wanted to know and understand during the first six months after the onset of the survivors’ strokes. Krippendorff’s method of qualitative content analysis was used to analyse data. In paper IV, 42 PEM:s from 21 Swedish stroke units were examined. Data were analysed by use of descriptive statistics and Krippendorff’s method of qualitative content analysis. Results: Becoming the relative of a person affected by stroke means to experience chaos but also to reach a turning point. The turning point is the start of a febrile activity that shows the relatives’ willingness to seek order in the chaotic situation (I). Being the relative of a person affected by stroke also means to be in a struggle for freedom. Relatives do not want to adapt to the stroke or its consequences. Instead, they prefer to choose their own way of life and to write their own history. Therefore, they strive to integrate the stroke and its consequences to their everyday lives (II). The information that the relatives wished to have was about the stroke survivor, the professionals and themselves. Moreover, the results showed that the relatives’ information quest was related to personal involvement, contextual factors, different knowledge needs and different ways to obtain information (III). The PEM:s, offered at Swedish stroke units, were adequate in terms of quality of suitability and readability. The content of the printed education materials offered to relatives varies with the stroke units. Conclusion: To become a relative of a person affected by stroke means to end up in chaos, but also to reach a turning point (I). At this turning point the person is prepared to adjust arrange his/her life to the new conditions. Therefore, nurses need to learn to identify these turning points and include support for relatives in their changing life situation. Being a relative during the first six months of a survivor’s onset of stroke means to fight for freedom (II) without abandoning the stroke survivor. In this process, it is important that the relatives learn to balance freedom with responsibility and life and care for the survivor with relations to other relatives. Relatives are capable as they are active, committed and social persons (I, II, III). This is why alternative pedagogic methods and approached need to be developed and tested. Nurses need training in using such alternative methods. The content of the printed education materials offered to relatives at Swedish stroke units varies with the unit. As a result, it would be useful to establish a national electronic centre.

Relatives

stroke

stroke units

printed education materials

learning

Nursing

Omvårdnad

An investigation into the effect of the PCB motion on the dynamic response of MEMS devices under mechanical shock loads

Alsaleem, Fadi M.

January 2007

Thesis (M.S.M.E.)--State University of New York at Binghamton, Watson School of Engineering and Applied Science, 2007. / Includes bibliographical references.

A design quality and cost model for printed circuit board assembly /

Shina, Sammy G.

January 1998

Thesis (Ph.D.)--Tufts University, 1998. / Adviser: Anil Saigal. Submitted to the Dept. of Mechanical Engineering. Includes bibliographical references. Access restricted to members of the Tufts University community. Also available via the World Wide Web;

Solder paste inspection based on phase shift profilometry

Hui, Tak-wai.

January 2007

Thesis (M. Phil.)--University of Hong Kong, 2008. / Also available in print.