Applications of PMC
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Applications of PMC







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Applications of PMC. PMC for electronics. Alternative names are printed wiring board ( PWB )
Applications of PMC

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Slide 1

Applications of PMC

Slide 2

PMC for electronics

  • Alternative names are printed wiring board (PWB)

  • Printed circuit boards, or PCBs, are used to mechanically support and electrically connect electronic components using conductive pathways, or traces, etched from copper sheets laminated onto a non-conductive substrate

  • Most PCBs are composed of between one and twenty-four conductive layers separated and supported by layers of insulating material

Slide 3

Printed Circuit Board (PCB)

Slide 4

Core

Printed Circuit Board (PCB)

  • Layers may be connected together through drilled holes called vias

  • Some PCBs have trace layers inside the PCB and are called multi-layer PCBs

Via

SR (Solder Resist)

PTH

(Plated

Through

Hole) with

plugging

material

Slide 5

PCB- Core

  • Made of woven textile-E glass reinforcement reinforced epoxy; designated as FR-4

  • Why continuous fiber used as core in PCB?

Slide 6

PCB-Solder Resist

  • Areas that should not be soldered to may be covered with a polymer solder resist (solder mask) coating

  • The solder resist prevents solder from bridging between conductors and thereby creating short circuits.

  • Solder resist also provides some protection from the environment.

Slide 7

PCB-Holes

  • The walls of the holes, for boards with 2 or more layers, are plated with copper to form plated-through holes

  • Function; electrically connect the conducting layers of the PCB

Slide 8

Electrical Conductive Adhesives

  • Alternatives to solder interconnection.

Slide 9

Metal filled polymer composites

  • Metal fillers act as conductive path to conduct heat and electric in the composites

Thermal Conductivity

Silver (Ag)

Copper (Cu)

Aluminium (Al)

Gold (Au)

Nikel (Ni)

Electrical Conductivity

Silver (Ag)

Copper (Cu)

Gold (Au)

Aluminium (Al)

Nikel (Ni)

Slide 10

Typical dependence of electrical conductivity (logarithm) on conductive filler volume fraction

Sharp conductivity increase

occurs within the concentration

region φc1<φ<φc2 . This

phenomenon is called

percolation threshold

Insufficient physical contact of metal fillers

Slide 11

The percolation behavior is primarily affected by;

  • particle size (nano & micron size)

  • shape of the filler (flake, spherical, etc)

  • filler particle distribution (segregated or random)

  • Filler concentration

  • Oxide layer thickness

Slide 12

Example; Polyimide Electrically Conductive Die Attach Adhesive

  • silver filled, electrically conductive polyimide adhesive

  • This product is designed for die attachment and surface mount applications. Other applications include, but are not limited to assembling electrical and electronic components.

  • The cure schedule allows for rapid processing and the resulting bond exhibits excellent thermal stability and adhesion at high temperatures.

  • APPLICATIONS:• Die attachment• Printed circuit board fabrication• Sealing and high performance coatings• Advanced material composites

Slide 13

PMC for automotives

  • Composites are being used more and more in the automotive industry

  • Due to their strength, weight, quality and cost advantages

  • Many automotive components are already produced in natural composites, mainly based on polyester or PP and fibres like flax, hemp or sisal.

  • The adoption of natural fibre composites in this industry is lead by motives of a) price b) weight reduction and c) marketing ('processing renewable resources') rather than technical demands

Slide 14

The use of natural fibres in automotive industries has grown rapidly over the last 5 years, see Table 2:

  • Table 2: The use of natural fibres in automotive industries

Interior part pf Mercedes A-200 made

By natural mat thermoplastic

In 1999, natural fibres used in the automotive industries comprised 75 percent flax,

10 percent jute, 8 percent hemp, 5 percent kenaf and 2½ percent sisal.

Slide 15

Table 1: Properties of glass and natural fibres

* tensile strength strongly depends on type of fibre, being a bundle or a single filament

Slide 16

Natural Fibers

  • Bast fibres (flax, hemp, jute, kenaf, ramie (china grass)) - the bast consists of a wood core surrounded by a stem. Within the stem there are a number of fibre bundles, each containing individual fibre cells or filaments. The filaments are made of cellulose and hemicellulose, bonded together by a matrix, which can be lignin or pectin

Slide 17

Natural Fibers

  • Leaf fibres (sisal, abaca (banana), palm) - In general the leaf fibres are coarser than the bast fibres. Applications are ropes, and coarse textiles. Within the total production of leaf fibres, sisal is the most important.

Slide 18

Natural Fibers

  • Seed fibres (cotton, coir, kapok)

  • Cotton is the most common seed fibre and is used for textile all over the world. Other seed fibres are applied in less demanding applications such as stuffing of upholstery. Coir is an exception to this. Coir is the fibre of the coconut husk, it is a thick and coarse but durable fibre. Applications are ropes, matting and brushes.

Slide 19

BONE CEMENT

  • Acrylic cement is used for the fixation of total joint prosthesis

  • The cements used in orthopedic surgery are combination of prepolymerized PMMA solid particle and the liquid monomer

  • The powder particles are sphere (30 to 150 µm in diameter), molecular weight of 20,000 to 2 million

  • For the reaction to occur,prepolymerized PMMA needs to contain an initiator, dibenzoyl perioxide (BP)

Slide 20

BONE CEMENT

  • Bone cement, or poly(methyl methacrylate) (PMMA), is commonly used to anchor hip prostheses in the femur.

  • The material is very brittle, however, and prone to fracture, fatigue and wear.

Slide 21

PMC for Medical Applications

  • Currently PMMA is the polymer most commonly used as a bone cement for the fixation of total hip prostheses.

  • Ideally, a bone cement material should be easy to handle, biologically compatible, nonsupporting of oral microbial growth, available in the particulate and molded forms, easy to obtain, nonallergenic, adaptable to a broad range of dental and medical applications, in possession of high compressive strength, and effective in guided tissue regenerative procedures.

Slide 22

Problems of PMMA Bone Cement

  • Strong exothermic setting reaction

  • Toxic effect of the monomer

  • Inability to bond directly to bone - caused loosening at the interface

  • Brittle nature

    - To overcome these problems, many types of bioactive bone cements have been developed.

Slide 23

  • To improve the biochemical properties of PMMA bone cement, many types of bioactive particle fillers have been added into the cement

  • Example of particle fillers are glass ceramic, titania (anatase & rutile), etc

Slide 24

Recent studies on Bone Cement + titania particles (K. Goto et al., Biomaterials 26 (2005))

Figure (c)

Shows direct

Contact

Between bone (B)

And Cement (C),

while Figure (b)

Shows soft

Tissue layer

Less than

10 um. The soft

Tissue layer

In (a) and (d)

Is thicker

Than (b) and (c)


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