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Friday, June 27, 2014


Squeegees with either rubber or plastic blades are useful for scraping off excess resin from reinforcing cloth and woven roving 'When doing laminating or lay-up work. This is important for. Keeping the reinforcing-material-to-'resin ratio high for greater strength in the cured laminate. Squeegees can also be used for spreading resin quickly and removing air bubbles.

The blades on some squeegees are stiff. Others have some flexibility such as those used for cleaning window glass). It will take some experimenting with both types to determine which you prefer for fiberglassing work. Squeegees are available in various widths or in strips that you can cut to desired lengths. Those with blades from about 3 to 6 inches wide are about right for most fiberglassing repair work. Some squeegees are gripped by the side of the blade, others have handle. The choice is largely a matter of individual preference. Those with handle can be used to get at hard to reach areas.
Plastic Squeegees

Monday, June 23, 2014

Glass Fiber-Reinforced Polymer (GFRP) Composites

Fiberglass is simply a composite consisting of glass fibers, either continuous or discontinuous, contained within a polymer matrix; this type of composite is produced in the largest quantities. The composition of the glass that is most commonly drawn into fibers (sometimes referred to as E-glass) . fiber diameters normally range between 3 and 20 _m. Glass is popular as a fiber reinforcement material for several reasons:

1. It is easily drawn into high-strength fibers from the molten state.
2. It is readily available and may be fabricated into a glass-reinforced plastic economically using a wide variety of composite-manufacturing techniques.
3. As a fiber, it is relatively strong, and when embedded in a plastic matrix, it produces a composite having a very high specific strength.
4. When coupled with the various plastics, it possesses a chemical inertness that renders the composite useful in a variety of corrosive environments.

The surface characteristics of glass fibers are extremely important because even minute surface flaws can deleteriously affect the tensile properties. Surface flaws are easily introduced by rubbing or abrading the surface with another hard material. Also, glass surfaces that have been exposed to the normal atmosphere for even short time periods generally have a weakened surface layer that interferes with bonding to the matrix. Newly drawn fibers are normally coated during drawing with a ‘‘size,’’ a thin layer of a substance that protects the fiber surface from damage and undesirable environmental interactions. This size is ordinarily removed prior to composite fabrication and replaced with a ‘‘coupling agent’’ or finish that promotes a better bond between the fiber and matrix.

There are several limitations to this group of materials. In spite of having high strengths, they are not very stiff and do not display the rigidity that is necessary for some applications (e.g., as structural members for airplanes and bridges).

Most fiberglass materials are limited to service temperatures below 200C (400F); at higher temperatures, most polymers begin to flow or to deteriorate. Service temperatures may be extended to approximately 300C (575F) by using high-purity fused silica for the fibers and high-temperature polymers such as the polyimide resins. Many fiberglass applications are familiar: automotive and marine bodies, plastic pipes, storage containers, and industrial floorings. The transportation industries are utilizing increasing amounts of glass fiber-reinforced plastics in an effort to decrease