Additives of Polycarbonate (PC)

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Additives of PC:

1. Functional Additives

2. Fillers

3. Reinforcements

Functional Additives:

1. UV absorbers are the only effective UV stabilizers

2. Colorants

3. Blowing Agents

Fillers:

1. Graphite, MoS2 and PTFE are successfully used in PC to minimize abrasion and wear  moldings.

2. Aluminum powder is used to increase the thermal and electrical conductivity.This provides protection against electromagnetic interference (EMI) in, for examples, data processing installations.

Reinforcements:

1. The preferred reinforcement for PC as for many other plastics, glass fiber. 

2. PC occupies third place amongst GF reinforced thermoplastics PA and PP.

3. The glass content varies between 10 and 40%. Chopped strand alkali-free E-glass surface-treated with silanes to promote adhesion is the main reinforcement.

4. A PC reinforced with 30% w/w glass fiber can compete in mechanical terms with non-ferrous metals or thermosets. 

5. Wollastonite is used very occasionally to improve the stiffness of moldings.

Grades of PC:

PC is available in the following grades.

1. Injection grades 

2. Extrusion grades

3. Blow grades

4. Thermoforming grades

In addition to that they are available in the following special grades,

1. Transparent grades

2. Tinted grades

3. Unmodified grades 

4. Flame retardant grades

Processing considerations of PC:

1. Drying in hopper dryer or in trays in an over for four hours at 120°C - 140°C will reduce the moisture level in the PC below 0.02%. 

2. The apparent melt viscosity is also less dependent on the rate of shear than usual with thermoplastics. Because of high melt viscosities flow path ratio are in the range of 30:1 to 70:1 which is substantially less than for many more general purpose thermoplastics. 

3. Processing temperatures are high at which thermal degradation occurs quite rapidly. Normally it is in the range of 280°C - 320°C 

4. Polycarbonate adhere strongly to metal and if allowed to cool in an injection cylinder or extrusion barrel may on shrinkage, pull pieces of metal from the wall. It is therefore necessary to purge all equipment free of the resin with a polymer such as PE, after processing.

Processing techniques:

1. Injection Moulding 

2. Extrusion 

3. Blow molding 

4. Thermoforming 

Casting process is also used for making films. Like metals, polycarbonate can be cold formed by punching and cold rolling. 

Surface Finishing of PC:

1. PC can be easily polished to a high gloss. Only alkali-free polishing pastes should be used so as not to damage the surface.

2. Suitable products are available for printing    ,coating, hot embossing etc. 

3. PC moldings can also be vacuum metallized.

Machineability of PC:

Machining can be possible in PC with much precaution because it has stress-cracking tendency.

Weldings:

1. Moldings and semi-finished products can be joined by vibration, friction, heated tool and hot gas welding in recent years, welding and riveting with ultrasonics have been preferred. 

2. Heated tool welding is preferable to heated gas welding. 

3. The tool temperature is 400 C while air temperatures of 450 to 500 C are required for hot gas welding.

Bonding:

1. Suitable adhesives are solvents such as methylene chloride which dissolve the surfaces of the parts to be joined.

2. Two pack adhesives based on epoxide and silicone resins and polyurethane adhesives are suitable for joining PC to PC and other materials. 

3. The adhesives must be free of component which are incompatible with PC.

Applications of PC:

1. Appliances

2. Automotive

3. Electrical & Electronics 

4. Food contact articles 

5. Medical

6. Optical

7. Miscellaneous 

Applications of PC in appliances:

Coffee filters, shaver housings, chocolate moulds, blenders, tablewares, kitchen mixer bowls, grinder bowls, housing for ball point and fountain pens, rim heater grills, motor bracket and housing, camera, binocular casings, housings for hair dryers and coffee makers, water tank for steam iron, films for labels and memory switches, fruits juicer parts, high impact vacuum sweeper housing, mixers and power tools, bobbins for textile industries, baby feeding bottles and cutlery

Applications of PC in Automotive:

Wind screen wiper brackets, car interior moulded trims, instruments glazing, indicator lamps, wind shields for two wheelers, door handles, tail and side marker lights, PC blends in instruments, panels as well as bumpers, wheel cover and body panels protective hoods, fan wheels, components for sewing machines, chaises, levers, valves, control cams, directional signs, heating grill, ventilators and radiator grills, overrides, fuse box & covers and housing for automobile & aerial motors.

Applications of PC in Electrical & Electronics:

Wiring devices, insulators panels, plugs and socket terminal blocks, coil formers, Slater enclosures, housing and cover for distributor boxes. Panel light covers, battery boxes fuses, electric meter covers, connectors, breaker boxes, gears, printers housings, slide window,, telephone housing for mining operations, telephone dails, coil formers and housings, winding supports, switch plates, fuse boxes, housing for computers, calculation machine and magnetic disk packs.

Applications of PC in Food Control articles:

Mineral water bottles, microwave oven wares, beermugs table wares and food storage containers.

Applications of PC in Medical:

Blood bottles, dispensers for inhalers, sterilisable lab-wares, tissue culture dishes, posts for IV fluids, sterilizable container and packaging materials, surgical lighting, disposable, diagnostic cardio-vascular and intravenous devices, drug delivery systems and housings for blood cleaning filters.

Applications of PC in Optical:

Diffusers, lenses for lighting, vacuum metallised reflectors, housing for steel lamps and traffic signals, lamp holders, bulk heads, light fixture, lenses and safety glasses, window panels ( for out door lighting) sunglasses, ski goggles and face protective wires, audio compact discs, film and slide cassettes

Miscellaneous  Applications of PC:

Sporting goods, stencils, ink ducts, slide rules components and rulers.

Blends of PC:

PC-ABS 

- Alloys of a Bisphenol A  poly carbonates with ABS and MBS resins  have been known for many years. 

- These alloys retain their impact strength down to -50 C .They are non-splintering .

- The hardness of the alloys is comparable  to that of PC. 

- Because of the above properties, ability to mould to close dimensional tolerances , low warpage , low shrinkage, surface finish, PC ABS alloys are  widely used  in automotive industry for electrical application and for housings of domestics and business equipments.

PC-PBT

This is particularly notable for its high levels of  toughens and resistance to petrols and oils. 

PC-PET

This is recently introduced for incorporating advantages of both resin in the alloys.

Polychlorotrifluoroethylene (PCTFE)

Polychlorotrifluoroethylene (PCTFE):

The main characteristics are:

- hard, stiff, unbreakable,

- transparent to opaque,

- no smell or taste,

- weather resistant,

- non-toxic thermoplastic even thin films are pore-free, 

- bondable and weldable, easily machined.

Structure and Properties:

1. The main difference in the property profiles of PTFE and PCTFE reflects their chemical structures. 

2. The chlorine atom is significantly larger than the fluorine atom. 

3. The absolutely symmetrical structure of the PTFE back bone is thus disturbed and the chain separation is enlarged. 

4. Although the chain segments can still crystallize, this is much impeded and is thus less than PTFE. 

5. Although the chain mobility is slightly increased, the polarity of the chlorine atom results in larger intermolecular forces and thus a stronger and stiffer polymer. 

6. The polarity affects primarily the electrical properties of the polymer and limits its use to the high frequency range.

Availability:

1. PCTFE is thermoplastic and is supplied as granules primarily as a homopolymer for injection molding and extrusion. 

2. Copolymers with vinylidene fluoride and other monomers are also available. 

3. Powder grades are supplied for the manufacture of dispersions. Profiles, tubes, rods, blocks and films are available.

Thermal Properties:

1. The upper service temperature of 150°C is set not only by decreasing mechanical strength but also by embrittlement on long exposure to heat. 

2. The polymer melts at 216°C and glass transition temperature is 45 °C.

Electrical Properties:

1. PCTFE's insulating properties are very good because it does not absorb water because of its thermoplastic character, even thin films are free from pores. 

2. The dielectric properties are impaired by the dipole moment arising from the chlorine atoms. Other electrical properties are comparable with those of the perfluorinated polymers.

Optical Properties:

The refractive index n20D is 1.425. Rapid quenching of films and thin-walled moldings leads to crystal-clear transparency.

Permeability to Water Vapor & Gases:

PCTFE exhibits good barrier properties to gasses. PCTFE has the lowest permeability to water vapor of all transparent plastics films. 

Chemical Properties 

Resistance to Chemicals

1. Resistant to acids, alkaline solutions, many solvents at room temperature, aromatic or chlorinated hydrocarbons/esters and ketones cause reversible swelling of PCTFE at elevated temperatures. 

2. It is not resistant to chlorosulfonic acid or molten alkali metals. 

Weathering Resistance

PCTFE is weather resistant

Resistance to High Energy Radiation

Even small dosages of high energy radiation damage PCTFE similarly to PTFE. Because of the separation of chlorine, long exposure of PCTFE to radiation may result in corrosion of neighboring metal components.

Processing:

1. Preferred processing methods are compression molding, extrusion and injection molding. 

2. Metallic substrates can be coated with the help of dispersions.

3. Injection molding melt temperature: 70 to 280°C 

4. Mold temperature: 89 to 130°C. Shrinkage 1 to 2%  

5. Extrusion melt temperature 290 to 300°C also for cable sheathing

6. Compression molding melt temperature 270 to 280°C

7. Copper cable must be nickel or silver plated prior to sheathing because copper- and iron­ containing alloys catalyze degradation of PCTFE. High frequency and ultrasonic welding are suitable, bonding requires pretreatment. Films can be laminated, thermoformed, hot ­sealed, printed and vacuum metallized.

Typical Applications

1. Crucibles, fittings, tubes, inspection ports, membranes, cable insulation, printed circuits, spool cores, insulating films and pharmaceutical packaging. 

2. High frequency applications are limited.

Trade Names

Neoflon (Daikin America Inc., lP) Kel-F (3M Co., US) 

Processing of Natural Rubber Compounding

Processing of Natural Rubber Compounding:

The manufacture of rubber products from dry natural rubber can be divided into four stages: 

1. Mastication

2. Incorporation 

3. Shaping

4. Vulcanization

The rubber must be masticated to bring it to a suitable consistency (viscosity) to accept the compounding ingredients. These ingredients are incorporated into the masticated rubber, after which the rubber is shaped and vulcanized. The shaping and vulcanization stages may be combined as in transfer or injection molding or separated as in the extrusion and subsequent vulcanization of a tube.

Mastication: Unless the producer has modified NR to a specific processing viscosity, it is very tough, and therefore, requires mastication prior to compounding. 

1. During mastication, the NR molecules are mechanically broken down by means of high shear forces. The mastication can be carried out on mills at low temperatures, or at elevated temperatures in the presence of peptising.

2. High degrees of mastication are only required, if the NR is to be used in very soft compounds, or if the compound is to be dissolved in solvents (sponge, frictioning, rubber solutions). 

3. Low degrees of mastication make it already possible to incorporate chemicals and fillers readily in NR.

Mixing on Mills:

1. The rubber is first worked on the mill until a coherent band is formed on the mill rolls. 

2. On adding softeners, the band will generally split, and it has to heal before additional fillers are added to the compound. Finally, the sulphur is mixed in, if no ultra fast accelerators are present. 

3. The sul­phur is added on the warm up mill before processing. During the mixing process, the band must not be cut, and only after all ingredients have been incorporated in the compound, the band is cut and folded, that is, the compound is homogenized. 

4. When the mixing cycle is completed, the compound is cut from the mill as slabs, and cooled in a water bath and stored, or it is cut into slabs on batch-off equipment.

Mixing in Internal Mixers

1. When mixing is carried out in internal mixers a relatively hard and nervy rubber is required for good and efficient dispersion of compounding ingredients. 

2. The usual mixing temperatures are about 140 to 150°C, and through intensive cooling, this temperature can be reduced to 120 to 130°C for heat-sensitive compounds. 

3. If no means of cooling is available, the mixing tempera­ture can go as high as 180 to 190°C. 

4. Mixing at such high temperatures, also referred to as "hot mixing", has been popular for some time now, since it allows very short mixing cycles. 

5. However, the properties of the compounds and of the vulcanizates are considerably changed in this mixing process. 

Cooling Mills

1. After mixing, the compound is dumped from the internal mixer onto a cooling mill, which could also be equipped with blending bars. 

2. It is then cut into slabs or festooned in batch-off equipment for it to cool down. 

3. In some large-scale operations, the mixed compound is also palletized, cooled, and then stored sulphur.

Vulcanization:

1. NR compounds can be vulcanized in all commonly used processes - hot air, with or without pressure, steam, hot water, press, transfer moulding, injection moulding, roto cure, molten salt bath, hot air tunnel, high frequency radiation, lead cure, etc.

2. Because of the non-polar character of NR, there may be problems with preheating light-colored NR compounds by high frequency radiation 

3. Therefore, one should either add carbon black, or polar compounds, like triethanol amine, polar factices etc. to the compound. 

4. The higher the cure temperatures, the poorer are the mechanical properties of the vul­canizates, and the shorter is the plateaus.

Sulfur Vulcanization

1. Natural rubber can be compounded without fillers to give a vulcanizate with high elongation (600-800%) and high tensile strength (21-28 MPa or 3000-4000 psi). 

Reinforcing fillers such as carbon black, precipitated silicas, and hard days are used to adjust the hardness. 

2. Whiting (calcium carbonate) is the most common nonreinforcing filler. High loadings can be used to dilute the rubber with the minimum loss of softness, elongation, and resilience. 

3. Most natural rubber vulcanizates are cross-linked with sulphur.

Efficient Vulcanizations (EV)

1. EV systems are characterized by low sulfur content combined with a high accelerator concentration. 

2. A sulfur-donating accelerator may be used to further reduce the elemental sulfur content. 

3. Typically, an EV system contains 0.3-1.0 effective parts of sulfur and 2.0-5.0 parts of accel­erator. T

4. The semi-EV system is a compromise between the conventional and EV with sulfur at 1.0-1.8 parts and the accelerators at 1.0-2.5 parts. 

5. The EV systems produce vulcanizates with a higher concentration of monosulfide cross-links that are more thermally stable and more easily protected against oxidation.

Sulfur and Accelerators:

1. Although Natural Rubber (NR) can also be crosslinked with peroxides, or high energy radiation, in practice, sulfur and accelerators are predominantly used. 

2. For lower sulfur concentrations, larger amounts of accelerator are required, in order to keep up the level of cross-link density. 

3. Low sulphur vulcanization systems play an increasingly important role in addition to the conventional cures with about 1.5 to 2.0 phr sulfur. 

4. For optimum levels of mechanical and dynamic properties of vulcanizates with a good heat resistance, low sulfur 0.5-1.5 phr) or so-called "semi-efficient"' (Semi-EV) vulcanizations are used. "Effi­cient" vulcanizations (EV).

Metal Oxides:

Metal oxides are required in a compound to develop the full potential of accelerators. 

1. The main metal oxide is zinc oxide, but other oxides are used at times to achieve specific results, namely magnesium oxide in the presence of acidic compounding ingredients such as factice, based on sulphur monochloride, or lead oxide, to obtain an especially low water absorption of vulcanizates. 

Activators:

1. Many accelerator systems require additional activators, like fatty acids, or salts of fatty acids, namely stearic acid, zinc soaps, or amine stearate. Glycoles or trpthanol amine also serve as activators, the latter primarily in compounds with reinforcing silica fillers. Fatty acids have a lower activity in low Nitrogen NR Grades.

Vulcanization Inhibitors:

1. These are used to prevent premature vulcanization or scorching. 

2. In many instances, a sufficient scorch life is obtained by using either an­ appropriate combination of accelerators, or acidic compounding ingredients. 

3. When these measures still do not give sufficient scorch protection, special inhibitors are used, primarily those based on phthalimide sulfenamides. 

4. They not only delay the onset of cure, but also the time to completion of cure. 

Protective Agents

1. Because it is highly unsaturated, NR has to be compounded with protective agents to achieve a sufficient aging resistance.

2. The level of protection is determined by the chemical nature of the protective agent. 

3. Most effective are aromatic amines, such as p-phenylene diamine derivatives, which not only protect the vulcanizate against oxidative degradation, but also against dynamic fatigue and degradation from ozone and heat. 

4. It is remarkable that some agents such as PAN or PBN impart a good fatigue/resistance to NR, but none or very little to SBR vulcanizates. 

5. Since the most effective protective agents more or less discolor the vulcanizate, less effective ones, like bisphenols, phenols, polymeric hindered phenols have to be used in light-colored vulcanizates.

Fillers:

1. The active fill­ers do not give quite the same amount of reinforcement as in most SRs, but the effi­ciency of the fillers ranks in the same order in both cases. 

2. Reinforcing fillers enhance the already high tensile properties of gum NR, and they improve, in parti­cular, the abrasion and tear resistance. 

3. Less reinforcing fillers, such as N 770 (SRF) or N 990 (MT), and light inactive fillers, such as kaolin, calcium carbonate, barium sulphate, zinc oxide, or magnesium carbonate are used for a number of reasons. These include an improvement of processibility, and the attainment of particular specifications, such as density, colour, or even price. 

4. Depending on their activity, the fillers determine, more or less, the hardness, and they also reduce the rebound elasticity of NR vulcanizates. 

5. With inactive fillers, and especially with zinc oxide and N 990 black, one can formulate filled vulcanizates, which have almost the same elasticity as unfilled gum vulcanizates. 

6. NR compounds require and therefore con­tain considerably less filler than SR compounds. For instance, with highly active fillers, one generally uses up to about 50 phr, and somewhat higher concentrations with non-active fillers.

Oxidation:

1. The oxidation of a natural rubber compound is a complex process involving many reactions, which are influenced, by processing conditions, metal catalysts, temperature, and formulation. 

2. Oxidation proceeds through chain scission of the polymer backbone. 

3. The hydrogens and double bonds are the primary points for attack. Oxidized natural rubber vulcanizates exhibit inferior physical properties including hardness and, at some point, surface hardness. 

Ozone Attack:

1. In the presence of ozone, the surface of natural rubber vulcanizates develops cracks. 

2. The ozone reacts with the olefinic double bond to yield a 1,2,3-trioxlane, which decomposes to a zwitterion plus an aldehyde, cleaving the double bond. 

3. The zwitterion and aldehyde may recombine to the ozonide or the zwitterion can react with another zwitterion to yield a cyclic diperoxide or a polyperoxide. 

4. Ozone attack on natural rubber can be prevented through the use of wax and chemical antiozonants. 

Softeners and Resins:

1. A great number of different materials serve as softeners, the most important ones being mineral oils. 

2. These oils include a wide range of products, from paraffin to aromatic. Animal and vegetable oils are also important softeners or process aids, to include wool grease, fish oil, pine tar, and soya oil. 

3. NR requires lesser amounts of softener than most SR's. Synthetic softeners, which are commonly used with CR (Chloroprene Rubber) or NBR (Nitrile Rubber), play only a minor role in NR compounding. 

4. When selecting softeners for NR, the potential of blooming or migration has to be considered

Resins:

1. While it is important to add resins to compounds from most SRs, so that they can be fabricated, this is not generally necessary with NR compounds. 

2. If an exceptionally good building tack is required, such as compounds for frictioning of textiles, it is advantageous to add rosin, tar, pitch, or other tackifiers to NR com­pounds. 

3. Those tackifiers, which were specially developed for SRs, are of little rele­vance in compounding of NR. 

Applications:

1. Radial tires use a higher proportion of natural rubber because its high green strength, tack, and cohesive properties help maintain the uniformity of the green tire during construction. The low heat build-up of natural rubber is more important in a radial tire where the sidewall requires more flexibility.

2. Tires of trucks and off the road and earthmoving equipment are frequently damaged and large chunks of rubber can be torn out of the tread. 

3. Aircraft tire treads are also commonly made of all natural rubber, as are automobile engine mountings and suspension systems.

4. Adhesives for surgical, masking, and duct tape as well as packaging adhesives are made from natural rubber.

5. Significance include rubber printing rolls, baby bottle nipples, rubber bands and thread, tank linings, and tennis balls, as well as a wide variety of molded and extruded specialties.

Formulations: 

a) Formulation for Tyres 

Formulations: 

b) Formulation for Conveyer belts 

Formulations: 

c) Formulation for rubber Hose 

Polysaccharides:

Polysaccharides are usually subdivided into fiber-forming linear structural polysaccharides (e.g., cellulose, chitin), moderately to strongly branched reserve polysaccharides (e.g., amylose, pectin), and physically cross-linked, gel­forming polysaccharides (e.g., gums, mucopolysaccharides) (G: sakcharon = sugar). Cellulose and starch are amongst the best known polysaccharides 

Celluloses:

Nature converts glucose into cellulosc (in plants) when thousands of glucose molecules are linked together through hydroxyl groups at C1 and C4 in a long chain forming a polyanhydride (giant cellulose molecule) and several water molecules (by a process similar to polycondensation). The following is the structure of the repeat unit in cellulose 

The reason for this is the stiffness of the chains and hydrogen bonding between two -OH groups on adjacent chains. It has the property of forming long threads and for this reason is largely incorporated as raw material in textile industries Cellulose is highly stereo specific macromolecule. 

The melting temperature of crystalline cellulose is far above its decomposition temperature. The fiber forming properties of cellulose can be accounted by its unique conformation.

Starch:

Starches are intimate mixtures of amylose and amylopectin. They are obtained from com, potatos.

1. Starch is a polymer with an a-glucose as the repeat unit and is a widely distributed polysaccharide. This dissimilarity in the structure of starch makes it available as a granular material, with no trace of organized crystalline structure.

2. Amyloses arc practically linear poly [(1-4)-anhydro-D-glucopyranose]s with molecular weights of up to ca. one million. The stable macroconformation of amy­lose is that of a helix. Amylopectins are branched poly [α-(1 -4)-anhydro-D-glucopyranose]s with Christmas tree-like structures. They possess 1 branching unit per 18-27 glucose units; the branching is via 1.6-positions. 

Glycogen: Glycogen is a polysaccharide, found in animals only. It is an important energy storing material in the body and is found mainly in muscle and liver. This is a glucose polymer similar to amylopectin, except that it is more highly branched.

Dextran: In dextrans, chain bonds are mainly in (l~6') positions and branches via ­(1 -4') bonds. Dextrans are obtained by enzymatic polymerization of saccharose. They serve as blood plasma expanders and as columns in chromatography.

Chitin: Chitin is the structural polysaccharide of arthropods (insects, crustacea) where it forms so called exoskeleton, playing a role analogous to the protein collagen in higher animals. It is always associated with calcium carbonate and/or proteins. 

Natural Polymer

Natural Polymer:

- Fibres commonly used in composites materials, carpet, ropes, coir and geo textile. 

- Natural fibres such as jute and coir have been computing the properties of cellulose fibres. 

- Cellulose fibres are obtained from different parts of vegetables plants for e.g. jute are obtained from the stem; sisal, banana and pineapple from leaf, cotton from seed, coir from fruit etc. 

Chemical Composition:

Namely Constitutes:

1. Cellulosee

2. Hemi-cellulose

3. Lignin 

Cellulose: Cellulose is a linear condensation polymer consisting of D-anhydroglucopyranose units joined together by -1, 4-glycosIdic bonds. The pyranose rings are in chair conformation. The crystallinity in natural fibres is mainly due to the crystalline cellulose; as cellulose molecule is stiff and straight because of its internal hydrogen bond and linkages. 

Hemicelluloses: hemicelluloses are subdivided into (l) cellulosans and (2) incrusting hemicelluloses. Cellulosans are regarded as integral and structural part of cellulosic aggregate and are oriented in the same way as true cellulose. 

1. The cellulose an associated with most cellulosic xylan. The incrusting hemicelluloses on the other hand are loosely bound, being readily removed from the fibre.

2. The predominant polysaccharide of Jute is however composed of a backbone of-D-­xylopyranose units with approximately every seventh unit carrying a terminal 4-O-methyl -D-glucuronic acid residues linked through position.

Lignin: Lignin is a group of high molar mass, amorphous compounds with high meth­oxyl contents that are present in wood and some other plants. 

The monomers of lignin are aromatic alcohols with phenyl propane backbone p-coumaryl alcohol, coniferyl alcohol and sinapyl alcohol. 

The high Tg and rigidity of lignin may be due to cross-linking and intermolecular interaction. Amorphous lignin structure, under some conditions may adopt a quasi-ordered arrangement. 

The hemicellulose is linked to lignin hydroxyl via its uronic groups in an ester linkage. It has been suggested that the hydroxyl group in the propyl side chain of phenyl propane unit of lignin may be involved in this linkage. 

Amongst the naturally occurring lignocellulosic fibres, jute contains one of the highest proportions of stiff natural cellulose.

Applications:

1. In the textile industry, the high stiffness of Jute is often a limitation because of difficulties in the fine spinning, thus leading to only harsh and coarse fabrics.

2. However, in fibrous composites, stiffness of fibre is an important basis of design criteria since structures are designed on the basis of minimum deflection under load. 

3. Coir is also a hard fibre of low density. The best application of such lightweight hard fibres can be in the area of composite materials 

Natural Resin: “Natural organic substances that are usually transparent or translucent and yellowish to brown, are formed especially in plant secretions”. 

1. They  are soluble in organic solvents but not in water, are electrical non­conductors, and are used chiefly in varnishes, printing inks, plastics, and sizes and in medicine. 

2. The resins arise from condensation of naturally occurring chemical compounds such as the terpenoids and flavonoids contained in trees

3. Being mixtures, the resins do not exhibit simple melting or boiling points, although they do exhibit a predominant glass-transition temperature (Tg).

4. The Tg of natural resins ranges from approximately 0 to about 100°C, which is high for low molecular weight condensation polymers. Chemical modification increases the molecular weight and broadens the range of Tg

Rosins: Rosins are known as gum, wood, or tall oil rosin, based on the method of isolation and the source. Rosin is isolated from pine trees, principally from longleaf Pinus palustris, Pinus ellioti.

Composition: Rosin is primarily a complex mixture of monocarboxylic acids of alkylated hydrophenanthrene nuclei.

1. The resin acids are subdivided into two types based on their skeletal structure. 

2. The abietic-type acids contain an isopropyl group pendent from carbon 13. 

3. The pimaric-type acids have a methyl and vinyl group pendent from the same carbon atom.

Applications

1. The carboxyl group reacts with metal oxides, hydroxides, or salts to form rosin soaps or salts. 

2. The soaps of alkali metals, such as sodium and potassium, are useful in paper sizing and as emulsifiers in rubber polymerization. 

3. The salts, primarily of calcium and zinc, are used in printing ink formulations. 

4. The carboxyl group is converted to the alcohol by catalytic hydrogenation. 

5. Specialty paper is treated with stabilized rosins to minimize yellowing during aging. Treatment are used in concentrations of 0.1-3.0%. 

6. Rosin acid esters find wide application in printing ink formulations.

7. The resins provide pigment wetting, resistance to penetration, adhesion to substrates, hardness, and gloss.

8. Rosin-derived resins dispersed in linseed oil are used as vehicles for letterpress inks, which dry to a polymeric film by oxidation.

9. Metal salts of rosins, modified rosins, and polymerized rosins are used inexpensive gravure inks. Rosin ester resins are used extensively in pressure-sensitive adhesives as tackifiers.

10. Rosin, modified rosins, and derivatives are also used in hot-melt adhesives. 

11. Rosin ester resins are used as modifiers in the formulation of chewing gum. 

12. The soap of modified rosin has a long history as an emulsifier for the polymerization of styrene-butadiene rubber.

Shellac: Unlike other natural resins, shellac does not originate from plants, but is produced from the secretion of an insect. It is a purified form of lac and is the most widely known as lac product. Lac is produced by the larvae of Kerria laeea (Laccifer lacca). 

Composition: Shellac is primarily a mixture of aliphatic poly hydroxy acids in the form of lactones and esters. 

It has an acid number of 70, a saponification number of 230, a hydroxyl number of 260, and an iodine number of 15. Its average molecular weight is about 1000.

Applications

1. Shellac still has significant sales to the protective coatings industry.

2. Unpigmented shellac is used on floors, woodwork, and panelling. 

3. White, pigmented shellac is used as a primer-sealer for interior applications.

4. Shellac is used as a protective coating for pharmaceuticals.

5. Candy is coated with shellac to seal in moisture and keep the product fresh. 

6. Shellac is used in electrical applications. Paper coated with it serves as cores for motor windings. Shellac is used as the binder for manufacturing electrical insulation board based on flaked mica.

Rubber:

Natural Rubber:

Natural rubber (NR) (cis-1,4-polyisoprene) occurs in over 200 species of plants. The Hevea brasiliensis tree accounts for over 99% of the world's natural rubber production

Latex Composition 

1. Freshly tapped Hevea latex has a pH of 6.5-7.0, a density of 0.98 g/cm3, and a surface free energy of 4.0-4.5 J/cm2 (0.96-1.1 cal/cm2). 

2. The total solids of fresh field latex vary typically from 30 to 40%, depending on the clone, weather, stimulation, tapping frequency, and other factors. 

3. The dry rubber content is 3 wt % less than the total solids.

4. The rubber phase typically contains 96 wt % rubber hydrocarbon, 1 wt % protein, and 3 wt % lipids along with trace amounts of magnesium, potassium, and copper 

Processing: 

1. Latex was collected from tapping cups 2-3 hrs after tapping and taken immediately to the laboratory without ammoniation. In order to minimize tree-to-tree variation, the latex from 8-15 trees was blended together.

2. It was shown also that rubber with a high initial viscosity hardened less on storage.

3. The molecular weight distribution as determined by Mw/Mn is extremely wide for natural rubber. Molecular weights range from 3 x 104 to an estimated upper limit of 107.

4. The high molecular weight fraction imparts strength and other important physical properties; the low molecular weight fraction contributes to processibility.

Types and Grades

The type of rubber is defined by the raw material and the method of production, whereas the grade refers to quality subdivisions within a type 

Visually Graded Rubber

Visual inspection is the oldest method of grading rubber; eight types are produced from the latex of the Hevea tree: 

1. Ribbed smoked sheets (RSS)

2. White and pale crepes 

3. Estate brown crepes

4. Compo crepes

5. Thin blanket crepes (remills) 

6. Thick blanket crepes (ambers) 

7. Flat bark crepes and 

8. Pure smoked blanket crepes. 

Technically Specified Rubber (TSR):

Technically specified rubber (TSR) was introduced by the Malaysians in 1965 under the Standard Malaysian Rubber (SMR) scheme.

Other natural rubber-  producing countries soon followed with their own version: - Indonesia (SIR), Singapore (SSR), and Thailand (TTR). The introduction of TSR brought innovations in processing, packaging, and quality control to the natural rubber industry. 

- All versions of TSR are analysed with the same set of tests to determine quality, but small differences exist in the specification limits and the permissible raw materials. 

- The standard test methods for determining SMR are recognized by all natural rubber producers and consumers, with minor differences.

Polyamideimide (PAI)

Polyamideimide (PAI): Polyamideimides were introduced in 1964 and the range includes molding compounds, electrical insulating and stoving lacquers, films and fibers..

The original manufacturer of molding compounds of interest to designers was Amoco (US).

Polyamide-imides are either thermosetting or thermoplastic, amorphous polymers that have exceptional mechanical, thermal and chemical resistant properties. Polyamide-imides are used extensively as wire coatings in making magnet wire. They are prepared from isocyanates and TMA (trimellic acid-anhydride) in N-methyl-2-pyrrolidone (NMP). A prominent distributor of polyamide-imides is Solvay Specialty Polymers, which uses the trademark Torlon.

Polyamide-imides display a combination of properties from both polyamides and polyimides, such as high strength, melt processibility, exceptional high heat capability, and broad chemical resistance. Polyamide-imide polymers can be processed into a wide variety of forms, from injection or compression molded parts and ingots, to coatings, films, fibers and adhesives. Generally these articles reach their maximum properties with a subsequent thermal cure process.

Other high-performance polymers in this same realm are polyetheretherketones and polyimides.

Manufacture: 

1. This product group consists of polyimides formed by polycondensation of imide chains with aromatic diamines. 

2. Torlon is manufactured by phosgenation of trimellitic anhydride and reaction of the acid chloride with 4,4'-diaminophenyl methane in N-methyl pyrrolidone at room temperature. 

3. The resultant polyamide acid is cyclized to polyamideimide.

General Description:

1. Normal molecular weight PAI cannot be melt processed by injection molding/extrusion because of very high viscosity

2. To enable these processes to be used, the material is supplied with reduced molecular weight. 

3. The melt viscosity of PAI as supplied is so low that thin walled injection moldings are possible. 

4. Because the moldings are still thermoplastic after injection molding, i.e. prior to post­ treatment, scrap such as sprues, rejects, etc. can be recycled. 

5. PAI melts polymerize further above 246 °C. 

6. Since these molding compounds are processed at about 350 °C, post-polymerization occurs.

7. Although process ability is not generally affected adversely, the already starting polymerization limits the residence time of the melt in the plasticizing cylinder and recycling of scrap.

8. Even post heat-treated PAI is still somewhat thermoplastic but the melt viscosity is so high that it cannot be plasticized again.

Structure and General Properties-1

1. The imide content imparts high stiffness, hardness and flame retardance while the amide groups effect flexibility and ductility and melt process ability of this polyamide imide.

Structure and General Properties-2

Polyamideimides are characterized by the following properties:

-  high strength between - 190 & + 260 °C,

-  high impact strength,

  high dimensional stability (amorphous

   thermoplastic),

-  high fatigue limit (JBW = 56 N/mm2),

Structure and General Properties-3

-  high heat distortion temperature (265 to 280°C),

- low coefficient of linear expansion (6x10-6 to  20x10-6 K -1),

-  very good dielectric properties,

-  high chemical resistance (except to strong

-  alkaline solutions, oxidizing acids, nitrogen­

-  containing solvents, superheated steam above 160 °C).

-  resistant to stress cracking media,

Structure and Properties -4

- flame retardant (V-0), low emission of smoke and toxic gases,

- resistant to oxidation,

- resistant to high energy radiation,

- high UV stability,

- low outgassing losses in high vacuum,

- can be bonded,

- can be metallized by conventional methods. 

Designers and processors must note the following:

-  the relatively high melt viscosity limits the size of injection moldings,

-  high pressures and injection speeds are required for injection molding,

-  pellets must be predried,

-  injection molds must be preheated to between 200 and 260 °C,

-  moldings must be post heat treated.

Availability

 - The range includes the unmodified grades and other injection molding and extrusion compounds with fillers and/or reinforcements. PTFE and graphite filled grades are available.

- PAI is supplied as pellets for injection molding.

Mechanical Properties-1

Short-term Behavior at Low Rate of Deformation:

1. At room temperature, PAI do not exhibit a yield point. 

2. Even at 204°C, the flexural strength of the PAI grades selected is superior to that of well known high temperature resistant thermoplastics and even polyimides. 

3. The high level of mechanical properties of PAI is retained even after extended annealing at 250 °C.

Mechanical Properties-2

Creep Behavior Under Uniaxial Stress: 

1. PAI is very creep resistant. It reacts to high mechanical stresses more like metals than plastics. 

2. Glass fiber reinforced PAI are suitable for high mechanical and thermal stresses.

3. Behavior at High Rate of Deformation:

The impact strength of PAI is superior to that of other high-performance plastics.

Behavior Under Vibration: 

1. PAI exhibits a high fatigue limit which is maintained up to about 170 °C. 

Mechanical Properties-3

Friction and Wear Characteristics: 

1. The frequent use of PAI, especially the graphite and PTFE-filled grades for manufacturing bearings is based on the low wear of this material even in dry running.

2. All PAI moldings must be subsequently heat treated. The wear factor K is significantly affected by this post-treatment. Maximum wear resistance is achieved after more than eight days at 260 °C.

Electrical Properties

1. PAl exhibits excellent electrical & dielectric properties. 

2. The conductivity of PAI can be increased by the addition of graphite. 

3. Material reinforced with 30% w/w carbon fiber is used to shield components from electromagnetic interference (EMI).

Water Absorption

1. In humid atmospheres or when immersed in water, PAI absorbs small amounts of moisture. 

2. The maximum amount of water absorbed (5% w/w) is reached after about three months immersion at 90°C. The absorbed water is rapidly given off again by warming the molding to temperatures between 120 and 175°C. 

3. The dimensions of the molding alter on absorption of water and the dimensional stability at high temperatures falls.

Weathering Resistance

PAI exhibits excellent UV and thus weathering resistance.

Resistance to High Energy Radiation

PAI is very resistant to radiation. 

Flammability

PAI is distinguished by low smoke emission in fires. The flame temperature is 570 °C, The oxygen index varies between 44 and 52% depending on grade.

Processing -1

1. PAI has a high melt viscosity and is reactive in the melt state. This prevents the use of increasing temperature to decrease viscosity. 

2. PAI is best fabricated with heavy duty, high rate injection-molding equipment. The high rate is preferentially obtained by use of hydraulic accumulators. 

3. PAI is shear sensitive and low compression screws are recommended. 

4. Prior to injection, compression or transfer molding, PAI must be dried for about 16 hours at 150 °C or, in the case of injection molding granules, for about 8 hours at 180 °C.

Processing-2

1. At low shear rates, the viscosity of the PAI melt is very high. 

2. At higher shear rates it approaches those of polycarbonate and ABS. Thus complicated injection mold cavities can be filled at high injection speed with relatively low injection pressure. 

3. The viscosity is not particularly temperature dependent in the processing range of 315 to 360°C. 

Processing-3

Processing conditions are:

Injection molding: 

Melt temperature:           336 to 360 °C

Mold temperature:          230 °C

Compression molding:

Molding pressure:           35 N mm-2

Mold temperature:          345°C

Preheating is required.

Processing-4

1. Finally, post cure is an important step in processing PAI. 

2. PAI moldings must be heat treated. The temperature is maintained at 245 °C for 24 hours and then raised to 260°C over 24 hours. 

3. Components subject to wear should be kept at this temperature for 5 days to increase wear resistance.

Surface Finishing

1. Of all the current metallizing processes such as electroplating, plasma spraying, ion plating and vacuum metallizing, only the last is unsuitable. 

2. The moldings are first pickled, then washed, catalytically treated, activated, chemically nickel plated, then electroplated and dried. Electroplating is performed only prior to heat treatment

Joining

1. Bonding PAI moldings can be bonded using adhesives based on amide-imide. Such joins can be mechanically stressed and are resistant to heat and chemicals. Suitable adhesives can be prepared by, for example, dissolving PAI in n-methyl pyrrolidone (35% solution).

2. The surfaces to be joined must be free of grease and clean and fit closely together. Roughening increases the bond strength. After applying the adhesive and pressing the parts together, they are kept at 175 to 190 °C for 30 minutes. Temperatures of 230 to 245 °C are used for wall thicknesses greater than 10 mm. epoxide resins and cyanoacrylate adhesives are also suitable although their physical and chemical limitations should be taken into account.

Typical Applications-1

1. PAI glass reinforced resin grade is characterized by high strength and high modulus.

2. It has a very high strength to weight ratio allowing it to replace metal in compressors and in aerospace applications, including housings, structures, and equipment boxes. 

3. PAI is used successfully for load bearing components exposed to temperatures up to 260°C. Stresses are mainly mechanical and/or electrical.

Typical Applications-2

1. Components subject to electrical/dielectric stresses include connector insulating components of special grades of PAI for the aerospace industry and coil formers and for seismographs.

2. Moldings subjected mainly to mechanical stresses include cam switches, vanes for hydraulic & pneumatic motors, bearings and housings for petrol consumption gauges for the automotive industry, cover frames for office machinery, slide rings.

Typical Applications-3

Parts for military aircraft, automotive transmissions and off-highway equipment – including hydraulic parts, seal rings, washers and bushings – can last longer when made from PAI because these resins combine incredible wear resistance with other long-life benefits like toughness, thermal performance and chemical resistance. Plus they’re injection moldable, so fabrication can be easier and less costly than machining metal parts.

Typical Applications-4

1. Precision components made from PAI are virtually indestructible, making them a strong performer for demanding electronic handling operations. 

2. Test sockets molded from PAI are used to protect delicate devices during robotic handling and high-speed, high-force compression into electrical test sockets.

Typical Applications-5

1. Testing units for printed IC boards must be sealed to maintain test temperatures from -50°C to 150°C. Seal adapters machined from PAI can provide better dimensional stability for a tighter seal fit and offer longer part life than traditional materials.

2. PAI resin is also a major player in coating applications, due to its outstanding surface adhesion to a multitude of materials including metals and polytetrafluoroethylene. PAI dissolved in polar solvents is used to make high temperature resistant wire lacquers and adhesives.

PROPERTIES

1. Good resistance to chemicals

2. Excellent resistance to radiation

3. Very high mechanical properties

4. High temperature stability

5. Continuous use temperature is 200 ºC

6. High stiffness

7. Inherently flame resistance having LOI 43%

APPLICATIONS

Aerospace

1. Jet engine components, compressor & Generator parts, fasteners

2. Adaptors and electronic connectors.

Automotive

1. Transmission, Thrust washers & piston rings, ball bearings, wear surface

2. Bushings, seals, flow control components, racing engine connecting

3. Rods, thrust washers, gears.

Industries Injection Mould Materials

Industries Injection Mould Materials:

Sprue Bush: MS, HDS (H11, H13)

Locating / Register Ring: MS

Top Plate: C45 / MS / EN9

Cavity Ejecter Plates: P20

HRS Plate: HDS (H13,H11)

Stipper Plate: C45

Cavity Plate / Housing: EN353, P20

Cavity Inserts: P20,

Slider: P20

Slider Guide Rail: EN31

Heal Block: EN31, EN36

Finger Pin: EN8, EN9, EN353 (H13)

Pressure Pad: EN31, P20

Wear Plate: EN31, P20

Core Pin: EN, BeCu

Core Inserts: STAVAX, CALAX, NINEX, P20, SS420

Core Plate / Housing: EN353, P20

Guide Pillar: EN353, EN31

Guide Bush: EN353, BRONZE

Push Back Pin: EN31

Limit Bolt: EN8

Ejecter plate: P20

Ejecter Back Plate: P20

Ejecter Rods / Pin: Hot Die Steel (H11 S30), P20

Lifters: P20

Lifter Rods: EN8 / EN353

Ejecter / Knowout Pad: MS / EN31 / EN36

Spacer: C45 / MS / EN9 / EN8

Button: EN8 / EN353

Back Plate: C45 / MS / EN9

Legs: MS

Mould Lock: EN8 / MS / EN24

Hydrolic Cylinder: Piston Seals(PU, Nitrial, Rubber, Nylon, Teflone), Rod Seal, Viper Seal

Spring: 

Eye Bolt: EN8

Oring: Nitrial, Silicon(Black), Viton(Btown, Black)

Press Tool material: D2, SCSR

Through Hard process apply: EN31, EN36

Case hard process apply: EN8, MS, EN9

Waste

Waste: Plastic is the general common term for wide range of synthetic or semi synthetic organic amorphous solid materials derived from oil and natural gas.

PET: is also known as a wrinkle-free fiber. It’s different from the plastic bag that we commonly see at the supermarket. PET is mostly used for food and drink packaging purposes due to its strong ability to prevent oxygen from getting in and spoiling the product inside. It also helps to keep the carbon dioxide in carbonated drinks from getting out. Although PET is most likely to be picked up by recycling programs, this type of plastic contains antimony trioxide—a matter that is considered as a carcinogen—capable of causing cancer in a living tissue. The longer a liquid is left in a PET container the greater the potential for the release of the antimony. Warm temperatures inside cars, garages, and enclosed storage could also increase the release of the hazardous matter.

HDPE: Quite special compared to the other types, HDPE has long virtually unbranched polymer chains which makes them really dense and thus, stronger and thicker from PET. HDPE is commonly used as the grocery bag, opaque milk, juice container, shampoo bottles, and medicine bottle. Not only recyclable, HDPE is relatively more stable than PET. It is considered as a safer option for food and drinks use, although some studies have shown that it can leach estrogen-mimicking additive chemicals that could disrupt human’s hormonal system when exposed to ultraviolet light.

PVC: is typically used in toys, blister wrap, cling wrap, detergent bottles, loose-leaf binders, blood bags and medical tubing. PVC or vinyl used to be the second most widely used plastic resin in the world (after polyethylene), before the manufacture and disposal process of PVC has been declared as the cause of serious health risks and environmental pollution issues. In the term of toxicity, PVC is considered as the most hazardous plastic. The use of it may leach a variety of toxic chemicals such as bisphenol A (BPA), phthalates, lead, dioxins, mercury, and cadmium. Several of the chemicals mentioned may cause cancer; it could also cause allergic symptoms in children and disrupt the human’s hormonal system. PVS is also rarely accepted by recycling programs. This is why PVC is better best to be avoided at all cost.

LDPE: As said before, Polyethylenes are the most used family of plastics in the world. This type of plastic has the simplest plastic polymer chemical structure, making it very easy and very cheap to process. LDPE polymers have significant chain branching including long side chains making it less dense and less crystalline (structurally ordered) and thus a generally thinner more flexible form of polyethylene. LDPE is mostly used for bags (grocery, dry cleaning, bread, frozen food bags, newspapers, garbage), plastic wraps; coatings for paper milk cartons and hot & cold beverage cups; some squeezable bottles (honey, mustard), food storage containers, container lids. Also used for wire and cable covering. Although some studies have shown that LDPE could also cause unhealthy hormonal effects in humans, LDPE is considered as a safer plastic option for food and drink use. Unfortunately, this type of plastic is quite difficult to be recycled.

PP: Stiffer and more resistant to heat, PP is widely used for hot food containers. Its strength quality is somewhere between LDPE and HDPE. Besides in thermal vests, and car parts, PP is also included in the disposable diaper and sanitary pad liners. Same as LDPE, PP is considered a safer plastic option for food and drink use. And although it bears all those amazing qualities, PP isn’t quite recyclable and could also cause asthma and hormone disruption in human.

PS: Polystyrene is the Styrofoam we all commonly used for food containers, egg cartons, disposable cups and bowls, packaging, and also bike helmet. When exposed with hot and oily food, PS could leach styrene that is considered as brain and nervous system toxicant, it could also affect genes, lungs, liver, and immune system. On top of all of those risks, PS has a low recycling rate.

Type of Waste:

1. Defect/Rework: Defects Waste in Lean Manufacturing occur when a product is found to have flaws in it after production occurs. The affected parts must be replaced or reworked completely resulting in additional costs, delays and possible safety issues. In Lean Manufacturing, waste is called Muda, waste in the Japanese language. Two types of waste have been identified, Obvious and Hidden. Obvious Waste is waste that is easily seen, such as producing too many parts than what is needed, or producing parts which do not meet specifications. Hidden Waste is work that is necessary to produce a manufactured product that is also work that could be eliminated by using an alternative process or technology to produce product, one which requires less resources.

In general, as you’re analyzing the process to eliminate defects you’ll often find that there is:

1. a lack of standards or poor documentation

2. poor quality controls

3. a lack of a defined process altogether

4. poor or un-manufacturable product design

5. undocumented design changes that don’t marry to related parts

6. poor inventory control leading to ad-hoc manufacturing process adjustments.

This means that you should:

1. review the part or product design for ‘designed-in’ defects

2. check for standardized work plans and QC job aids such as checklists

3. check for a full understanding of product requirements and consider training

4. ask the people in that area!

2. Overproduction: Within Lean Manufacturing, lean consultants often find that Overproduction has the most significant impact on the success of the business. Anytime that a part, assembly or final product is produced that is unable to be used or sold due to lack of an (internal or external) customer, the business has created Overproduction Waste. In addition to the direct cost to the company of Overproduction Waste, Overproduction Waste can also contribute to Inventory or Transportation Waste, compounding the destruction of value for the business.

1. long setup times, leading to the desire for long production runs

2. manufacturing ‘Just in Case’ items are needed internally or externally

3. poor understanding of customer needs

4. producing for a forecast as opposed to having inventory ‘pulled’ as it’s needed

5. product design changes while existing designs are in process

6. badly implemented automation

3. Waiting: When traditional manufacturing processes are used, when one part of the manufacturing phase is completed there is usually a waiting period before the next phase can be continued. With Lean Manufacturing the waiting time (Waiting Waste) for a product is narrowed down to a much shorter period of time or eliminated completely.

With more careful planning and coordination it’s possible to get a quick return on investment from your manufacturing operation.

Types of Waiting Waste include:

1. parts or assemblies waiting in queues for the next step in the operation

2. people waiting for material, equipment or tools to perform their operation

3. finished products waiting to be shipped or sitting in stores

4. idle equipment

Typical causes of Waiting Waste include:

1. unplanned downtime

2. production bottlenecks and not balanced production workloads

3. setup times that are too long

4. producing to a forecast instead of a pull system

5. not enough people

6. people out unexpectedly

7. poor quality built into the process

8. ineffective internal communication

4. Not Clear (Confusion): Non-Utilization Waste in Lean Manufacturing is when personnel are idle waiting for the materials to come from a previous manufacturing step, or when people are under-utilized relative to their skills or knowledge set. Non-Utilization Waste is the only Lean Manufacturing waste that is not directly connected to a manufacturing process but instead is a management issue. If people are not adding the most value possible for their skill set and availability this is non-utilization waste.

Non-Utilization Waste manifests itself as people:

1. not being on task

2. not following processes

3. not having well established processes

4. not leveraging available critical thinking skills

5. and in overall demotivation due to broken processes or an inability of the person to provide feedback to the management system on how to improve processes, conditions or products.

Non-Utilization Waste can occur from:

1. administrative types of tasks that don’t add value

2. ineffective communication

3. lack of a teamwork environment

4. mis-assignment of tasks to people with the wrong skills

5. poor training

6. poor listening skills

7. rushed decisions

5. Transporting: Lean Manufacturing identifies different types of waste in manufacturing processes so that these can be identified and eliminated. In this, Part 5 in our 8 Part Series, we discuss Transport Waste. Transport waste is when a product that is meant to be used in manufacturing is moved or touched unnecessarily. Moving not only costs money, but can also result in the increased risk of that product being damaged, lost or misused. Lean Manufacturing negates the issue of transport waste due to the pre-assembly and pre-fabrication of parts that occur prior to their arrival at the manufacturing site. Once the pre assembled parts arrive at the manufacturing site they do not need to be transported again.

More often than not, Transportation Waste is caused by:

1. Unnecessary steps in a process

2. Poor production layout

3. Process flows which are not aligned

4. Not well designed systems

6. Inventory: Among the types of waste identified in Lean Manufacturing is Inventory Waste. Inventory waste is inventory that is left untouched waiting to be used. This wastes  space as well as the capital used to purchase the inventory without immediate financial returns. With the implementation of Lean Manufacturing, all inventory is accounted for prior to being ordered and the foreman on site knows exactly how inventory will be used. Lean Manufacturing enables a continuous workflow and creates a more predictable schedule, lessening the inventory that is over-ordered or never used.

Inventory Waste is often related to Motion and Transport Waste and be be driven by:

1. over-purchasing, including when perceived savings can be had through bulk discounts

2. overproduction of parts, assemblies or end products

Inventory Waste in often caused by:

1. Unreliable supply chains

2. Not understanding demand

3. Long setup times

4. Production speeds that are not aligned between production areas

5. Overcapacity in some areas and undercapacity in others

6. Poor monitoring systems

Steps to take to reduce or eliminate Inventory Waste include:

1. obtaining raw materials only as necessary and in only the quantities needed

2. reducing buffer inventory between process steps

3. moving to a ‘pull’ or Kanban system of manufacturing

7. Motion: When Lean Manufacturing approaches the issue of motion it is not related to the physical movement of products that are used to create the end result (Transport Waste), but rather the people or equipment that are used to create physical products. Motion Wasted in lean manufacturing is the increased motion of machinery or a person due to an inefficient manufacturing process. Wasted motion increases the amount of wear and tear on both workers and machinery, therefore decreasing its lifespan or ability to work on at a manufacturing site. Not only does wasted motion cost money, it can also lead to unnecessary accidents and injuries.

Motion Waste can be caused by:

1. Inefficient floor layouts

2. Improper equipment

3. Poor allocation of tasks between machinery, people or steps in a process

Motion Waste can often be categorized and measured by looking at activities such:

1. walking

2. reaching

3. lifting

4. lowering

5. bending

6. stretching

7. or otherwise unnecessary moving, such as traveling to other facilities when other forms of meetings would do

8. Excess Processing: Many factors can lead to Overprocessing Waste. Sometimes, products that are excessively processed are highly complex and expensive and it can be difficult to clearly identify overprocessing. At other times, a comparison of detailed customer specifications or the elimination of rework can eliminate overprocessing. By using Lean Manufacturing, products are designed and fabricated using equipment and design methods that help to ensure products that exactly meet end customer requirements.

Causes of Overprocessing Waste include:

1. Poorly communicated customer specifications that leave doubt as to exact requirements

2. Rework to meet product specifications or quality requirements

3. Poorly planned work processes that cause extra steps along the way

4. Including more components or material than necessary for the product to meet specifications

5. Delivering higher precision dimensional components than necessary

6. Using materials with properties that unnecessarily exceed specifications such as strength, hardness, purity etc.

Why Should We Recycle Plastic Waste?

Plastic recycling reduces C02 emitted from the manufacture of new plastic, emissions from incinerating plastic waste and prevents waste from going to landfill. It also reduces the speed at which we use the earth’s oil stocks. Further, recycling plastic is more energy-efficient than producing new polymers.