1 / 40

Manufacturing with Plastics

Manufacturing with Plastics. Chapter 18. Competencies. Define key terms associated with polymers and plastics and describe the difference between the two. Differentiate between thermoplastics and thermosets, and identify the use for each.

jayme
Télécharger la présentation

Manufacturing with Plastics

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Manufacturing with Plastics Chapter 18 Chapter 18

  2. Competencies • Define key terms associated with polymers and plastics and describe the difference between the two. • Differentiate between thermoplastics and thermosets, and identify the use for each. • Identify the correct plastics process used to make uniquely different products • Define the two processes of polymerization • Differentiate between linear, branched, and cross-linked polymers Chapter 18

  3. Chapter 18

  4. Chemistry of Polymerization The carbon atom must always have four covalent bonds. The four noted carbon compounds are • Methane – has one carbon atom bonded to four hydrogen atoms • Ethane – two carbon atoms with six hydrogen atoms • Propane – three carbon atoms with eight hydrogen atoms • Butane – four carbon atoms with 10 hydrogen atoms Chapter 18

  5. Chemistry of Polymerization Every carbon atom must have four bonds, but it is possible for two or three of the bonds to be between the same two carbon atoms. • If two of the hydrogens are removed from the ethane molecule, the bonds that went to the hydrogen will simply form a new double bond between the carbons. (p.340) When double bonds are formed • the once “ane” suffix is changed to “ene” • triple bond is formed the “yne” suffix is used. So we have the progression of: Ethane to Ethene to Ethyne (Acetylene) Chapter 18

  6. Chapter 18

  7. Chemistry of Polymerization An unsaturated molecule is any compound having double or triple bonds. This unsaturated state enables the compound to be reacted with itself, which is the key to polymerization. Chapter 18

  8. Chemistry of Polymerization • A molecule will polymerize if • it has at least two reaction points • maintains at least two reaction points after each joining of the compound. • Polymerization is when these bonds are opened, they can react with another ethane molecule and continue reacting to form chains containing thousands of carbon atoms. Chapter 18

  9. Chemistry of Polymerization • This type of polymerization is called addition, chain-growth or chain reaction polymerization. • Condensation polymerization also known as step-growth or step-reaction. • One characteristic of this reaction is that reaction by-products such as water are condensed out. Chapter 18

  10. Polymers The reactions form what is know as polymers. Polymers are grouped into 3 categories • Thermoplastic polymers (TP) • represents 70% of the tonnage of all synthetic polymers produced. • Can be easily and economically shaped into products • Can be subjected to this heating and cooling cycle repeatedly without significant degradation of the polymer. Common TP polyethylene, polyvinylchloride, polypropylene, polystyrene, and nylon Chapter 18

  11. Thermoplastic (linear) - Soften repeatedly when heated (straight chains) • PET • Polyethylene Terphalate (Beverage Containers) • HDPE • High Density Polyethylene (Milk bottles, detergent bottles) • PVC • Polyvinyl Chloride (Food wrap, vegetable oil bottles) • LDPE • Low Density Polyethelene (Shrink wrap, plastic bottles) • PP • Polypropylene (Margerine and yogurt containers) • PS • Polystyrene (Egg cartons, fast food trays) Chapter 18

  12. Polymers • Thermosets polymers (TS) • cannot tolerate repeated heating cycles, when initially heated, they soften and flow for molding but the elevated temperatures also produce a chemical reaction that hardens the material into an infusible solid. • toaster parts, automotive engine parts, electrical outlet parts, handles on pots and pans, ash trays • Elastomers (rubbers) • exhibit extreme elastic extensibility when subjected to low mechanical stress. Chapter 18

  13. Polymers • Plastics • Polymers compounded with various additives. • Additives • Agents that enter the molecular structure and are designed to change its properties (Antioxidants, flame retardants, lubricants, etc.) • Fillers • Incorporated to improve mechanical properties, often called reinforcing agents. (Increase bulk, stiffness, etc.) Chapter 18

  14. POLYMER STRUCTURES AND COPOLYMERS There are structural differences among polymer molecules. There are three aspects of molecular structure • Stereoregularity • Branching and cross-linking • Copolymers. We will discuss only #2 and 3 Chapter 18

  15. POLYMER STRUCTURES AND COPOLYMERS Stereoregularity • Concerned with the spatial arrangement of the atoms and groups of atoms in the repeating units of the polymer molecule Branching and cross-linking (see overhead) • Linear polymers • Because their structure is linear. Generally, a polymer consists of more than one type of structure. • Thus a linear polymer may contain some branched and cross-linked chains. (This is the characteristic of a thermoplastic polymer) Chapter 18

  16. POLYMER STRUCTURES AND COPOLYMERS • Branched polymer • side branches chains are attached to the main chain during the synthesis of the polymer. • Branching interferes with the relative movement of the molecular chain. As a result, resistance to deformation and stress-crack resistance are affected. • Branched polymers are like a pile of tree branches compared to straight logs of linear chains Chapter 18

  17. POLYMER STRUCTURES AND COPOLYMERS Cross-linked polymers • when primary bonding occurs between branches and other molecules at certain connection points. • Lightly cross-linked structures are characteristic of elastomers. • When the polymer is highly cross-linked it considered thermoset. Chapter 18

  18. POLYMER STRUCTURES AND COPOLYMERS Chapter 18

  19. POLYMER STRUCTURES AND COPOLYMERS • Copolymers • Polymers whose molecules are made of repeating units of two different types. • Also possible are terpolymers , which consist of mers of three different types. (ex. ABS or acrylonitrile-butadiene-styrene) Chapter 18

  20. Crystallinity Amorphous and crystalline structures are possible with polymers, although the tendency to crystallize is much less than for metals and nonglass ceramics. Degree of crystallinity (the proportion of crystallized material in the mass) • As crystallinity is increased in a polymer, so does • Density • Stiffness, strength, and toughness • Heat resistance Chapter 18

  21. Crystallinity Crystallization in linear polymers involves the folding back and forth of the long chains upon themselves to achieve a very regular arrangement of the mers A number of factors determine the capacity and/or tendency of a polymer to form crystalline regions within the material. • As a general rule, only linear polymers can form crystals • Stereoregularity of the molecule is critical • Copolymers, due to their molecular irregularity, rarely form crystals • Slower cooling promotes crystal formation and growth Chapter 18

  22. Crystallinity Chapter 18

  23. Thermal & Mechanical Properties Chapter 18

  24. Manufacturing With Plastics Classification by process rather than product or material is more relevant, because most processes are suitable for making products from a large variety of plastics Casting - filling a mold by gravity • Liquid resins (epoxy) • Hot melted plastic poured into a casting (nylon) • Slush casting for thin walled products (snow boots, gloves, toys) • Wet spinning -fibers formed by spinning the solution through multi-hole dies • Rotational molding - variation of slush casting, mold is heated as it is rotated. Works exceptionally well for larger parts (IDOT barrels, chemical containers) Chapter 18

  25. Manufacturing With Plastics Molding - melt processing-polymers are deformed with the aid of applied pressure • Results in a finished part • Need three things to be a molding operation (Time, temperature, and pressure) Chapter 18

  26. Molding Process Extrusion • Pellets, granules or powder is placed into a hopper and fed into the extruder barrel. • As screw in the barrel that turns it blends and moves the material down the barrel. • Material then forced through a die that is in desired shape. It is cooled by water or air and cut to length. • Largest production volume of plastics (bar, tube, sheet, film) • Rated by the length to diameter ratio of the screw Chapter 18

  27. Extruder barrel and screw Chapter 18

  28. Molding Process Process can produce • Solid profiles • Hollow profiles • Wire and cable coating Defects in Extrusion • Melt Fracture • Sharkskin • Bambooing Chapter 18

  29. Defects in Extrusion Chapter 18

  30. Molding Process Injection molding • Similar to die casting metal. Pellets are fed into heated cylinder where they are melted. • The screw rotates much like extrusion molder (it moves back as material in front of it are melted) then it rams forward pushing the melted material into the die. • most wide spread technique for making 3-D configurations • uses either reciprocating screw or reciprocating plunger (RAM) • rated by clamping pressure of die Chapter 18

  31. Injection Molding Chapter 18

  32. Molding Process • Defects in Injection Molding • Short Shots • Flashing • Sink marks and voids • Weld lines Molds in injection molding are usually expensive and complex Chapter 18

  33. Molding Process Other molding techniques: • Thermoplastic Foam Injection Molding – involves the molding of thermoplastic parts that possess a dense outer skin surrounding a light weight foam center. • Multi-Injection Molding: • Sandwich – injection of two separate polymers • Bi-injection – used to combine plastics of two different colors or to achieve different properties in different sections of the same part. Chapter 18

  34. Molding Process • Reaction Injection Molding (RIM) – Two reactant liquids are heated and brought together under high pressure • Compression molding – Pre-measured amount of polymer introduced into the heated mold then the top half comes down and applies pressure. Usually uses thermosetting plastics and produces products like dishes, container caps, etc. Chapter 18

  35. Reaction Injection Molding Chapter 18

  36. Compression molding Chapter 18

  37. Transfer Molding Chapter 18

  38. Molding Process Blow Molding • Extruded tube or preform is expanded by internal pressure (most bottles) • Extrusion blow molding • continuous tube is extruded, pinched off, placed in a mold and blown into shape • Injection blow molding • part is injected into a mold then transferred and blown into shape Chapter 18

  39. Molding Process Thermoforming - Heating a thermoplastic sheet and using a vacuum to pull the sheet over perforated mold. • Fast food containers, advertising signs, panels for shower stalls • Hot air pressure and vacuum forming - drive sheet into female die cavity Chapter 18

  40. Chapter 18

More Related