Fiberglass as a medium for sculpture

Tasch, Thomas John.

January 1965

Call number: LD2668 .T4 1965 T197

Sculpture.

Plastics--Molding.

Masters theses

Computer controlled inspection for operation of plastic molding machine

Costello, John T., Dorf, Roger A.

January 1970

Thesis (M.E.)--Boston University / PLEASE NOTE: Boston University Libraries did not receive an Authorization To Manage form for this thesis or dissertation. It is therefore not openly accessible, though it may be available by request. If you are the author or principal advisor of this work and would like to request open access for it, please contact us at open-help@bu.edu. Thank you. / This report involves the overall design of a closed loop computer control plastic injection molding system and detailed design of the inspection portion of the system for a specific part. This project is concentrated on the inspection portion of the system. A part and its print specifications were provided. Design requirements called for 100% inspection of the critical part dimensions which were most subject to change. The main system constraints influencing the design were inspection accuracy and speed. The system also had to be designed using available hardware. A gaging system was designed to be used in conjunction with a Digital Equipment Corporation (DEC) PDP-8/I computer to inspect plastic parts produced by an Allrounder 100 injection molding machine. The design of a gage system that allows fast and automatic checking of the part requires sensitive instruments. Linear transducers were used in order that fast checking would be accomplished and allow the gage to be paced with the plastic molding machine. After the checking fixture design was completed and components ordered, a work station design was made in order to fully utilize the check fixture. Two designs were completed with one under an inspector's control and the other completely mechanized for future hookup with a computer controlled robot. A computer program was written to accept voltage signals from the transducers, convert them to part deviations, compare them to specified tolerances, and make an accept/reject decision on each part. The design is limited to one specific part, but that does not decrease the importance of the project because the parameters worked with are measured in all parts. The checking method may vary somewhat for different parts, but the basic concept will not change. The design phase is complete. It was planned that the building of the system should be completed in two successive phases and a third phase used for a critical evaluation of the system. In phase 1 the system should be completed, the computer software developed and tested, the checking fixture completed and checked out, and the manual work station designed in detail. Phase 2 would involve a balance of the work and decision making between the computer and the operator. The necessary computer hardware and software would be developed and debugged and the work station changed to allow automatic operation, thus saving an inspector's time. The final stage will be an analysis of phases 1 and 2 and possible further extension of the system to other parts so that it is more universal. The analysis will be directed at determining the economic feasibility of the system for industrial applications. / 2031-01-01

Manufacturing engineering

Plastic molding

Automation

Experimental study of anisotropy in injection molded thermoplastic parts

Bakerdjian, Zaven

January 1978

No description available.

Injection molding of plastics.

Anisotropy.

Thermoplastics.

The dynamics of thermoset injection molding and the anistropies of molded parts /

Sidi, Shiraz Ismail.

January 1980

No description available.

Thermosetting plastics.

Injection molding of plastics.

Thermal Models and Energy Saving Strategies for Rotational Molding Operations

Ghosh, Kalyanjit

09 July 2004

Transient heat transfer phenomena in the rotational molding of plastic parts are modeled in this study. Natural convection and radiation from the furnace and flue gases to the mold housing are analyzed. Other models include transient heat transfer through the mold, single-phase conduction through the particulate plastic material prior to phase change, melting of the plastic and heating of the liquid pool. Subsequent staged cooling of the mold and solidification of the plastic using a combination of free and forced convection and radiation, are also modeled. The mold wall, melt, and solidified plastic regions are divided into a number of finite segments to track the temperature variation with time during the molding process. The corresponding variations in masses and thicknesses of the melt and solidified plastic regions are estimated. This information is used to estimate the energy consumption rates for various phases of the process. The model is applied to a specific molding process in a commercial rotational molding plant. Parametric studies of the effect of heating and cooling durations on the plastic temperatures and the energy consumption rates are conducted. These analyses provide insights about opportunities for optimization of the heating and cooling schedules to reduce overall energy consumption and improve throughput. The overall energy and gas consumption for the rotational molding process, taking into consideration the thermal mass of the auxiliary housing (steel) required to hold the molds, is estimated on a per-batch basis. In addition, a preliminary design for an alternative system for heating and cooling the molds using a high temperature heat transfer fluid (HTF) flowing through jackets integral to the molds is proposed.

Rotational molding

Energy saving strategies

Synthesis and characterization of divinyl monomers for styrene-based reaction injection molding

Sanchez, John Lawrence

28 August 2008

Not available / text

Monomers

Injection molding of plastics

Styrene

Slicing of 3D CAD models for mould design

黃挺, Wong, Teng.

January 1998

published_or_final_version / abstract / toc / Mechanical Engineering / Master / Master of Philosophy

Experimental study of anisotropy in injection molded thermoplastic parts

Bakerdjian, Zaven

January 1978

No description available.

Anisotropy.

Injection molding of plastics.

Thermoplastics.

Finite element and experimental analyses of the inflation of membranes in relation to thermoforming

Wu, Richard L.

January 1984

No description available.

Plastics -- Molding.

Finite element method.

Structural analysis of thick polypropylene moldings

Shindo, Nobuhiko

08 1900

No description available.

Molding materials

Polypropylene

Crystalline polymers