Module Title: | Detailing & Specification |
Language of Instruction: | English |
Module Delivered In |
No Programmes
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Teaching & Learning Strategies: |
The learner is immersed in a range of collaborative, problem-solving activities, to investigate and evaluate where design can propose solutions for commercial and social benefit. The holistic, student-centred, studio-based approach, facilitated by faculty, is intended to negotiate, facilitate and guide learner engagement and scaffold a deep-learning using the following strategies: Lectures, Studio-based learning, Presentation, Workshop and Self-directed independent learning. |
Module Aim: |
The aims of the Case Bridging Study element of this module are: to investigate the theory of form and the visual perception of products; to promote an understanding of the principles and context of form in product design; and to provide a practical and ordered approach to form generation. The learner will investigate the functional and physical requirements of component parts and product architecture requirements to assist in the design of more appropriate and progressive and engaging products. The aim of the Design Specification element of this module is to facilitate the learner with integration and implementation aspects of the component sourcing and design for manufacture and assembly elements of the Honours Degree Project. |
Learning Outcomes |
On successful completion of this module the learner should be able to: |
LO1 |
Recall and demonstrate implementation of the key principles of form generation through a practical and ordered approach to concept design and design development work. |
LO2 |
Demonstrate a clear understanding of the functional and physical requirements of individual component parts and product architecture in product design work. |
LO3 |
Demonstrate an ability to control form and to prepare and present designs for appropriate, progressive and engaging products. |
LO4 |
Recall principle modelling concepts necessary for successful three dimensional solid modelling. |
LO5 |
Demonstrate a high level of proficiency in computer-aided solid-modelling and surface-modelling when designing individual parts and assemblies. |
LO6 |
Prepare fully-defined and dimensioned solid-modelling files for export to conversion software. Create roughing and finishing raster-based tool paths from solid-modelling files for export to postprocessor equipment for machining. |
LO7 |
Incorporate outputs from CNC postprocessor equipment to assist in the preparation of scale models and appearance models. |
LO8 |
Present, on suitable storage media, a comprehensive suite of part and assembly files showing fully dimensioned and annotated 3D models that comply with the latest BSI and ISO standards of technical product specifications and documentation. |
LO9 |
To review personal application & deliverables over the year and deliver a development plan |
Pre-requisite learning |
Module Recommendations
This is prior learning (or a practical skill) that is recommended before enrolment in this module.
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No recommendations listed |
Incompatible Modules
These are modules which have learning outcomes that are too similar to the learning outcomes of this module. |
No incompatible modules listed |
Co-requisite Modules
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6868 |
DSGN H4424 |
Human Centred Design & Interaction |
Requirements
This is prior learning (or a practical skill) that is mandatory before enrolment in this module is allowed. |
No requirements listed |
Module Content & Assessment
Indicative Content |
Terminology
Coursework will cover the basic concepts and terminology used in three-dimensional solid-modelling applications such as: Feature-based Modelling, Parametric Modelling, Solid-modelling, Surface Modelling, Design Intent.
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CBS - Project Framing
Learners will explore form to convey meaning through: shape, scale, texture, colour, material selection and manufacturing processes. Successful form generation is always directed towards opportunities and held within constraints. Learners will be encouraged to explore contextual form factors through a series of form generation boards covering product predecessors, competing products, corporate personality/identity and form benchmarking. Learners will also explore intrinsic form factors and how these elements impact on product symbolism and semantics. Learners will be required to prepare these boards, together with a form generation statement to outline the intended direction for establishing the physical appearance principles and parameters for directing form generation during the project. Through defining and describing these opportunities and constraints the learners will be better equipped to direct the form generation process.
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CBS - Concept Design
The Case Bridging Study is designed to encourage learners to communicate their form generation efficiently through sketching and sketch models.
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CBS - Design Detailing
Learners will also source components and fittings and be expected to consider product architecture requirements including the functional aspects, such as the individual operations and transformations that contribute to the overall performance of a product, and the physical elements, such as the parts, components and sub-assemblies that implement the product’s function, to prepare product architecture proposals that are both considered and appropriate. Elements of the Ergonomic Study and Form Iteration Modelling stages in the Human Centered Design module will be applied to the design detailing stage. Learners will be encouraged to demonstrate that product architecture proposals have considered ergonomic requirements, possible future changes to the product, opportunities for product variety, component standardisation, product performance, design for manufacture and assembly and issues regarding the management of future product development. In turn, elements of the Design Detailing stage will inform the Model Planning stage of the Human Centered Design module.
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CBS - DFMA Through SolidWorks
Design for Manufacture and Assembly is the combination of design for ease of manufacture of component parts and the design of the product for easy of assembly and, sometimes, disassembly too. Learners will be encouraged to simplify the product structure, to reduce manufacturing and assembly costs, and to quantify improvements in overall performance. Work undertaken during the design detailing and design for manufacture and assembly elements of this module will feed directly into the Concept Realisation element of the Human Centered Design module.
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CBS - Final Presentation
PowerPoint presentation reviewing all elements of the Case Bridging Study from initial project framing through to final presentation renderings and model,
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Design Specification
Most of this part of the module is allocated for learners to practice and prepare for computer aided modelling and design specification for Honours Degree Project submissions. Learners will prepare a suite of files to include a solid-model base-part file and tool path files necessary to machine (subtractive manufacture/modelling) or to 3D print (additive manufacture/modelling) appearance evaluation models in appropriate modelling material. Learners will be constantly challenged during self-directed projects and this module requires learners to employ creative thinking and demonstrate problem solving abilities for transforming design sketches and sketch models into computer generated solid-modelling. Should learners encounter problems with individual project work then instructions or modelling procedures, salient to their specific needs, will be demonstrated either directly within the learner’s solid-modelling file or as a live working example to the entire class. Additional modelling skills will be demonstrated using interactive exercises, examples and also as individual learners encounter problems with project work.
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Design Specification - Component Sourcing
Sourcing of proprietary component parts, examination of materials, manufacturing processes, detailing and finishes.
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Design Specification - Design for Manufacture and Assembly
During this module learners will develop and demonstrate their design proposals paying particular attention to detailing, wall thicknesses, draft angles, ribs, bosses and internal detailing and tolerances.
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Design Specification - Bill of Materials
Learners will compose a Bill of Materials (BOM) listing of raw materials, parts, sub-assemblies and the quantities of each needed to manufacture the end product.
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Design Specifications - Technical Drawings
Learners must prepare and submit, on a memory stick or other storage media, a suite of part and assembly files showing a fully dimensioned and annotated 3D models that comply with the latest BSI and ISO standards of technical product specifications and documentation. A full set of printed technical drawings (GA and two, or more, interconnecting parts files) also form part of this module’s submission requirements.
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Design Studio (Resource)
A dedicated space designed to allow for studio-based learning. This space is specific to a particular learning group. While used to deliver studio-based education the space is available to accommodate learners outside scheduled/timetabled hours. It provides a safe learner-driven, peer-reviewed environment, supported on a one-to-one basis. It supports the synthesis of parallel concurrent modular knowledge, skills and competency with prior learning & personal aesthetic judgement, to resolve specific design research question/s.
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Computers/Plotters/Printers (Resource)
In this year each learner requires the use of a personal computer of suitable specification to run software used on the design programme. There should be access to printing and plotting facilities in order to complete final deliverables for the Honours Degree Project.
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Assessment Breakdown | % |
Continuous Assessment | 100.00% |
Continuous Assessment |
Assessment Type |
Assessment Description |
Outcome addressed |
% of total |
Assessment Date |
Project |
PowerPoint presentation of Case Bridging Study project to include project outline and brief, contextual boards, form generation statement to include product symbolism and semantics, concept sketching and selection, evidence of sketch modelling. Final presentation images showing product architecture/component layout, exploded views, surfaces and finishes. |
1,2,3,4,5,6,7,8 |
35.00 |
Week 13 |
Project |
Suite of Solid Modelling Files (Part and Assembly files) showing fully dimensioned and annotated 3D models that comply with the latest BSI and ISO standards of technical product specifications and documentation.
A full set of printed technical drawings (GA and two, or more, interconnecting parts files) also form part of this module’s submission requirements. |
1,2,3,4,5,6,7,8 |
35.00 |
Week 29 |
Reflective Journal |
Reflective Practice: reviewing approach, engagement, performance, with aligned modular elements and identification of future developmental need/s in design practice. |
1,2,3,4,5,6,7,8,9 |
20.00 |
Week 30 |
Oral Examination/Interview |
P16: Honours Degree Project Defence & Synthesis. Learners will present for interview, submit and defend Honours Degree Project |
1,2,3,4,5,6,7,8,9 |
10.00 |
Week 30 |
No End of Module Formal Examination |
SETU Carlow Campus reserves the right to alter the nature and timings of assessment
Module Workload
Workload: Full Time |
Workload Type |
Frequency |
Average Weekly Learner Workload |
Studio Based Learning |
Every Week |
4.00 |
Independent Learning Time |
Every Week |
2.00 |
Total Hours |
6.00 |
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