2. Computer Aided Design and Production Process

2. Computer Aided Design and Production Process

Assoc.Dr. Ahmet Zafer Şenalpe-mail: [email protected]

Mechanical Engineering DepartmentGebze Technical University

ME 521Computer Aided Design

mailto:[email protected]

Design and Production Process

Mechanical Engineering Department, GTU

Dr. Ahmet Zafer Şenalp ME 521 2


Integrating The Design and ManufacturingProcess Through a Common Datase-A Scenario

Goals:Better qualityLower costQuick delivery

Design description: 4 spaces are needed in the cabinet1. CD player2. Cassette player3. Reciever4. Storage compartment of CD’s

Example: Audio system cabinet design





Preliminary Design:The designer can draw a lot of design concepts.During this phase, according to the need can make 2 or 3 dimensional modelsPhotorealistic images of preliminary designs can be created.

Preliminary designs submitted to acceptance:The design concept is sent to the market via e-mail to measure the response

Selection of the model that should be designed and feasibility study:Most admired model that collects the most sales potential will be the selected model.

When the design concept is completed, data is stored to the database: furniture fiction: The amount of shelf, the information such where to use which shelf are categorised and saved to database and in need can be recalled from the database and changed accordingly.





Determining the dimensions of the cabinet: Its overall size should be determined so that each space within it can accommodate various models of the audio components on the market. Thus it is necessary to obtain information on the sizes of the audio components available. This information may be obtained from catalogs or retrieved from manufacturers' or distributors' databases.

Determining the material to be used for the cabinet: The designer could specify natural oak, natural pine, particle board, steel sheet, or some other material.

However, in the case of products that operate under severe conditions, such as mechanical assemblies, the designer must be guided by the material's properties. The database is useful in this phase also because properties of many materials can be stored in it for later retrieval and use.





determining the thickness of each shelf and door and the side walls:

The thickness of the shelves must be sufficient to avoid deflection caused by the weight of the audio components. However, in mechanical assemblies requiring high accuracy or a structure supporting heavy loads, dimensions such as thickness must be determined to avoid excessive deformation. The finite-element method is generally used to calculate the deformation of a structure.

By evaluating the deflection of the shelves while varying the thickness of the shelves, the designer can determine the proper thickness of the shelves and store that information in the database.

In addition acoustic analysis may be necessary.

Assembly technique:Assembly technique is determined by an expert system.





Cabinet details:When the design conceptualization, analysis, and optimization phases have been completed, the designer moves on to design documentation to specify the details of the cabinet.

The part drawings of the shelves, doors, and side walls are generated by using computer-aided drafting. In this phase, the designer can add more details for aesthetic purposes.





To make the cabinet, each part shape is arranged on the raw material, in this case sheets of wood, and cut out with a saw.

Waste can be reduced by arranging the parts efficiently on the wood sheets. The designer can try various parts layouts on the com puter screen until obtaining a layout with minimum waste. The computer program can facilitate this process by calculating the amount of waste for each layout. Also a nesting program that automatically provides the most economic layout can be used.

Furthermore, software tools may be used to design the jigs and fixtures for this cutting process and to pro gram the materials handling systems. These systems may be conveyor belts or robots that transfer the raw material and the cut parts to and from the saw.





Once prepared, the parts have to be assembled. Ideally, the assembly process can also be carried out by robots that are programmed automatically from the descriptions of the final product and its parts that are stored in the database.

The jigs and fixtures for the assembly process can also be designed simultaneously.

In addition, a robot can be programmed to paint the cabinet after it has been assembled.

This scenario is summarized in figure given in next page. It shows how the CAD, CAM, and CAE activities are integrated through the database, which is the objective of CIM.




CAD, CAM and CAE IntegrationThrough the Database




Part Model




Finite Element Mesh




Applying Boundary Conditions




Results:Displacement




Results:Equivalent Stress




Geometric model

Pressure Vessel Analysis




Finite element model





Boundary conditions









Equivalent stress distributions

Example Part Solid Model




Finite Element Analysis




Flow Analysis




Die Design




CNC Cutter Locations




Documents

2. Computer Aided Design and Production Process