1,546 research outputs found
Manufacturing code generation for rotational parts in a feature based product modelling environment
An important element for the integration of CAD/CAM is the representation and handling
of data used during the design and manufacturing activities. The use of features and product
modelling techniques bring a better handling of this data and provide CAD/CAM with an excellent
platform for integration. The thesis explores the use of a predefined set of features in a product
modelling environment for the design and machining of rotational components.
Theword features in this research implies a set of functional, geometrical and technological
information with a unique form. Those features are pre-defined and comprise of a limited number
of elements which carry the information related to design and manufacturing activities.
The thesis is divided into three main parts. The first part contains a review of topics related
to the research e. g. group technology, component features, CAD/CAM and also contains a
literature survey of related research works.
In the second part the "features" are defined and presented. Also the product modelling
environment is explained and the basic rule based procedures which are used to automatize
the operation planning activities are presented.
In the last part a description of the case-studies used for automatic NC code generation
is presented followed by a discussion of the results. Lastly, the conclusions are drawn and ideas
for further work presented
Simulation of wind farms in flat and complex terrain using CFD
Use of computational fluid dynamic (CFD) methods to predict the power production from wind entire wind farms in flat and
complex terrain is presented in this paper. Two full 3D Navier–Stokes solvers for incompressible flow are employed that incorporate the k–ε and k–ω turbulence models respectively. The wind turbines (W/Ts) are modelled as momentum absorbers by means of their thrust coefficient using the actuator disk approach. The WT thrust is estimated
using the wind speed one diameter upstream of the rotor at hub height. An alternative method that employs an
induction-factor based concept is also tested. This method features the advantage of not utilizing the wind speed
at a specific distance from the rotor disk, which is a doubtful approximation when a W/T is located in the wake of another and/or the terrain is complex. To account
for the underestimation of the near wake deficit, a correction is introduced to the turbulence model. The turbulence time scale is bounded using the general “realizability” constraint for the turbulent velocities. Application is made on two wind farms, a five-machine one located in flat terrain and another 43-machine one
located in complex terrain. In the flat terrain case, the combination of the induction factor method along with the
turbulence correction provides satisfactory results. In the complex terrain case, there are some significant discrepancies with the measurements, which are discussed.
In this case, the induction factor method does not provide satisfactory results
CFD modelling of wind farms in complex terrain
Modelling of entire wind farms in flat and complex terrain using a full 3D Navier–Stokes solver for incompressible flow is presented in this paper. Numerical integration of the
governing equations is performed using an implicit pressure correction scheme, where the wind turbines (W/Ts) are modelled as momentum absorbers through their thrust
coefficient. The k–ω turbulence model, suitably modified for atmospheric flows, is employed for closure. A correction is
introduced to account for the underestimation of the near wake deficit, in which the turbulence time scale is bounded using a general “realizability” constraint for the
fluctuating velocities. The second modelling issue that is discussed in this paper is related to the determination of the reference wind speed for the thrust calculation of the
machines. Dealing with large wind farms and wind farms in complex terrain, determining the reference wind speed is not obvious when a W/T operates in the wake of another WT
and/or in complex terrain. Two alternatives are compared: using the wind speed value at hub height one diameter upstream of the W/T and adopting an induction factor-based
concept to overcome the utilization of a wind speed at a certain distance upwind of the rotor. Application is made in two wind farms, a five-machine one located in flat terrain and a 43-machine one located in complex terrain
Gas Holdup in a Trayed Cold-Flow Bubble Column
An Experimental Study Was Performed to Investigate the Effect of Sieve Trays on the Time-Averaged Gas Holdup Profiles and the overall Gas Holdup in a Cold-Flow Bubble Column that Was Scaled-Down from a Commercial Unit. Γ-Ray Computed Tomography (CT) Was Used to Scan the Column at Several Axial Locations in the Presence and Absence of Trays from Which the Local Variation of the Gas Holdup Was Extracted. the overall Gas Holdup Was Also Determined using the Same Configuration by Comparing the Expanded and Static Liquid Heights. Air and Water Were Used as the Gas-Liquid System. the Superficial Gas and Liquid Velocities Were Selected to Span the Range of the Commercial System using Gas Spargers Having Multiple Lateral Distributors that Were Also Scaled-Down from the Commercial Design. to Investigate the Impact of Sparger Hole Density on the Local and overall Gas Holdup, Two Difference Sparger Designs Were Used in Which the Hole Density Per Lateral Was Varied. the Gas Hole Velocity Was Maintained Constant at Ca. 245 M/s, Which Approached that Used in the Commercial Reactor. It is Shown that the Local Gas Holdup Determined by CT is Generally Higher in the Tray Down Comer Region and Exhibits an Asymmetric Pattern When Trays Are Present. the Use of Increased Sparger Hole Density at a Constant Gas Superficial Velocity Leads to Steeper Gradient in the Gas Holdup Near the Column Centerline and a Higher overall Gas Holdup. These Findings Suggest that the Performance of Bubble Column Reactors for Various Applications is Sensitive to Both Sparger and Tray Design. © 2001 Elsevier Science Ltd. All Rights Reserved
Flow and wakes in large wind farms in complex terrain and offshore
Power losses due to wind turbine wakes are of the order of 10 and 20% of total power output in large wind farms. The focus
of this research carried out within the EC funded UPWIND project is wind speed and turbulence modelling for large wind
farms/wind turbines in complex terrain and offshore in order to optimise wind farm layouts to reduce wake losses and loads
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