Optimal Design of a Hybrid System for a Reliable Load Supply in Remote Area

The power supply in remote areas has been usually provided by thermal power plants, usually diesel generators. Recently the use of renewable resources to generate electricity and protect the environment increased rapidly. Hybrid power systems may constitute the most economical solution in many applications in the near future, especially for electrification remote area. Hybrid systems by definition contain a two sources or more of power generation (or storing) to supply electricity to the loads. These sources may be pure traditional, traditional and renewable, or may be renewable only. This paper describes a case study for a remote area. It shows importance of using the hybrid system to electrify a remote area. The suggested hybrid system consists of wind turbine, PV, traditional generator, and batteries to supply a load (72 kWh/d). A real wind data related to Alsukhna near Homs is used. We perform a technical and economical analysis using Homer to determine the optimal design of a hybrid System for a Reliable Load Supply in Remote Area with least cost.

Optimization of the Design of Hexapod Platform

The main objective of this research is to present a study on the design optimization of the 6-RUS Stewart platform. The geometric and kinematic models are calculated and the singular positions are determined, then its translation and orientation workspace are determining. The direct geometric model of the studied platform was determined by using a proposed hybrid method.