Simulation and Economic Analysis of a Hybrid Wind Diesel System for Remote Area Power Supply

Abdullah, Jalal

06 September 2010

The Kingdom of Saudi Arabia has an area of 1.69 million square kilometers. It is the biggest oil producers in the world, and the electricity industry relies heavily on oil. The annually growth request for electricity is around 5%. The price of electricity will be expensive in the next 30 years and there could be a shortage of electricity supply. It is better to use alternative forms of energy to prolong the life of the oil industry in Saudi Arabia. To reduce dependence on oil, the Kingdom of Saudi Arabia is considering using alternative sources of energy including solar energy and energy wind. Since the wind speed is around 10m/s and in the summer it is full of sunshine; therefore, the renewable energy should play a more important role in future electric power supply of the Kingdom of Saudi Arabia. A hybrid system is proposed in this thesis to study the possible power supply system in the remote areas. Wind information in Dhahran is used in simulations in order to make sure that the system is reliable and appropriate to be used in the remote areas of the country. Economic analysis is also conducted to compare the cost of the hybrid system with that of a 200 km transmission line connected from existing service area.

net present value

frequency

payback time

speed and voltage controller

NPV

Hybrid wind diesel system

MODELING AND SIMULATION OF A HYBRID WIND-DIESEL MICROGRID

Friedel, Vincent

January 2009

Some communities in remote locations with high wind velocities and an unreliable utility supply, will typically install small diesel powered generators and wind generators to form a microgrid. Over the past few years, microgrid projects have been developed in many parts of the world, and commercial solutions have started to appear. Such systems face specific design issues, especially when the wind penetration is high enough to affect the operation of the diesel plant. The dynamic behavior of a medium penetration hybrid microgrid is investigated. It consists of a diesel generator set, a wind-generator and several loads. The diesel engine drives a 62.5 kVA synchronous generator with excitation control. The fixed-speed wind turbine drives a 60 kW cage rotor induction generator. The microgrid can be connected to the utility grid but can also run as an isolated system. The total load of the microgrid is about 100 kVA which varies during the day, and consists of static and dynamic loads, including an induction motor. The excitation controller and speed controller for the diesel’s synchronous generator are designed, as well as the power control of the wind turbine, and the controller for capacitor banks and dump load. The system is modeled and simulated using PSCAD. The study evaluates how the power generation is shared between the diesel generator set and the wind generator, the voltage regulation during load connections, and discusses the need of battery energy storage, the system ride- through-fault capability and frequency control, particularly at times when the utility is disconnected and the microgrid is run as an independent isolated power system. The results of several case studies are presented.

Power Systems

Hybrid microgrid

Wind-Diesel system

PSCAD modeling

Elektroteknik och elektronik

Fuel consumption measurements and fuelconditioning in high-pressure fuel systemfor single cylinder test cell / Mätning av bränsleförbrukning och konditionering av bränsle i högtrycksbränslesystem för encylinderprovcell

Aksoy, Can Aksoy

January 2019

This master thesis is part of a bigger project issued by AVL with the purpose to design a high pressure compression ignition fuel system for their single cylinder test cell at their facility in Södertälje. Typically compression-ignition fuel tests are being run within an operating pressure range of 500-2400 bar, but this system has to be able to run with pressures up to 3500 bar. The project was intended to be carried out by two participants where this master thesis covers the evaluation of how fuel consumption rates shall be measured in the system described above as well as how the fuel shall be conditioned. The selected concept for measuring fuel consumption rate was based on measuring the mass flow on the low-pressure side of the system with a Coriolis flowmeter. The chosen temperature sensor for monitoring the temperature on the high-pressure side was a K-type thermocouple which would be directly connected to the fuel rail in the system. A bleeder was selected on the basis that it had been used in one of AVL's old test cells. A heat exchanger could not be chosen. However a rough estimation of the capacity needed for a heat exchanger was calculated for future reference. The methodology used to develop a concept was based on the engineering project process taught to students at Karlstad University. First a project plan was made followed by a solution-independently expressed product specification including a specification of requirements and QFD-matrix. Several concepts were generated for measuring the fuel consumption by evaluating different measuring principles, available components, possible positions of the components within the system and combinations with different fuel supply concepts. Less extensive methods were used for the remaining tasks in the detailed engineering phase of the project. The concepts were compared using Pugh's analysis and a concept was selected in collaboration with AVL. The majority of the objectives for this master thesis could be successfully carried out. The documentation and drawings requested by the client, manufacturing of the system, implementation and validation into the test cell could not be done due to lack of time. This, along with the selection of a heat exchanger and low-pressure thermocouple was left for future work.

fuel system

diesel system

single cylinder

engine test cell

test cell

high-pressure diesel

flow measurement

fuel consumption

fuel conditioning

Mechanical Engineering

Maskinteknik

Optimalizace rozhraní svařovaného zásobníku paliva systému common rail / Interface Optimization of Welded Fuel Accumulator of Common Rail System

Hurt, Libor

January 2009

This master’s thesis is aimed to sphere of injection system for diesel engines. The main task of thesis was to invent new concept for high pressure interface of laser welded fuel accumulator, that would able to endure pressure 2000 bars and higher. Also, it would be applicable to serial production. Thesis includes description of diesel system by Bosch, making of design proposals in ProEngineer program and making of stress analyses for some particular elements in Ansys. Whole the work was passed in conjunction with Bosch Diesel development department.