Outline
- Abstract
- Index Terms
- 1 Introduction
- 2 Microturbine Generation (mtg) System
- 2.1 Types of Microturbine Systems
- 2.2 Basic Process and Components of a Mtg System
- 3 Mathematical Representation of a Microturbine
- 3.1 Speed and Acceleration Control
- 3.2 Fuel System
- 3.3 Compressor-Turbine
- 3.4 Temperature Control
- 4 Permanent Magnet Synchronous Generator (pmsg)
- 4.1 Permanent Magnet Materials
- 4.2 Operating Region of a Pmsm
- 4.3 Dq Axis Representation of a Pmsm
- 5 Simulation Results
- Conclusion
- References
رئوس مطالب
- چکیده
- کلمات کلیدی
- 1. مقدمه
- 2. سیستم تولید میکروتوربینی (MTG)
- 1.2. انواع سیستم های میکرو توربینی
- 2.2: فرآیند و اجزای پایه و اصلی یک سیستم MTG
- 3. نمایش ریاضی یک میکروتوربین
- 1.3: کنترل سرعت و شتاب
- 2.3: سیستم سوخت
- 3.3: کمپرسور و توربین
- 3.4: کنترل دما
- 4. ژنراتور سنکرون مغناطیس دائم (PMSG)
- 1.4: مواد مغناطیس دائم
- 2.4: ناحیه کاری یک PMSM
- 3.4: نمایش محور dq یک PMSM
- 5. نتایج شبیه سازی
- 6.نتیجه گیری
Abstract
In a hybrid energy system consisting of renewable sources of energy, there should be some storage facility or backup generation to maintain continuity of supply to the load when renewable source alone is not sufficient. The objective of this paper is to present one of such generating system that is capable of acting as a backup generator. This paper presents the modeling and simulation of a microturbine generation (MTG) system, the nonrenewable source of energy suitable for isolated as well as grid-connected operation. The system comprises of a permanent magnet synchronous generator driven by a microturbine. A brief description of the overall system is given and mathematical models for the microturbine and permanent magnet synchronous generator are presented. The developed models are simulated in MATLAB/Simulink.
Keywords: Acceleration control - compressor-turbine - fuel system - machine - microturbine generation system (MTG) - permanent magnet synchronous generator - temperature controlConclusions
The modeling of a single-shaft micro turbine generation system suitable for power management in DG applications is presented in this chapter. The model is good for both, power only and CHP applications. Detailed mathematical modeling of the control systems of the microturbine is given and simulation of the developed MTG system model is carried out. A MATLAB/Simulink model of the proposed MTG system was implemented in the SimPower Systems blockset. Different load conditions are applied on the MTG system. The simulation results show that the developed model of the MTG system has the ability to meet the power requirements of the load, within MTG’s rating.