TRAINING GAS TURBINE

TRAINING GAS TURBINE

TRAINING GAS TURBINE

A gas turbine extracts energy from a flow of hot gas produced by combustion of gas or fuel oil in a stream of compressed air. It has an upstream air compressor (radial or axial flow) mechanically coupled to a downstream turbine and a combustion chamber in between. “Gas turbine” may also refer to just the turbine element. Energy is released when compressed air is mixed with fuel and ignited in the combustor. The resulting gases are directed over the turbine’s blades, spinning the turbine, and mechanically powering the compressor. Finally, the gases are passed through a nozzle, generating additional thrust by accelerating the hot exhaust gases by expansion back to atmospheric pressure. Energy is extracted in the form of shaft power, compressed air and thrust, in any combination, and used to power aircraft, trains, ships, electrical generators, and even tanks.

 

• PENGERTIAN GAS TURBINE

Turbin gas atau mesin turbin gas , dengan nama lama turbin pembakaran internal , adalah jenis mesin pembakaran internal aliran kontinu

 

• MATERI GAS TURBINE

1. Overview of Gas Turbine Technology and Applications

• Simple cycle Gas Turbines; cycle considerations; applications; fuels and corrosion;

emissions; combined cycle and cogeneration. Overview of Developments

High temperature turbines, reheat turbines, close cycles, and other developments.

2. Rotating Components and Matching

• Brief overview of compressor and turbine design; component characteristics and

matching. Compressor surge and prevention.

3. Vibration and Rotor Dynamics

A review of vibration will include specific problems such as Blade Vibration and Shaft Critical

Speeds. Case histories will link vibration with the fatigue failure of components. Rotor

instability, in its various forms, will be discussed. Vibration spectrum analysis will be utilised

for the solution of resonance, instability, and gear and blade problems. Campbell (Spoke)

diagrams and Critical Speed maps will be derived and used for the solution of vibration and

Rotor Dynamic problems. The design and performance of Squeeze-Film Damper Bearings for

overcoming many of the problems associated with machine unbalance and critical speeds, will

be covered.

4. Combustors and Fuels

A description of combustor types, chamber design, fuel atomisation, ignition and combustor

arrangements will be presented. Also discussed will be the constraints imposed by fuels on the

design and operation of the hardware. The wide spectrum of fuels, both gaseous and liquid, is

examined. An overview of fuel treatment and additives will be made.

5. Performance Analysis

Basic thermodynamic aspects of stationary Gas Turbines. Design and off-design operation.

Influence of site effects on typical performance maps. Variable geometry compressor and

turbine status.

6. Performance Analysis for Problem Detection

The fundamental concepts of performance analysis as a tool for saving energy costs are

discussed. Basic and applied thermodynamics will be reviewed for gas turbines. The use of

performance data to pinpoint problem areas will be discussed. Diagnostics related to fouling,

nozzle erosion, bowing surge, choke, etc. will be covered. Meaningful trending methods will

also be discussed.

7. Gas Path Analysis for Stationary Gas Turbines – Status

Simulation of degraded Gas Turbines, derivation and application of fault coefficient matrix,

fault trees and other techniques. Implications for component life and emissions.

8. Gas Turbine Fouling

The causes, effects and detection of fouling in axial compressors will be covered including aero

thermodynamic effects, effects on surge margin, intake distortion and blading problems.

Filtration and control techniques will be covered.

9. Gas Turbine Repair

The techniques of inspection and repair of gas turbines are described in detail, including NDT

techniques, cleaning, plating, heat treatment, welding, etc.

10. Maintenance

Case histories of various types of failures and maintenance problems of onshore and offshore

gas turbine compressor installations are discussed. Maintenance techniques using bore scope

and spectrum analysis including acoustic monitoring are discussed. Techniques for checking

and conducting repairs on impellers, diffusers, bearings, couplings, and foundation repair are

emphasised.

11. Special Considerations for CHP Gas Turbines

This section will cover special considerations in design, operation and maintenance of turbines

and associated equipment on Cogeneration Services. Several cases will be covered. Off design

operation effects on HRSG, STTG Cycles and evaporate cooling will be covered.

• PELATIHAN ONLINE GAS TURBINE

Pelatihan tentang Gas Turbine ini sangat di perlukan untuk meningkatkan pengetahuan tentang migas cadangan di dasaran dengan baik dan mengetahui system yang harus digunakan dengan kualitas yang baik tanpa kesulitan. Pelatihan ini berlangsung selama 2 hari, pelaksananannya yang di mulai dari tanggal 05-06 Februari 2024 dari Perusahaan PT. Adikari Wisesa Indonesia yang merupakan Perusahaan yang berpacu dibidang minyak bumi yang diikuti dengan 1 peserta yang menggunakan fasilitas Zoom Meeting yang di laksanakan secara online. Training yang diselenggarakan oleh Berdiklat Training berjalan dengan lancar dan peserta juga dapat mengetahui tata cara menggunakan banyak contoh yang ditunjukkan melalui video yang di tampilkan saat pelatihan online agar memudahkan peserta dalam menerapkan didunia kerja.

Makan jika ingin melaksanakan atau memahami pelatihan tentang GaS Turbine ini Perusahaan harus memberikan arahan dan tujuan sebagai target pengembangan  diri untuk mengetahui tentang pelatihan Gas Turbine dengan mengujungi link Pelatihan Gas Turbine silahkan hubungi marketing training kami melalui WA 0812 2534 6564, 0853 2672 5665,0812 2534 6568