<?xml version="1.0" encoding="UTF-8"?><!DOCTYPE article  PUBLIC "-//NLM//DTD Journal Publishing DTD v3.0 20080202//EN" "http://dtd.nlm.nih.gov/publishing/3.0/journalpublishing3.dtd"><article xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink" dtd-version="3.0" xml:lang="en" article-type="research article"><front><journal-meta><journal-id journal-id-type="publisher-id">JPEE</journal-id><journal-title-group><journal-title>Journal of Power and Energy Engineering</journal-title></journal-title-group><issn pub-type="epub">2327-588X</issn><publisher><publisher-name>Scientific Research Publishing</publisher-name></publisher></journal-meta><article-meta><article-id pub-id-type="doi">10.4236/jpee.2016.45002</article-id><article-id pub-id-type="publisher-id">JPEE-66367</article-id><article-categories><subj-group subj-group-type="heading"><subject>Articles</subject></subj-group><subj-group subj-group-type="Discipline-v2"><subject>Engineering</subject></subj-group></article-categories><title-group><article-title>
 
 
  Advanced Cycles Large-Scale Aero-Derivative Gas Turbines: Performance Comparison
 
</article-title></title-group><contrib-group><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>arinyima</surname><given-names>Nkoi</given-names></name><xref ref-type="aff" rid="aff1"><sup>1</sup></xref></contrib><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>Thank</surname><given-names>God Ebi Isaiah</given-names></name><xref ref-type="aff" rid="aff2"><sup>2</sup></xref></contrib></contrib-group><aff id="aff2"><addr-line>Department of Mechanical Engineering, Niger Delta University, Wilberforce Island, Nigeria</addr-line></aff><aff id="aff1"><addr-line>Department of Mechanical Engineering, Rivers State University of Science and Technology, Port Harcourt, 
Nigeria</addr-line></aff><pub-date pub-type="epub"><day>10</day><month>05</month><year>2016</year></pub-date><volume>04</volume><issue>05</issue><fpage>7</fpage><lpage>19</lpage><history><date date-type="received"><day>2</day>	<month>April</month>	<year>2016</year></date><date date-type="rev-recd"><day>accepted</day>	<month>9</month>	<year>May</year>	</date><date date-type="accepted"><day>12</day>	<month>May</month>	<year>2016</year></date></history><permissions><copyright-statement>&#169; Copyright  2014 by authors and Scientific Research Publishing Inc. </copyright-statement><copyright-year>2014</copyright-year><license><license-p>This work is licensed under the Creative Commons Attribution International License (CC BY). http://creativecommons.org/licenses/by/4.0/</license-p></license></permissions><abstract><p>
 
 
  This paper aims at carrying out comparative performance analysis of simple and advanced cycles large-scale aero-derivative industrial gas turbines derived from aircraft turbofan engines. The investigation involves technical performances of three large-scale aero-derivative engine cycles based on existing and projected cycles for applications in land based power generation and Combined-Heat-and-Power (CHP). Preliminary design and performance simulation were implemented of a simple cycle (baseline) three-spool 100 MW aero-derivative engine model, intercooled and intercooled/recuperated engine cycles of the same 100 MW nominal power rating. In the analysis, design point and off-design performances of the engine models were established. The results indicate that to a large extent, the advanced engine cycles showed superior performance in terms of thermal efficiency, and fuel flow. In numerical terms, thermal efficiencies of intercooled engine cycle, and intercooled/recuperated engine cycles, over the simple cycle at design point increased by 2.42% and 0.94% respectively, whereas heat rates of these cycles over simple cycle at design point decreased by 2.37% and 0.93% respectively. It is worthy of note that for large-scale aero-derivative gas turbines having power rating of 100 MW and above, intercooled cycle would consume less fuel than intercooled-recuperated and simple cycles. This finding would actually aid good choice of cycle option for large-scale aero-derivative gas turbine designers, manufacturers and users.
 
</p></abstract><kwd-group><kwd>Aero-Derivative-Gas-Turbines</kwd><kwd> Thermal-Efficiency</kwd><kwd> Intercooled-Recuperated</kwd><kwd> Fuel-Flow</kwd><kwd> Heat-Rate</kwd></kwd-group></article-meta></front><body><sec id="s1"><title>1. Introduction</title><p>Aero-derivative industrial gas turbines (ADIGT) could be grouped into three categories namely: small-scale, medium-scale, and large-scale aero-derivatives, based on different ranges of power ratings. Small-scale ADIGT category can be defined as having the range of power rating from about 0.6 MW up to 5 MW. The range of power rating greater than 5 MW but up to 20 MW could be classified as medium-scale category. Large-scale category would be considered as the class having power rating above 20 MW [<xref ref-type="bibr" rid="scirp.66367-ref1">1</xref>] - [<xref ref-type="bibr" rid="scirp.66367-ref3">3</xref>] . As the name implies, aero-derivative industrial gas turbines (ADIGT) are gas turbines derived from aero-gas turbine engines by means of conversion. The decision to use aero-derivative gas turbines is mainly based on economical and operational advantages. Gas turbine manufacturers have found that to reduce cost of designing and developing new gas turbines, a more effective approach is to develop high performance industrial gas turbines by modifying aircraft gas turbine engines [<xref ref-type="bibr" rid="scirp.66367-ref4">4</xref>] [<xref ref-type="bibr" rid="scirp.66367-ref5">5</xref>] . Also, by introducing aero-derivative’s removable gas generator, better flexibility is provided which in turn leads to reducing maintenance operation and enhancing gas turbine availability in industrial applications [<xref ref-type="bibr" rid="scirp.66367-ref6">6</xref>] . More so, implementing aero-derivative technology for industrial gas turbine has resulted in low maintenance downtime, good part-load efficiencies and higher rate of return [<xref ref-type="bibr" rid="scirp.66367-ref4">4</xref>] - [<xref ref-type="bibr" rid="scirp.66367-ref7">7</xref>] .</p><p>It has been reported that the introduction of modern, high thrust aero-engines for aircraft propulsion has resulted in the development of a commensurate range of new high power, high efficiency ADIGT. This is illustrated for instance by the Rolls-Royce TRENT. The development of these large, efficient ADIGT offers particular chances for use in power generation and combined-heat-and-power plant [<xref ref-type="bibr" rid="scirp.66367-ref4">4</xref>] . ADIGT gives various advantages over their industrial design counterparts, in technology, project implementation and maintenance. Comparing performance, modern ADIGTs present a very efficient form of simple cycle energy conversion and this is exemplified in the TRENT GT. The high efficiency of the TRENT engine makes it a distinct choice for simple cycle application. With a state-of-the-art technology development from a modern aero-engine, fiscal studies have indicated that the high efficiency aero-derivative version exceedingly counterpoises for higher first cost that could be expected. Modern ADIGTs are also a feasible option for Combined-cycle-gas-turbine (CCGT) and CHP applications where power in the 60 - 120 MW class is anticipated. The TRENT GT, having a combined-cycle efficiency of about 51.5%, is one of the most competitive options available in its class. Modern ADIGT plants are an amply-embraced alternative for energy generation and this progression is expected to advance with the TRENT and future developments [<xref ref-type="bibr" rid="scirp.66367-ref3">3</xref>] - [<xref ref-type="bibr" rid="scirp.66367-ref8">8</xref>] .</p><p>Besides, another instance is the GE LM6000 aero-derivative gas turbine series which has undergone some new innovations in technology especially those in the 35 - 65 MW<sub>e</sub> range. The GE LM6000 has the latest innovations in the LM6000PG &amp; PH versions. These are denoted as the “PG” for the standard annular combustor (SAC) and “PH” for the dry low emissions (DLE) model. The improved technologies for these new products include new higher temperature alloys and improved cooling pattern to withstand high combustor outlet temperature, LP compressor operating at higher speed and increased mass flow, and higher pressure ratio. The GE LM6000 PG offers a 25% simple cycle power increase compared to the GE LM 2500, its predecessor, owing to advanced technology [<xref ref-type="bibr" rid="scirp.66367-ref9">9</xref>] . The advancement to the GE LM6000 gas turbine produces an 18% increase in the exhaust energy and 25% increase in power, and about 52% combined-cycle efficiency when incorporated into a 2- on-1 reference combined-cycle plant [<xref ref-type="bibr" rid="scirp.66367-ref9">9</xref>] .</p><p>More so, aero-derivative gas turbines can meet stringent NOx control requirements because they are suitable for power augmentation by steam injection. For instance, the GE LM series industrial aero-derivative gas turbines are meeting NOx requirements as low as 25 parts per million (ppm) using steam injection. Other merits of aero-derivative gas turbines include low weight-to-power ratio, compactness, and hence, lesser erection and startup time [<xref ref-type="bibr" rid="scirp.66367-ref10">10</xref>] [<xref ref-type="bibr" rid="scirp.66367-ref11">11</xref>] . More so, aero-derivative gas turbine are most suitable for highly efficient cogeneration plants, more flexible combined-cycle plants, and in mechanical drive applications for production and distribution of oil and gas [<xref ref-type="bibr" rid="scirp.66367-ref12">12</xref>] .</p><p>Using heat exchangers (both recuperators and intercoolers) in an engine exhibits tremendous potential to cut fuel consumption and thereby reducing CO<sub>2</sub> emissions. It was explained that the recuperator utilizes part of heat from the exhaust gas to raise the temperature of the air entering the combustor [<xref ref-type="bibr" rid="scirp.66367-ref13">13</xref>] . This method achieves the same turbine entry temperature as obtainable in conventional power plants but with the advantage of utilizing lesser fuel [<xref ref-type="bibr" rid="scirp.66367-ref13">13</xref>] . Besides, gas turbine user requirements have, over the years, necessitated technological advancement in engine performance, and comprehensive researches are being conducted to achieve this [<xref ref-type="bibr" rid="scirp.66367-ref14">14</xref>] [<xref ref-type="bibr" rid="scirp.66367-ref15">15</xref>] .</p><p>Technically, improvement of thermal efficiency for industrial and aero gas turbines is of paramount importance to the overall performance of the engines. Increase in thermal efficiency depends on certain factors including: Changes in some engine cycle parameters, such as overall pressure ratio (OPR), and turbine entry temperature (TET). Cutting-edge technology of engine components like methods of cooling, efficiencies of components, ducts pressure losses, and introduction of different overall thermodynamic cycle, for example, use of unconventional components like intercoolers and regenerators or recuperators [<xref ref-type="bibr" rid="scirp.66367-ref5">5</xref>] [<xref ref-type="bibr" rid="scirp.66367-ref16">16</xref>] . More so, performance and economic viability of gas turbines are inseparable [<xref ref-type="bibr" rid="scirp.66367-ref15">15</xref>] .</p><p>The aim of this paper is to compare the technical performances of large-scale aero-derivative industrial gas turbines. The investigation encompasses comparative assessment of simple (SC), intercooled (IC), and intercooled/recuperated (ICR) cycle options. This sort of analysis would surely aid good choice of engine cycle options in the category of large-scale aero-derivative land based gas turbines. GE Power has developed, manufactured and deployed 100 MW large-scale intercooled aero-derivative gas turbine in the LMS100 series [<xref ref-type="bibr" rid="scirp.66367-ref17">17</xref>] , however, this research introduces analysis of a 100 MW intercooled-recuperated aero-derivative gas turbine and a counterpart simple cycle version. Hence, this research has the advantage of providing wider range of cycle options in this category of aero-derivative gas turbines.</p></sec><sec id="s2"><title>2. Materials and Methods</title><sec id="s2_1"><title>2.1. Design Point Performance (DP)</title><p>The Design Point of a gas turbine could be defined as the very condition in the operating range of a gas turbine when the engine is running at the very mass flow, speed, and pressure ratio for which the components were designed [<xref ref-type="bibr" rid="scirp.66367-ref18">18</xref>] . In establishing the design point of the engine, pressure ratio and TET that results in an overall highest thermal efficiency are normally determined from preliminary cycle calculations. After this is done, other appropriate design parameters of the gas turbine system may be allotted. Then, detail design of different engine components can be done in order to provide the specified requirements of the complete system when operating at the DP. There are many requirements from a gas turbine engine. These may be referred to as design priorities, and always these requirements are in conflict. The design of the engine is greatly influenced by a set of these priorities depending on the engine application [<xref ref-type="bibr" rid="scirp.66367-ref5">5</xref>] [<xref ref-type="bibr" rid="scirp.66367-ref15">15</xref>] [<xref ref-type="bibr" rid="scirp.66367-ref19">19</xref>] [<xref ref-type="bibr" rid="scirp.66367-ref20">20</xref>] .</p></sec><sec id="s2_2"><title>2.2. Off-Design Performance (OD)</title><p>Besides the DP performance of the gas turbine, it is mandatory to ascertain its general performance over the entire operating range of power output and speed. This is known as Off-Design (OD) performance [<xref ref-type="bibr" rid="scirp.66367-ref18">18</xref>] . Component characteristics as indicated by component maps of compressor, turbine, and combustor, are very useful in ascertaining off-design behaviour of the gas turbine system. At steady state operation of the engine, corresponding operating points on the component maps are matched and can be plotted on the compressor characteristic diagram to form an equilibrium running line [<xref ref-type="bibr" rid="scirp.66367-ref20">20</xref>] .</p><p>Various performance plots of power output, specific fuel consumption (sfc), thrust, specific thrust or power, etc could be made once the operating conditions of an engine have been determined. It is important to note that off-design performance is very much affected by factors such as ambient conditions of temperature and pressure, altitudes, flight speed (for aero engines), etc. The off-design performance analysis is normally achieved by the use of computer model simulations of engines [<xref ref-type="bibr" rid="scirp.66367-ref20">20</xref>] [<xref ref-type="bibr" rid="scirp.66367-ref21">21</xref>] .</p></sec><sec id="s2_3"><title>2.3. TURBOMATCH</title><p>Engine components operating point matching to establish OD performance is normally a tedious and time consuming task since it is an iterative process. Computer based simulation is normally employed to accomplish the task. TURBOMATCH is an in-house gas turbine engine performance software developed and established at Cranfield University (CU). It is employed to simulate the DP and OD performances of a broad range of aero and industrial gas turbines. Simple single shaft engines, complex multi-spool engines, as well as novel cycle engine configurations can be modelled adequately using the scheme [<xref ref-type="bibr" rid="scirp.66367-ref15">15</xref>] - [<xref ref-type="bibr" rid="scirp.66367-ref16">16</xref>] [<xref ref-type="bibr" rid="scirp.66367-ref18">18</xref>] - [<xref ref-type="bibr" rid="scirp.66367-ref20">20</xref>] .</p><p>In the scheme, different engine components (intake, compressor, combustor, turbine, nozzle, etc) are repre- sented by bricks (building blocks of the programme). These bricks are pre-programmed routines deployed to simulate, on a modular basis, the performance of the various engine components they represent. The cycle thermal efficiency, specific fuel consumption, power, or thrust of the engine, etc. are essential performance output parameters that are obtained as desired results of the simulation. Besides these overall cycle results, individual component performance characteristics, and the working-fluid properties at various stations within the engine are also outputted [<xref ref-type="bibr" rid="scirp.66367-ref15">15</xref>] [<xref ref-type="bibr" rid="scirp.66367-ref18">18</xref>] [<xref ref-type="bibr" rid="scirp.66367-ref22">22</xref>] [<xref ref-type="bibr" rid="scirp.66367-ref23">23</xref>] .</p></sec><sec id="s2_4"><title>2.4. Simple Cycle Three-Spool Turboshaft Engine with Free Power Turbine</title><p>In this paper, three-spool turboshaft engine with a free power turbine (FPT) was considered in which a high pressure compressor (HPC) is driven by the high pressure turbine (HPT) and a low pressure compressor (LPC) is driven by an intermediary low pressure turbine (IPT). The schematic representation of such engine is shown in <xref ref-type="fig" rid="fig1">Figure 1</xref> indicating station numbers.</p><p>The T-S diagram of the simple cycle is shown in <xref ref-type="fig" rid="fig2">Figure 2</xref> considering isentropic efficiencies of compressors and turbines. With the notations of <xref ref-type="fig" rid="fig1">Figure 1</xref> and <xref ref-type="fig" rid="fig2">Figure 2</xref>, and applying steady flow energy equation, heat flow into the cycle in the combustion chamber (process 4 - 5) per unit air mass flow is given by Equation (1).</p><disp-formula id="scirp.66367-formula297"><label>(1)</label><graphic position="anchor" xlink:href="http://html.scirp.org/file/2-1770226x7.png"  xlink:type="simple"/></disp-formula><p>where c<sub>pi</sub> is the specific heat capacity at constant pressure, which varies with temperature at the given engine component station i.i represents engine station numbers 1, 2, 3, 4, 5, 6 etc.</p><p>Heat rejected at constant pressure (process 8 - 2) in the exhaust is given by Equation (2).</p><disp-formula id="scirp.66367-formula298"><label>(2)</label><graphic position="anchor" xlink:href="http://html.scirp.org/file/2-1770226x8.png"  xlink:type="simple"/></disp-formula><fig id="fig1"  position="float"><label><xref ref-type="fig" rid="fig1">Figure 1</xref></label><caption><title> Schematics of a three-spool turboshaft engine with free power turbine</title></caption><graphic mimetype="image"   position="float"  xlink:type="simple"  xlink:href="http://html.scirp.org/file/2-1770226x9.png"/></fig><fig id="fig2"  position="float"><label><xref ref-type="fig" rid="fig2">Figure 2</xref></label><caption><title> T-S diagram of actual simple cycle three-spool turboshaft gas turbine</title></caption><graphic mimetype="image"   position="float"  xlink:type="simple"  xlink:href="http://html.scirp.org/file/2-1770226x10.png"/></fig><p>Equation (3) or Equation (4) gives the total compressor work (CW) (process 2-3-4) per unit air mass flow, where process 2 - 3 occur in the LPC and process 3 - 4 occur in the HPC.</p><disp-formula id="scirp.66367-formula299"><label>(3)</label><graphic position="anchor" xlink:href="http://html.scirp.org/file/2-1770226x11.png"  xlink:type="simple"/></disp-formula><disp-formula id="scirp.66367-formula300"><label>(4)</label><graphic position="anchor" xlink:href="http://html.scirp.org/file/2-1770226x12.png"  xlink:type="simple"/></disp-formula><p>High pressure turbine work (HPTW) (process 5 - 6) per unit air mass flow is defined by Equation (5).</p><disp-formula id="scirp.66367-formula301"><label>(5)</label><graphic position="anchor" xlink:href="http://html.scirp.org/file/2-1770226x13.png"  xlink:type="simple"/></disp-formula><p>Intermediary pressure turbine work (IPTW) (process 6 - 7) given by Equation (6)</p><disp-formula id="scirp.66367-formula302"><label>(6)</label><graphic position="anchor" xlink:href="http://html.scirp.org/file/2-1770226x14.png"  xlink:type="simple"/></disp-formula><p>Free power turbine work (FPTW) (process 7 - 8) given by Equation (7)</p><disp-formula id="scirp.66367-formula303"><label>(7)</label><graphic position="anchor" xlink:href="http://html.scirp.org/file/2-1770226x15.png"  xlink:type="simple"/></disp-formula><p>This implies that total expansion work (EW) is obtained as stated in Equation (8)</p><disp-formula id="scirp.66367-formula304"><graphic  xlink:href="http://html.scirp.org/file/2-1770226x16.png"  xlink:type="simple"/></disp-formula><disp-formula id="scirp.66367-formula305"><label>(8)</label><graphic position="anchor" xlink:href="http://html.scirp.org/file/2-1770226x17.png"  xlink:type="simple"/></disp-formula><p>The thermal efficiency is calculated using Equation (9) below.</p><p><inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/2-1770226x18.png" xlink:type="simple"/></inline-formula> (9) [<xref ref-type="bibr" rid="scirp.66367-ref19">19</xref>]</p></sec><sec id="s2_5"><title>2.5. Modifications to the Simple Cycle</title><p>To increase the efficiencies of the simple-cycle, unconventional components are added to the cycle. These components include intercoolers, regenerators (recuperators), or reheaters. However, the initial and maintenance costs of the cycle may increase due to these additional components. The improvements in cycle performance brought about by these components can only be justified if the decrease in fuel costs offsets the increase in other costs. There is the general urge to reduce fuel consumption in gas turbine operation [<xref ref-type="bibr" rid="scirp.66367-ref24">24</xref>] . This is achieved by the introduction of these modifications to the simple cycle. The descriptions of these modifications are outlined below [<xref ref-type="bibr" rid="scirp.66367-ref15">15</xref>] .</p><sec id="s2_5_1"><title>2.5.1. Intercooled Cycle</title><p>Incorporating an intercooler between the LPC and HPC of the simple cycle engine in section 2.4 such that air leaving the LPC is cooled before entering the HPC, results in an intercooled cycle. Intercooling reduces the total compressor work, thereby, increasing useful work output, turbine work remaining the same [<xref ref-type="bibr" rid="scirp.66367-ref5">5</xref>] . Also, intercooling will increase the specific work of the cycle, increase heat input from combustor, and thus fuel consumption will rise [<xref ref-type="bibr" rid="scirp.66367-ref25">25</xref>] . The T-S diagram of the intercooled three-spool engine cycle is shown in <xref ref-type="fig" rid="fig3">Figure 3</xref>.</p></sec><sec id="s2_5_2"><title>2.5.2. Intercooled/Recuperated Cycle</title><p>Incorporating a recuperator between the outlet of the HPC and outlet of the LPT of the intercooled engine in section 2.5.1 such that air leaving the HPC is heated before entering the burner, results in an intercooled/recup- erated cycle. The recuperator or regenerator is a heat exchanger connected between the turbine exhaust and the compressor exit. The thermal efficiency of the cycle increases due to recuperation because the portion of heat in the exhaust gases that is supposedly wasted by flaring is now utilised to preheat the air at the exit to the compressor. This, in effect, reduces the heat gain from burning fuel, and hence, decreases fuel consumption for same power output. However, if the compressor outlet temperature is equal or higher than the turbine exhaust temperature, the use of a regenerator is not recommended. Else, there will be a reversal of heat flow to the exhaust gases, causing the efficiency to decrease. Very high pressure ratios in gas-turbine engines could cause this adverse</p><fig id="fig3"  position="float"><label><xref ref-type="fig" rid="fig3">Figure 3</xref></label><caption><title> T-S diagram of actual intercooled cycle three-spool gas turbine</title></caption><graphic mimetype="image"   position="float"  xlink:type="simple"  xlink:href="http://html.scirp.org/file/2-1770226x19.png"/></fig><p>situation [<xref ref-type="bibr" rid="scirp.66367-ref15">15</xref>] . However, the intercooler effect of reducing thermal efficiency is compensated by recuperation effect in ICR. The T-S diagram for the cycle with both intercooling and recuperation is shown in <xref ref-type="fig" rid="fig4">Figure 4</xref>, where process 9-10-11 is recuperation (regeneration).</p><p>Referring to the cycle in <xref ref-type="fig" rid="fig4">Figure 4</xref>, T<sub>9</sub> is the maximum temperature that can occur within the recuperator which is the temperature of the exhaust gases entering the recuperator and leaving the turbine. Air in the regenerator (recuperator) can only be preheated to a temperature below T<sub>9</sub>, and air will normally exit the regenerator at T<sub>10</sub>, a lower temperature [<xref ref-type="bibr" rid="scirp.66367-ref15">15</xref>] [<xref ref-type="bibr" rid="scirp.66367-ref26">26</xref>] .</p><p>Using the station numbering and notations in the T-S diagram of <xref ref-type="fig" rid="fig4">Figure 4</xref>.</p><p>The heat input per unit air mass flow here is given by Equation (10).</p><disp-formula id="scirp.66367-formula306"><label>(10)</label><graphic position="anchor" xlink:href="http://html.scirp.org/file/2-1770226x20.png"  xlink:type="simple"/></disp-formula><p>Here, compressor work is given by Equation (11), and Equation (12) gives the expansion work.</p><disp-formula id="scirp.66367-formula307"><graphic  xlink:href="http://html.scirp.org/file/2-1770226x21.png"  xlink:type="simple"/></disp-formula><disp-formula id="scirp.66367-formula308"><label>(11)</label><graphic position="anchor" xlink:href="http://html.scirp.org/file/2-1770226x22.png"  xlink:type="simple"/></disp-formula><disp-formula id="scirp.66367-formula309"><label>(12)</label><graphic position="anchor" xlink:href="http://html.scirp.org/file/2-1770226x23.png"  xlink:type="simple"/></disp-formula><p>Equation (13) calculates the thermal efficiency in this case with reference to Equation (11) and Equation (12).</p><disp-formula id="scirp.66367-formula310"><label>(13)</label><graphic position="anchor" xlink:href="http://html.scirp.org/file/2-1770226x24.png"  xlink:type="simple"/></disp-formula><p>TURBOMATCH code is capable of computing engine performance parameters using thermodynamic relations and models, considering variations of properties of working fluid at different conditions of pressure and temperature [<xref ref-type="bibr" rid="scirp.66367-ref21">21</xref>] - [<xref ref-type="bibr" rid="scirp.66367-ref23">23</xref>] .</p></sec></sec></sec><sec id="s3"><title>3. Analysis and Results</title><sec id="s3_1"><title>3.1. Simple Cycle Three-Spool Aero-Derivative Gas Turbine (Base-Line Engine Core)</title><p>For the engine model, a simple cycle three-spool engine inspired by the aero-derivative GE LMS100 core is chosen as the baseline engine. The LMS100 turbine has a free power turbine (FPT), an intermediary turbine (IPT) that drives the LPC, and an intercooler. With an overall compression ratio of 42:1, it has an annular combustor equipped with dry low emission (DLE) technology, and an air-cooled HPT which drives the HPC. The LMS100 was derived from the LM6000 by the addition of the intercooler and free power turbine delivering an</p><fig id="fig4"  position="float"><label><xref ref-type="fig" rid="fig4">Figure 4</xref></label><caption><title> T-S Diagram of actual intercooled-recuperated 3-spool gas turbine cycle</title></caption><graphic mimetype="image"   position="float"  xlink:type="simple"  xlink:href="http://html.scirp.org/file/2-1770226x25.png"/></fig><p>output power of about 100 MW [<xref ref-type="bibr" rid="scirp.66367-ref17">17</xref>] .</p><p>It should be understood that the design point of the inspiring engine core is proprietary information of the original equipment manufacturer (OEM), and as such, the design point is reasonably chosen by engineering judgment. This is because some key defining parameters of the DP like the turbine entry temperature (TET), etc. are not usually disclosed by the OEM [<xref ref-type="bibr" rid="scirp.66367-ref15">15</xref>] [<xref ref-type="bibr" rid="scirp.66367-ref27">27</xref>] . Based on this fact, and due to availability of data, international standard atmosphere (ISA)-sea level static (SLS) was chosen as the design point with the adoption of U.S.A.F. standard for pressure recovery at intake.</p><p>The engine components were modelled in TURBOMATCH bricks shown in <xref ref-type="fig" rid="fig5">Figure 5</xref>. The DP was chosen as ISA SLS condition of 100 MW output power. The isentropic efficiencies of both the LPC and HPC were assumed to be 0.875, with a surge margin of 0.80. The design pressure ratios of the LPC and HPC are 3.0 and 14.05 respectively, giving an overall pressure ratio of about 42.15:1. The LPC is driven by LP spool of the IPT and the HPC is driven by the HP spool of the HPT. The turbine entry temperature was assumed to be 1730 K and taken as the engine handle for the simulation, while the air mass flow was set at 215.5 kg/s with 8.0% mass bleed for cooling of the compressor turbines inlet blades. A combustion chamber pressure loss of 5% of the HPC delivery pressure was allowed whereas the combustor efficiency of 0.998 was assumed. The isentropic efficiency of the HPT and the IPT were taken to be 0.89, and that of the free power turbine was set at 0.90. Default non- dimensional speed of 0.6, and a non-dimensional mass flow of 0.8, were used. The simulation results were generated, and summarized in <xref ref-type="table" rid="table1">Table 1</xref>.</p></sec><sec id="s3_2"><title>3.2. Design Point Performance of Intercooled Three-Spool Large-Scale-ADIGT Engine</title><p>The simple cycle LS-ADIGT engine described in section 3.1 is modified by introducing an intercooler between the LP and HP compressors. While retaining component efficiencies, TET, and inlet mass flow, the air leaving the LP compressor is cooled to a temperature of 320˚C, with intercooler effectiveness of 30%, and intercooler pressure loss of 3% of LPC delivery pressure. However, a mass bleed totaling 27% of intake air mass flow is channeled for both HPT and IPT inlet blades cooling. The intercooled engine arrangement is shown in <xref ref-type="fig" rid="fig6">Figure 6</xref> in TURBOMATCH bricks, and the DP performance results are summarized in <xref ref-type="table" rid="table1">Table 1</xref>.</p></sec><sec id="s3_3"><title>3.3. Design Point Performance of ICR Three-Spool LS2-ADIGT Engine</title><p>The intercooled/recuperated three-spool large-scale aero-derivative engine components in TURBOMATCH bricks is shown in <xref ref-type="fig" rid="fig7">Figure 7</xref>. The core engine parameters of the intercooled LS-ADIGT described in section 3.2</p><fig id="fig5"  position="float"><label><xref ref-type="fig" rid="fig5">Figure 5</xref></label><caption><title> Simple cycle 3-spool Large-scale-ADIGT engine components in TURBOMATCH bricks (inspired by GE LMS100 core)</title></caption><graphic mimetype="image"   position="float"  xlink:type="simple"  xlink:href="http://html.scirp.org/file/2-1770226x26.png"/></fig><fig id="fig6"  position="float"><label><xref ref-type="fig" rid="fig6">Figure 6</xref></label><caption><title> Intercooled 3-spool LS2-ADIGT engine components in TURBOMATCH bricks (inspired by GE LMS100 core)</title></caption><graphic mimetype="image"   position="float"  xlink:type="simple"  xlink:href="http://html.scirp.org/file/2-1770226x27.png"/></fig><table-wrap id="table1" ><label><xref ref-type="table" rid="table1">Table 1</xref></label><caption><title> Summary of DP performance results of the LS2-ADIGT engines simulation</title></caption><table><tbody><thead><tr><th align="center" valign="middle"  rowspan="2"  >Performance parameter</th><th align="center" valign="middle"  colspan="3"  >Value at DP of simulated three-spool LS2-ADIGT engines</th></tr></thead><tr><td align="center" valign="middle" >Simple cycle</td><td align="center" valign="middle" >Intercooled</td><td align="center" valign="middle" >ICR</td></tr><tr><td align="center" valign="middle" >Power turbine rating (kW)</td><td align="center" valign="middle" >100,000</td><td align="center" valign="middle" >100,000</td><td align="center" valign="middle" >100,000</td></tr><tr><td align="center" valign="middle" >Inlet mass flow (kg/s)</td><td align="center" valign="middle" >215.5</td><td align="center" valign="middle" >215.5</td><td align="center" valign="middle" >215.5</td></tr><tr><td align="center" valign="middle" >Exhaust mass flow (kg/s)</td><td align="center" valign="middle" >220.59</td><td align="center" valign="middle" >220.47</td><td align="center" valign="middle" >220.54</td></tr><tr><td align="center" valign="middle" >Fuel flow (kg/s)</td><td align="center" valign="middle" >5.09</td><td align="center" valign="middle" >4.97</td><td align="center" valign="middle" >5.04</td></tr><tr><td align="center" valign="middle" >Exhaust gas temperature (K)</td><td align="center" valign="middle" >783</td><td align="center" valign="middle" >692</td><td align="center" valign="middle" >690</td></tr><tr><td align="center" valign="middle" >Overall compression pressure ratio</td><td align="center" valign="middle" >42.15:1</td><td align="center" valign="middle" >42.15:1</td><td align="center" valign="middle" >42.15:1</td></tr><tr><td align="center" valign="middle" >Thermal efficiency</td><td align="center" valign="middle" >0.457</td><td align="center" valign="middle" >0.467</td><td align="center" valign="middle" >0.460</td></tr></tbody></table></table-wrap><fig id="fig7"  position="float"><label><xref ref-type="fig" rid="fig7">Figure 7</xref></label><caption><title> Intercooled/recuperated 3-spool LS2-ADIGT engine components in TURBOMATCH bricks (inspired by GE LMS100 core)</title></caption><graphic mimetype="image"   position="float"  xlink:type="simple"  xlink:href="http://html.scirp.org/file/2-1770226x28.png"/></fig><p>are retained except for the inclusion of a recuperator of 75% effectiveness, with cold side and hot side pressure losses of 1% and 2% respectively, of the inlet pressure, and 2% mass leakage. The inlet mass flow remains 215.5 kg/s with a total of 27.4% bleed for both HPT and IPT inlet blades cooling. Also, keeping ISA SLS as design point, the engine was simulated and the summary of its DP performance shown in <xref ref-type="table" rid="table1">Table 1</xref>.</p></sec><sec id="s3_4"><title>3.4. Verification of Performance Results of Base Engine LS-ADIGT</title><p>To verify the results of performance parameters of the simulated baseline engine, comparison is made with public domain source reference data of LMS100. This is shown in <xref ref-type="table" rid="table2">Table 2</xref>.</p><p>By the use of component maps in TURBOMATCH codes, the off-design performances of the SS-ADIGT engines were simulated and the variation of some key engine output parameters were plotted and presented in <xref ref-type="fig" rid="fig8">Figure 8</xref> and <xref ref-type="fig" rid="fig9">Figure 9</xref>.</p><p>With reference to the simulation results shown in <xref ref-type="table" rid="table1">Table 1</xref> and plots of <xref ref-type="fig" rid="fig8">Figure 8</xref> and <xref ref-type="fig" rid="fig9">Figure 9</xref>, it could be observed that for the LS2-ADIGT the intercooled, and intercooled/recuperated, engines have increased thermal efficiency, compared to the simple cycle engine at both DP and off-design point. This is because the intercooler decreases the temperature of the air entering the HP compressor and as such reduces the HP compressor work. Similarly, recuperator increases the temperature of air entering the combustor to reduce the quantity of heat flow required from burning fuel by heat-exchange action with stream of exhaust gas. The ICR cycle combines both advantages of intercooling and heat-exchange discussed above to achieve increased thermal efficiency. In the same vein, heat rate is reduced in the advanced cycles compared to the simple cycle.</p><p>In <xref ref-type="fig" rid="fig1">Figure 1</xref>0, the percentage increases at DP in thermal efficiency of the advanced cycle engines over the simple cycle engine are shown.</p><p>The negative sign on the heat rates in <xref ref-type="fig" rid="fig1">Figure 1</xref>0 indicate percentage reduction in heat rate of advanced cycles over simple cycle. Of course increase in thermal efficiency is accompanied with corresponding decrease in heat rate for the ADIGT engines. The thermal efficiencies of intercooled engine cycle, and intercooled/recuperated engine cycles, over the simple cycle at design point increased by 2.42%, and 0.94% respectively, whereas heat rates of these cycles over simple cycle at design point decreased by 2.37%, and 0.93% respectively.</p><fig id="fig8"  position="float"><label><xref ref-type="fig" rid="fig8">Figure 8</xref></label><caption><title> Variation of thermal efficiency with TET at ISA SLS (LS2-ADIGT)</title></caption><graphic mimetype="image"   position="float"  xlink:type="simple"  xlink:href="http://html.scirp.org/file/2-1770226x29.png"/></fig><fig id="fig9"  position="float"><label><xref ref-type="fig" rid="fig9">Figure 9</xref></label><caption><title> Thermal efficiency varying with shaft power at ISA SLS (LS2-ADIGT)</title></caption><graphic mimetype="image"   position="float"  xlink:type="simple"  xlink:href="http://html.scirp.org/file/2-1770226x30.png"/></fig><fig id="fig10"  position="float"><label><xref ref-type="fig" rid="fig1">Figure 1</xref>0</label><caption><title> Percentage change in performance parameters of IC and ICR cycles over simple cycle for the LS2-ADIGT engines</title></caption><graphic mimetype="image"   position="float"  xlink:type="simple"  xlink:href="http://html.scirp.org/file/2-1770226x31.png"/></fig><p>However, it is important to note that though the thermal efficiency is improved by using the advanced cycles, the incorporation of intercoolers and recuperators would make the engine more complex. This would increase the capital and maintenance cost actually, but cost of fuel would reduce due to reduction in heat rate and fuel consumption.</p><p>These results compare favorably with values obtained in the literature. For instance, it was reported that the 1.4 MW intercooled/recuperated Heron-1 turbo-shaft gas turbine manufactured by EECT of the Netherland exhibits thermal efficiency of 42.9% while a simple cycle gas turbine of same power range has thermal efficiency</p><table-wrap id="table2" ><label><xref ref-type="table" rid="table2">Table 2</xref></label><caption><title> Verifying performance results of simulated LS2-ADIGT engine</title></caption><table><tbody><thead><tr><th align="center" valign="middle"  rowspan="2"  >Performance parameter</th><th align="center" valign="middle"  colspan="4"  >Value at ISA SLS</th></tr></thead><tr><td align="center" valign="middle" >Inspiring core LMS100</td><td align="center" valign="middle" >Simulated baseline engine</td><td align="center" valign="middle" >Variation</td><td align="center" valign="middle" >% variation</td></tr><tr><td align="center" valign="middle" >Power turbine rating</td><td align="center" valign="middle" >100,000 kW</td><td align="center" valign="middle" >100,000 kW</td><td align="center" valign="middle" >0.00</td><td align="center" valign="middle" >0.00</td></tr><tr><td align="center" valign="middle" >Inlet mass flow</td><td align="center" valign="middle" >N/A</td><td align="center" valign="middle" >215.5 kg/s</td><td align="center" valign="middle" >-</td><td align="center" valign="middle" >-</td></tr><tr><td align="center" valign="middle" >Exhaust mass flow</td><td align="center" valign="middle" >220 kg/s</td><td align="center" valign="middle" >220.47 kg/s</td><td align="center" valign="middle" >−0.47</td><td align="center" valign="middle" >−0.21</td></tr><tr><td align="center" valign="middle" >Fuel flow</td><td align="center" valign="middle" >N/A</td><td align="center" valign="middle" >4.97 kg/s</td><td align="center" valign="middle" >-</td><td align="center" valign="middle" >-</td></tr><tr><td align="center" valign="middle" >Exhaust gas temperature</td><td align="center" valign="middle" >686 K</td><td align="center" valign="middle" >692 K</td><td align="center" valign="middle" >−6</td><td align="center" valign="middle" >−0.87</td></tr><tr><td align="center" valign="middle" >Overall pressure ratio</td><td align="center" valign="middle" >42.00:1</td><td align="center" valign="middle" >42.15:1</td><td align="center" valign="middle" >−0.15</td><td align="center" valign="middle" >−0.36</td></tr><tr><td align="center" valign="middle" >Thermal efficiency</td><td align="center" valign="middle" >0.440</td><td align="center" valign="middle" >0.467</td><td align="center" valign="middle" >−0.027</td><td align="center" valign="middle" >−6.1</td></tr></tbody></table></table-wrap><p>of about 26% - 34%. This represents a thermal efficiency increase of about 26.2% at the minimum [<xref ref-type="bibr" rid="scirp.66367-ref27">27</xref>] . More so, percentage increases were reported of thermal efficiencies of recuperated engine cycle, and intercooled/recupe- rated engine cycle, over simple cycle of a turbo-shaft engine at DP as 20.6%, and 24.2% respectively, whereas percentage reduction in specific fuel consumption of these cycles over simple cycle at DP as 17.3%, and 21.1% respectively [<xref ref-type="bibr" rid="scirp.66367-ref15">15</xref>] . Similarly, It was found that thermal efficiencies of recuperated engine cycle, and intercooled/recuperated engine cycles, over the simple cycle at DP increased by 13.5%, and 14.5% respectively, whereas percentage reduction in specific fuel consumption of these cycles over simple cycle at DP as 12.5%, and 13% respectively [<xref ref-type="bibr" rid="scirp.66367-ref20">20</xref>] .</p></sec></sec><sec id="s4"><title>4. Conclusion</title><p>Performance simulation of a simple cycle (baseline), IC and ICR three-spool large-scale aero-derivative industrial gas turbine derived from turbofan engine has been implemented. In doing so, design and off-design point performances of the engine models were established. It is found that the IC and ICR cycles exhibit better thermal efficiency than the simple engine. Similarly, heat rate in combustor is reduced in the advanced cycles than the simple engine. It is, however, worthy of note that for large-scale aero-derivative gas turbines having power rating of 100 MW and above, intercooled cycle would consume less fuel than intercooled-recuperated and simple cycles. This finding would actually aid good choice of cycle option for large-scale aero-derivative gas turbine designers, manufacturers and users.</p></sec><sec id="s5"><title>Acknowledgements</title><p>The authors would like to thank Prof. Pericles Pilidis and Dr. Theoklis Nikolaidis of the Department of Power and Propulsion of Cranfield University United Kingdom for their valuable contributions.</p></sec><sec id="s6"><title>Cite this paper</title><p>Barinyima Nkoi,Thank God Ebi Isaiah, (2016) Advanced Cycles Large-Scale Aero-Derivative Gas Turbines: Performance Comparison. Journal of Power and Energy Engineering,04,7-19. doi: 10.4236/jpee.2016.45002</p></sec><sec id="s7"><title>Nomenclature</title></sec><sec id="s8"><title>NOTES</title></sec></body><back><ref-list><title>References</title><ref id="scirp.66367-ref1"><label>1</label><mixed-citation publication-type="other" xlink:type="simple">Major, B. and Powers, B. 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