Technical paper by A. Carlos Fernandez-Pello, Sang-Won Park, Albert P. Pisano, S. Bennett Sprague, + David C. Walther
UoC Berkeley, 2007, 19 pages
> Content
> Abstract + keywords 1
> Reference + biographical notes 1
> 1 Introduction 2
> 2 Background 3
» 2.1 Characteristic times of combustion 3
» 2.2 Heat transfer 4
» 2.3 Flame quenching 4
» 2.4 Mixing + turbulence 5
» 2.5 Sealing 5
> 3 Small-scale rotary engine designs 6
» 3.1 Peripheral ported P78 engine 6
» 3.2 Peripheral ported P348 engine 7
» 3.3 Side-ported S367 engine 8
» 3.4 Side-ported S1500 engine 9
> 4 Test apparatus 9
> 5 Experimental results 11
» 5.1 P78 peripheral ported engine 12
» 5.2 P348 peripheral ported engine 12
» 5.3 S367 side-ported engine 13
» 5.4 S1500 side-ported engine 14
> 6 Discussion 15
» 6.1 Effect of engine seals 15
» 6.2 Effect of port timing 16
» 6.3 Effect of combustion chamber design 16
» 6.4 Effect of blowby 16
> 7 Conclusions 18
> Acknowledgements 18
> References 18
This paper describes the development and characterisation of small-scale rotary engines with displacements in the range of 78-1500 mm 3 for portable applications in the range of 10-200 W of power output. Small-scale combustion engines present a number of research challenges including manufacturing tolerances, sealing, thermal management, ignition, combustion efficiency and porting. Four engines have been characterised using a custom test bench and show an increase in performance due to design changes that mitigate the challenges associated with small-scale engines. The volumetric power density has been increased from 11 W/cm 3 in a 348 mm 3 engine operating with a supercharged hydrogen/air mixture to 22 W/cm 3 in a 1500 mm 3 engine operating with naturally aspirated liquid hydrocarbon fuel. The thermal efficiency has also been increased from 0.2 to 4%. Continued improvements in sealing, thermal management, combustion efficiency and friction reduction will allow further increases in engine performance.
german keywords: Wankelmotor / Kreiskolbenmotor
English Keywords: Wankel Engine / Wankel Rotary Engine / Rotary Piston Engine / Rotary Combustion Engine
Key takeaways
AI
The study focuses on developing and characterizing small-scale rotary engines for portable power generation.
Engine displacements range from 78 mm³ to 1500 mm³, achieving power outputs of 10-200 W.
Power density increased from 11 W/cm³ (348 mm³) to 22 W/cm³ (1500 mm³) through design optimizations.
Thermal efficiency improved from 0.2% to 4% by enhancing sealing and combustion chamber designs.
Continued advancements in sealing, thermal management, and combustion efficiency are essential for performance gains.
Technical paper by Kenji Yokoo, Eiji Arai, Takanori Sakai, Yoshinori Ogata, Masanori Hashimoto, Yuta Morinaga, Shinsuke Miyata Mazda 2023 Japanese version (original) starts at page 8 > Content ... (English version) » Summary + abstract 1 » 1. Introduction 1 » 2. Development concept + main specifications 2 » 2.1 Improved thermal efficiency 2 » 2.2 Minimize weight 3 » 2.3 Mountability 3 » 3. Weaving technique 4 » 3.1 Improvements in rotary engine configuration technology 4 » 1) Oil seal internal pressure reduction 4 » 2) Trochoidal plating 5 » 3) Apex seal 5 » 3.2 Development of reciprocating engine configuration technology 5 » 1) D.I. pump drive 5 » 2) Variable hydraulic control 6 » 3) Cooled EGR system 6 » 4. In conclusion 6 » References 6 » Authors 7 Mazda is approximately11New rotary engine making a comeback after a long hiatus8CDeveloped a mold. This small, high-output engine will be used as a generator in a series hybrid, and is part of the company's multi-solution strategy, which is a measure to protect the global environment.1It is one. In the development of this engine, we inherited the spirit of``continuous challenge'' and worked to evolve and optimize thermal efficiency improvement technology and structural technology to realize our vision for the evolution of internal combustion engines. Cooling loss, which is an issue in rotary engines, has been optimized by reviewing the basic specifications. The side housing, which was previously made of cast iron, has been replaced with aluminum to reduce its weight. Additionally, in line with the evolution of combustion, we utilized reciprocating engine configuration technology and strengthened the structure to withstand high-load combustion. Compared to a reciprocating engine, it takes advantage of the ability to achieve the required output performance in a more compact unit, and even when combined with a large high-output motor and generator and placed on the same axis.MX-30This makes it possible to mount it on the vehicle body frame. german keywords: Wankelmotor / Kreiskolbenmotor English Keywords: Wankel Engine / Wankel Rotary Engine / Rotary Piston Engine / Rotary Combustion Engine
This paper describes the development of small rotary internal combustion engines developed to operate on the High Efficiency Hybrid Cycle (HEHC). The cycle, which combines high compression ratio (CR), constant-volume (isochoric) combustion, and overexpansion, has a theoretical efficiency of 75% using air-standard assumptions and first-law analysis. This innovative rotary engine architecture shows a potential indicated efficiency of 60% and brake efficiency of >50%. As this engine does not have poppet valves and the gas is fully expanded before the exhaust stroke starts, the engine has potential to be quiet. Similar to the Wankel rotary engine, the 'X' engine has only two primary moving partsa shaft and rotor, resulting in compact size and offering low-vibration operation. Unlike the Wankel, however, the X engine is uniquely configured to adopt the HEHC cycle and its associated efficiency and low-noise benefits. The result is an engine which is compact, lightweight, low-vibration, quiet, and fuel-efficient. Two prototype engines are discussed. The first engine is the larger X1 engine (70hp), which operates on the HEHC with compression-ignition (CI) of diesel fuel. A second engine, the XMv3, is a scaled down X engine (70cc / 3HP) which operates with spark-ignition (SI) of gasoline fuel. Scaling down the engine presented unique challenges, but many of the important features of the X engine and HEHC cycle were captured. Preliminary experimental results including firing analysis are presented for both engines. Further tuning and optimization is currently underway to fully exploit the advantages of HEHC with the X architecture engines.
book by Richard Ansdale, 1968, 170 pages > Contents ... > Preface 7 > 1 » Introduction to the NSU / Wankel RC Engine, its Design + performance Characteristics » page 1 of main part * german version » auxiliary part » Bezeichnungen der Einzelteile > 2 » The Essentials of Rotary Piston Internal Combustion Engines 5 > 3 » The Epitrochoidal Configuration 19 » 3.1 » Derivation of Epitrochoids from First Principles 19 * german version » other photo by F+S + 2 additional photos » 3.2 » The Rotor Contour - How it is obtained 24 » 3.3 » Other configurations - Their advantages or limitations 26 > 4 » The First Single Rotation (SIM) Type NSU / Wankel RC Engine 30 > 5 » The Planetary Rotation Engine 35 > 6 » Fundamental Relationships of Wankel RC Engines 44 » 6.1 » Fundamental Relationships 44 » 6.2 » Calculation of displacement volume suggested by G.B. Seward 48 » 6.3 » Calculation of Compression Ratio 52 » 6.4 » Displacement + equivalent displacement volumes 53 » 6.5 » Surface / Volume Ratio 62 > 7 » Sealing 68 » 7.1 » The Oil Seal Arrangement 69 * german version » additional pictures of Daimler-Benz Zellenkolben » 7.2 » Gas Sealing 70 » Figure with double side seals 75 » 7.3 » The Side Seals 77 » 7.4 » The Apex Seals 78 * german version » additional figure with slotted Apex Seal > 8 » The Porting - Side + Peripheral Inlet Ports + their Merits, Gas Velocity + Volumetric Efficiency 84 * german version » additional diagram with Side + Peripheral Intake Port > 9 » Lubrication 95 > 10 » Engine Cooling 100 » 10.1 » Introduction 100 » 10.2 » Air Cooling 103 * german version » additional diagram Druck- + Saugluefter » 10.3 » Liquid Cooling 105 > 11 » Ignition 108 > 12 » Power Output 113 > 13 » Performance Characteristics 117 » 13.1 » Fuel Requirements 117 » 13.2 » Engine Noise + Vibrations 117 » 13.3 » Exhaust Emission 119 » 13.4 » Performance 122 » 13.5 » Fuel Consumption 128 > Appendix » Mathematical Analysis of the NSU Wankel RC Engine 131 » A.1 » Generation of Trochoids 131 » A.2 » Generation of Epitrochoids 132 » A.3 » The Parameter ø (Schwenkwinkel) 134 » A.4 » The Envelope of a Trochoid 136 » A.5 » The Area of the General Rotor 140 » A.6 » The Area Bounded by the Epitrochoid + the Apexes of a Rotor 141 » A.7 » Velocities + Accelerations 144 » A.8 » Torque 150 » A.9 » Circular Arc Approximation to Rotor Flank 151 » A.10 » Calculation of the Surface / Volume Ratio 153 » Notation 155 * german version » auxiliary parts ... » 15 » Die Vorteile des Kreiskolbenmotors » 16 » Ausgefuehrte Wankelmotoren » Literaturnachweis > Index 156 german keywords: Wankelmotor / Kreiskolbenmotor English Keywords: Wankel Engine / Wankel Rotary Engine / Rotary Piston Engine / Rotary Combustion Engine
Technical paper by: Kelvin Fu, Aaron J. Knobloch, Bryan A. Cooley, David C. Walther, Carlos Fernandez-Pello, Dorian Liepmann (University of California, Berkeley), + Kenji Miyaska (Fukui University, Japan) 2001, 6 pages > Content » Abstract 1 » Nomenclature 1 » Introduction 1 » Quenching experiments 2 » Rotary engine design + scaling issues 4 » Conclusions 6 » Acknowledgments 6 » References 6 A research program is currently underway with the purpose of developing a MEMS-sized rotary (Wankel-type) internal combustion micro-engine, which would use liquid hydrocarbon as fuel and would be capable of delivering power on the order of milli-watts. The most significant issue in sustaining combustion in an engine of this size is the increased heat losses due to the high surface-to-volume ratio, german keywords: Wankelmotor / Kreiskolbenmotor English Keywords: Wankel Engine / Wankel Rotary Engine / Rotary Piston Engine / Rotary Combustion Engine
Thesis by Guido A. Danieli, 1976 (MIT) 159 pages german keywords: Wankelmotor / Kreiskolbenmotor English Keywords: Wankel Engine / Wankel Rotary Engine / Rotary Piston Engine / Rotary Combustion Engine based on Mazda 12A engine > Table of Contents » Abstract 2 » Acknowledgments 3 » Table of Contents 5 » Introduction 7 » Chapter 1 - Theoretical Analysis 9 » 1.1 Thermodynamic Model of the System 9 » 1.2 Combustion Model 20 » 1.3 Flame Propagation Model 20 » 1.4 Heat Transfer Model 31 » 1.5 Quenching Mechanism 36 » 1.6 Leakage + Gas Exchange Mechanisms 37 » 1.7 Geometrical Model 39 » Chapter 2 - Experimental Results 42 2.1 Experimental Apparatus + Techniques 42 2.2 Results + their Analysis 46 » Chapter 3 - Comparison between Theory + Experiments 52 » 3.1 Motoring Conditions 53 » 3.2 Firing Conditions 58 » 3.3 Some parametric Studies on Engine Performance 72 » Conclusions 76 » References 80 » Tables 82 » Appendix A - Formulation of Momentum Equation to compute Pressure Differences within the Chamber of a Wankel Engine 95 » Appendix B - Geometrical Notes 98 » Appendix C - Mixing Gases at constant Pressure (Heat Transfer Model) 102 » Appendix D - Simple Case of Flame Propagation 103 » Appendix E - Determination of the Angle alpha which determines the Housing Coordinates of the Intercept between the perpendicular to the Rotor Surface from a given Point + the Housing 106 » Appendix F - Possible Sources of Error in the Energy Balance 108 » Appendix G - Meaning of pV during Combustion 113 » Figures 115 » Biographical Notes on Guido A. Danieli 159
International journal of automotive engineering, 2020
Comparatively, this review is meant to focus on possible developments studies of the rotary engine design. The controversial engine produces a direct rotational motion. Felix Wankel derived the triangular rotor shape from complex geometry of the Reuleaux triangle. The Wankel engine simulation and prediction of its performance is still limited. The current work reviews rotary engine's flow field inside the combustion chamber with different commercial software used. It studies different parameters effect on the performance of the engine, such as the effect of the recess sizes and the shape-factor. It is found that the engine chambers design is one of the aspects of improvement opportunities.
276 S.B. Sprague et al. California, Berkeley in 1998. His research interests include sensors and microsystems for portable power and energy applications. Albert P. Pisano is a Professor of Mechanical Engineering at the University of California, Berkeley. He received his PhD in Mechanical Engineering from Columbia University. His research interests include Micro Electromechanical Systems (MEMS) for a wide variety of applications, including power generation, radio frequency components, drug delivery and strain sensors. A. Carlos Fernandez-Pello is a Professor of Mechanical Engineering at the University of California, Berkeley. He received his PhD in Applied Mechanics and Engineering Science from the University of California, San Diego. His research interests span micro- and meso-scale combustion and microgravity combustion, specifically ignition and flame propagation, smoldering and transition to flaming. 1 Introduction Advances in device miniaturisation have led to opportunities in reduced-scale, distributed power generation. Electrochemical, thermochemical and biological power production strategies are being investigated for personal power systems (Dunn-Rankin et al., 2005). Particularly interesting is the production of power from internal combustion engines using liquid fuels. Liquid fuels have a very large chemical energy density and consequently are particularly suitable for portable power generation. In comparison with rechargeable batteries, with an energy density of 0.7 MJ/kg for lithium-ion batteries, hydrocarbon fuels have 45 MJ/kg of stored chemical energy. Therefore, if this chemical energy can be converted to electricity with an efficiency as low as even 5%, then portable devices could be developed that would replace batteries for a number of applications. Leveraging the inherent advantages in storage and energy density of liquid hydrocarbon fuels is the prime motivation for this and other heat engine work. A thorough review of the issues related to combustion device development at the small scale has been previously reported (Fernandez-Pello, 2002). Several of the other heat engine and thermochemical approaches in development are addressed in the above two reviews. The objective of this work is to describe the development, fabrication and operation of small-scale rotary engines developed in the University of California Berkeley combustion laboratory to be used in a portable power generation device. A rotary engine design was originally chosen for a MEMS engine that would benefit from the planar design (Fu et al., 2001). The rotary engine is still well suited for small-scale power generation because it has a high specific power, a low cost due to a minimum number of moving parts, and no valves or transmission are required for operation. The planar design allows for high-precision electrical discharge machining and the mechanical shaft output can be directly coupled to an electric motor to produce electrical power. The emissions of rotary engines are lower than two-stroke engines due to better intake and exhaust scavenging that prevent contamination of fresh charge with exhaust, although sealing problems may reduce this benefit. Furthermore, rotary engines are inherently capable of fuel flexible operation with glow plug ignition, which is a preferable mode of operation in small-scale engines. This is due to the motion of the rotor whereby the compression stroke is separated from the glow plug location, which prevents premature initiation of
Development and characterisation of small-scale rotary engines 277 the combustion reaction (Cardes et al., 2005). During the engine development, several distinct designs have been produced to characterise the effect of engine size, port timing, fuel type and sealing on power generation. These results will be described and the implications to other small-scale combustion engines will be discussed. 2 Background There are several important factors that affect the performance (output power and efficiency) of small-scale engines. These include flame quenching, combustion time, mixing, turbulence and sealing. Flame quenching is important because it limits the minimum linear distance within which combustion can be sustained and therefore limits the size of the combustion chamber and in turn the achievable power density. Combustion time is crucial to engine operation since it determines maximum engine speed and therefore power output. Furthermore, combustion time affects the completeness of the chemical reactions within an engine, affecting emissions. The low Reynolds numbers encountered in small-scale engines hamper turbulent mixing, which is needed for achieving homogeneous mixtures. Sealing affects the efficiency and power output since the maximum pressure is reduced and exhaust gases can contaminate the intake charge. 2.1 Characteristic times of combustion For complete combustion, the residence time of the expansion stroke of the engine must be longer than the chemical time necessary for combustion to occur. The residence time is determined by the engine operation speed and the geometry, but is independent of scale for rotary engines. The residence time of a combustion stroke is calculated from the ratio of the crankshaft angular displacement as the rotor passes from the end of the compression stroke to the beginning of the exhaust stroke, and the angular speed of the rotor. For the engines addressed here that have speeds ranging from 5000 to 20000 rpm, the corresponding residence times range from 7.5 to 1.9 ms with an angular crankshaft displacement of 225°. The chemical reaction time is estimated from the reaction rate of the fuel and the average concentration of the fuel and oxidiser. Using a one-step global reaction under stoichiometric conditions and a combustion temperature of 2200 K, methanol has a characteristic reaction time of 10 µs (Borman and Ragland, 1998). The small-scale rotary engines, however, are expected to have combustion temperatures lower than 2200 K due to high heat losses to the surroundings. Using a combustion temperature as low as 1300 K, the reaction time of methanol is calculated to still be less than 1.2 ms. Thus, the residence time of the expansion stroke is still longer than the corresponding chemical reaction time since small-scale rotary engines are designed to operate at maximum speeds of 20000 rpm. In many cases, energetic fuels can be used in the form of nitromethane additives to increase the chemical reaction rate and in turn reduce the chemical time by increasing the oxidiser concentration. The addition of nitromethane is common practice for small-scale combustion engines of this scale (Papac et al., 2004).
278 S.B. Sprague et al. 2.2 Heat transfer Heat generation is proportional to the chemical mass throughput of the device. The mass throughput is proportional to the area of the inlet multiplied by the residence time. Assuming the residence time is equal to the chemical time, the mass throughput and consequently the heat generation rate are proportional to q ~S L ·l 2 where S L is the laminar flame speed and l is the characteristic dimension of the chamber or the device. The power density ( q /l 3 ) therefore increases inversely proportional to the scale of the device (Epstein and Senturia, 1997). Heat losses in actual systems, however, place a practical limit on the net power of the device (heat generated less heat lost). Heat losses to the environment are proportional to the surface area of the engine and the heat generated by combustion is proportional to the volume of the combustion chamber. Since volume is related to the length cubed and surface area is related to the length squared, the ratio of surface area to volume increases linearly as the length scale is reduced. Therefore, the rate of heat loss approaches and finally dominates heat generation as the scale is reduced. This critical crossover point has been determined to first order to be of the order of 1 mm by several investigators (Fu, 2001; Leach and Cadou, 2005; Peterson, 1998). 2.3 Flame quenching Quenching occurs due to thermal losses as well as radical destruction at the wall (Glassman, 1987). There is a minimum distance of a combustion chamber at which combustion can occur and it is determined by the ratio of the heat generated by the combustion reaction to the heat loss to the wall. The minimum linear distances of the combustion chambers for the small-scale rotary engines presented in this paper are between 0.4 and 1.6 mm, which is less than the thermal quenching distance for methanol at standard temperature and pressure conditions, 2.0 mm (Borman and Ragland, 1998). However, the thermal quenching distance in an actual engine is decreased due to the high-temperature walls and high compression pressures (Borman and Ragland, 1998). Experiments on combustion in small channels have shown that external heating of channel walls allows combustion to occur in channels smaller than the conventional quenching distance (Maruta et al., 2005; Zamashchikov, 1995). Numerical modelling of combustion in channels with adiabatic walls also shows that flames can propagate in channels smaller than the quenching distance (Leach and Cadou, 2005; Lee and Tsai, 1994). Radical quenching, on the other hand, becomes dominant only when the wall temperature is relatively high. Miesse et al. (2004) found no effect of surface material on quench distance below 500 K and a large radical quenching effect near 1300 K. The maximum heat losses in rotary engines occur at the top dead centre position when both the temperature and the gas velocity are high due to changes in density from combustion. Using the correlation from Woschni (1967) as referenced by Heywood (1988), the maximum heat transfer coefficient for a small-scale engine with a displacement of 1.5 cm 3 at 6000 rpm is found to be 535 W/m 2 K. The heat transfer coefficient is proportional to the rotor width, B, and gas velocity, w, as follows (Heywood, 1988): 0.2 0.8 c h B w α − (1) The heat transfer coefficient decreases as the size of the engine is decreased because of the reduction in the gas velocity, which offsets the effect of the rotor width reduction.
Development and characterisation of small-scale rotary engines 279 The Woschni correlation was however developed for large-scale engines by assuming turbulent convective heat transfer across a flat plate resulting in the 0.8 power dependency on velocity. The Reynolds number in the 1.5 cc engine ranges from 4200 at 8000 rpm to 7800 at 15000 rpm. This places the flow field outside of laminar flow, but cannot be considered fully turbulent. As such, the heat transfer could scale with velocity to a power as low as 0.5 for the fully laminar case and therefore application of the Woschni correlation may overestimate the heat transfer coefficients within small-scale engines. As engine scale is reduced, however, continued application of turbulent model correlations may overestimate the effect of decreasing engine size on the heat transfer coefficient. However, even though h c is reduced, the total heat loss increases because the surface area to volume ratio increases as the size of the engine is decreased. Therefore, flame quenching is more likely to occur as the size is reduced due to the higher ratio of heat losses to heat generation. 2.4 Mixing and turbulence Both a homogeneous charge and turbulent flow enhance the overall reaction rate, and consequently increase the potential power output of the engine. The former requires adequate mixing of fuel and oxidiser, which depends on the turbulence level and the mixing length. Turbulence is determined by the Reynolds number, which decreases as the size of the engine is decreased. Therefore, mixing and turbulence are important issues in small-scale engines. In the range of engines described here, the Re (defined by engine intake conditions) values are typically in the transitional regime (Dellimore and Cadou, 2004); thus turbulence levels are limited. However, with liquid fuels, droplet vaporisation times are dominant over mixing times in small engines (Park et al., 2006); thus care must be taken to ensure adequate vaporisation for optimal engine performance. 2.5 Sealing Leakage during the compression stroke and the combustion event reduces the overall power output due to the loss of high-pressure gas (Annen et al., 2003). Ideally, the ratio of mass leakage to mass throughput should be constant as the size of the engine is decreased. Large-scale rotary engines have complex sealing mechanisms to separate the three operating chambers and ensure a high operating pressure, including apex seals, face seals and corner seals (Yamamoto, 1981). However, for small-scale rotary engines, it is impractical to have numerous sealing components because of the difficulty to assemble. Therefore, few and relatively simple seals are used for apex sealing. Tight tolerances are desired for face sealing, which seals between the rotor face and housing. Tolerance is, however, limited by manufacturing technology and does not scale with engine size. Small-scale engines with the same tolerance level as large-scale engines suffer a greater proportion of mass loss. Therefore, better means of fabrication are required at this scale. The small-scale rotary engines described in this paper are fabricated with electrical discharge machining and have tolerances ranging from 0.2 to 0.003 mm depending on the manufacturing approach. The apex seals and the close fit between the rotor and engine endplates, however, also add to the frictional losses experienced by the engine. An analysis of the frictional work due to the apex seals, normalised by the engine displacement, indicates that this value should increase as displacement decreases to the 1/3 power of displacement,
280 S.B. Sprague et al. f apex α disp −1/3 . However, analysis of normalised frictional losses due to face seals indicates that the friction decreases as displacement decreases by the 1/3 power of displacement, assuming a constant gap between rotor and the endplates, f face α disp 1/3 . Direct measurements of the normalised motoring work on 0.367 cc, a commercially available 5 cc rotary engine, and 500 cc (Yamamoto, 1981) engines show that the normalised friction decreases as the size is decreased, suggesting that face seal friction is the dominant friction loss mechanism at the small scale. 3 Small-scale rotary engine designs Four engines have been built and tested over the course of this development project to examine the impact of engine design and construction on performance. A table listing the design characteristics and operating conditions can be seen in Table 1. Changes in manufacturing processes, sealing design, porting methods and combustion pocket design, as well as increases in engine size, have led to improvements in overall engine performance. Table 1 Engine design characteristics and operating conditions Name P78 P348 S367 S1500 Displacement (mm 3 ) 78 348 367 1500 Porting Peripheral Peripheral Side Side Rotor length (mm) 9.5 12.5 17 25 Rotor depth (mm) 3.6 9 6.3 10 Pocket depth (mm) 0.46 0.67 1.3 1.5 Tolerance (mm) ±0.2 ±0.02 ±0.003 ±0.003 Fuel type Gaseous Gas/liquid Liquid Liquid Air induction Supercharged Supercharged Naturally aspirated Naturally aspirated Speed range (rpm) 2500–5000 3000–9000 1000–6000 8000–15000 Housing temperature (°C) 25–45 45–75 45–100 90–115 Igniter location Minor axis Minor axis Off axis Off axis 3.1 Peripheral ported P78 engine The P78 engine with a displacement of 78 mm 3 is a 1/64th scale version of the smallest commercially available rotary engine, the 5 cc Graupner/OS 49-PI. The P78 has been designed and built to determine the effect of scale on combustion performance. The engine consists of 15 parts: front plate, epitrochoid housing, back plate, rotor, internal gear, spur gear, shaft and three apex seals and three leaf springs (Figure 1). The apex seals consist of tabs of brass or steel between 0.5 and 1.0 mm thick. The seals are backed with metal leaf springs to maintain contact between the seals and engine housing. Two bearings, which are mounted in the front and back plates, position the shaft. The engine
Development and characterisation of small-scale rotary engines 281 is made from steel with a tolerance of 0.2 mm. The location of the peripheral ports is the same as the Graupner/OS 49-PI, with the intake mixture and exhaust gases entering and exiting the engine through radial passages in the engine housing. The combustion pocket is comprised of a simple rectangular recess made on the side of the rotor as seen in Figure 2 and the spark plug is located on the minor axis of the engine housing. Figure 1 Peripheral ported engines P78 and P348 Figure 2 P78 and P348 rotors with combustion pockets 3.6 mm 5.5 mm 9.5 mm 9 mm 7.5 mm 12.5 mm 9 mm 3.2 Peripheral ported P348 engine The size of the P348 engine is 4.5 times larger than the P78 engine with a displacement of 348 mm 3 to reduce heat transfer to the engine housing. The ratio of the rotor depth to length is approximately twice as large as the P78 engine specifically to reduce axial heat losses to the endplates. Heat-treated 17-4 PH900 stainless steel is used to reduce part wear and improve part tolerance from 0.2 to 0.02 mm. The same 15-part engine design with peripheral porting, rectangular combustion pocket, and minor axis igniter location is used as shown in Figures 1 and 2. Two types of face seals were developed for the P348, a one-piece graphite seal backed with a circular wavy spring and three-piece steel springs backed with individual steel leaf springs as shown in Figure 3. Although sealing is improved with the face seals, the improvements in sealing showed
282 S.B. Sprague et al. no observable effect in output power from the apex-seal-only designs. As such, the simplicity and relative effectiveness of the apex-seal-only designs are those implemented in engine testing. Sealing of the rotor face is achieved by having a close fit between the rotor and the endplates. Figure 3 Apex and face seals incorporated into the P348 engine 3.3 Side-ported S367 engine The size of the S367 engine is approximately the same as that of the P348 with a displacement of 367 mm 3 , but a side-ported design is used instead of peripheral ports. The displacement changes are due to slight changes in housing and combustion pocket geometry. Peripheral ports are advantageous at high speeds for maximum power output because of an increase in volumetric efficiency (Ansdale, 1968). However, peripheral ported engines have increased rotor port overlap, which occurs when the intake and exhaust ports are open at the same time, contaminating the intake charge with exhaust gases. Side port designs alleviate contamination of the intake charge by exhaust gases, as the ports are designed to prevent any port overlap. The rotor and rotor housing are fabricated with M2 tool steel to improve tolerances to 0.003 mm, and side plates are fabricated with aluminium (Figure 4). These endplates maintain assembly tolerance, but do not see direct contact with rotating components. Wear plates that contain the side ports are also made of M2 tool steel and are used between the aluminium endplate and rotor to minimise damage incurred by wear. The rotors are thinner compared to the P348 to focus flame front motion in the direction of the applied torque rather than towards the endplates, more consistent with operating rotary engines (Yamamoto, 1981). It has been shown in previous studies that the peak pressure during combustion in closed and semi-closed chambers of the order of 1 mm is reduced as the chamber height and width are reduced (Lee et al., 2003; Tsuji et al., 2004). Therefore, a teardrop-shaped rotor recess is used to increase the depth of the combustion chamber to increase combustion efficiency by allowing heat losses to the ignition kernel to be reduced (Figure 5). The inverted teardrop shape has been designed to increase turbulence, and in turn reaction rate and mixing through a ‘squish flow’ effect (Gorla and Bartrand, 1996). The igniter location is offset from the minor axis to reduce blowby as described in the Discussion section below.
Development and characterisation of small-scale rotary engines 283 3.4 Side-ported S1500 engine The S1500 engine is four times larger than the S367 with a displacement of 1500 mm 3 to further reduce heat losses and improve relative tolerances, but is manufactured using the same method and materials as the S367. The same peripheral porting, teardrop combustion pocket and off minor axis igniter location are used. Figure 4 Side-ported engines S367 and S1500 Figure 5 S367 and S1500 rotors with combustion pockets 9 mm 6.3 mm 17 mm 14 mm 10 mm 25 mm 4 Test apparatus A schematic diagram of the test apparatus is shown in Figure 6. The test bench consists of an electric motor/dynamometer, an optical tachometer, and an ignition system. The characteristics for the test bench changed slightly from the first two engines tested to the third and fourth. The two peripheral ported engines with the smallest combustion chamber depths are tested with hydrogen as fuel because the high reaction rates of hydrogen allows for combustion in smaller chambers. The use of a supercharged premixed hydrogen/air mixture is advantageous because it does not require the complexity of liquid fuel vaporisation or varying fuel/air concentrations. Hydrogen and air are mixed upstream of the engine in a T-junction, and individually controlled by
284 S.B. Sprague et al. mass flow controllers (Figure 6). A spark ignition system, manufactured by CH Electronics, Inc., that utilises a Hall effect sensor that is attached to a rotary dial is used to control the ignition and spark timing. A customised igniter is made from a ceramic tube with a tungsten electrode. In addition to a spark plug, a modified glow plug has been tested on the P348. The preliminary hydrogen testing was only done for experimental purposes, as practical devices would use liquid fuels due to the ease of transportation and high energy density. Figure 6 Schematic diagrams of engine testing apparatus. Left: dynamometer for gaseous fuels and electrical power measurement. Right: dynamometer for liquid fuels and mechanical power measurement (1) (1) (2) (2) (3) (3) (4) (5) (6) 1) engine 2) motor/dyno 3) ignition system 4) mass flow controller 5) fuel injector 6) torque arm/load cell Therefore, the two side-ported engines are tested with a liquid fuel blend, which consists of methanol (70%, by vol.), nitromethane (10%) and castor oil as a lubricant (20%) (Papac et al., 2004). A micro-dispensing valve (INKA2457210H) from the Lee Company is used as a fuel injector, and a function generator controls the fuel flow rate over the range of 10–100 mg/s. The maximum pressure of the fuel injection system is limited to 2 atm and the orifice diameter is 12.5 µm. The limiting pressure is established with regard to storage and safety concerns in the final demonstration unit. Air is inducted by natural aspiration and mixed with fuel in the intake manifold, which consists of 3 mm diameter tubing with 6 and 8 mm lengths (Figure 7). The ignition system for these engines was improved by controlling the ignition delay with a function generator. The function generator is actuated with a signal from an optical sensor that detects the position of the crankshaft. To ensure that spark power is consistent at higher operation speeds (limited by capacitor charging time), an automotive ignition system from MSD (part no. 5900 and 8223) is implemented for the later engine testing. The S367 used the same customised spark plug as the peripheral-ported engines; however, for the S1500, a commercial ¼”-32 spark plug (CH Ignitions Rimfire Plug no. 111) is adapted. Engine speed for all engines is measured using a Monarch Instruments ACT-3 tachometer with ROS-5W remote optical sensor. The engines are rigidly coupled to the dynamometer via a steel shaft. The engine power for all engines except the S1500 is determined by measuring the electrical power generated from a dynamometer. The electrical power is measured with a Maxon brushless electronically commutated motor
Development and characterisation of small-scale rotary engines 285 (part no. EC80) with a rectifier (International Rectifier no. 36MT20). Power generated by the engine spins the motor, which acts as a generator and produces electrical power. The rectifier circuit converts the motor’s three-phase output to a DC voltage potential. Rheostats are used to apply a resistance to the motor around 30 Ω and can be adjusted to produce the appropriate load, based on the engine being tested. For the S1500, the mechanical power is measured with a 23.5 cm long torque arm and a load cell that measures up to 2.5 N (Sensotec Model 31). The torque arm is attached to the motor, and the motor shaft is mounted so that the motor can rotate freely on the shaft axis. Temperature measurements are made on the housing near the combustion chamber using type-K thermocouples. These results are verified by infrared imaging using an Inframetrics SC10000 Thermacam. It is noted that at the scale of these engines, the Biot number is estimated at 0.05 and therefore the temperature in the housing is fairly uniform. Figure 7 Top-view schematic diagram showing liquid fuel injector and manifold Shaft Spark Plug Fuel Injector Intake Ports Air Porting Plates Engine 5 Experimental results Improvements in engine design and manufacturing technique produced a steady increase in engine performance over the course of this development project. Slight differences in power measurement technique are used, though in general an electric motor is used to both motor the engine with no combustion and measure the power delivered by the engine while operating with combustion. Results relating to combustion and power production for each engine will be presented in this section, followed by a Discussion section that describes how the performance is affected by the engine design.
286 S.B. Sprague et al. 5.1 P78 peripheral ported engine The P78 engine has been tested with stoichiometric hydrogen/air and propane/air mixtures. An electric motor is used to motor the engine while the spark ignition system ignites the mixture. The engine does not generate a net power output, but there is a reduction in the amount of power needed by the electric motor to turn the engine with combustion. The engine has been run with a Plexiglas front plate in order to obtain infrared images of combustion while operating the engine as shown in Figure 8. Figure 8 Infrared images of hydrogen–air combustion in the P78 engine 5.2 P348 peripheral ported engine A typical testing procedure for the P348 consists of bringing the engine up to a speed of approximately 3000 rpm through the use of the pressurised air to overcome friction. Then the spark system is energised and hydrogen is introduced until sustained combustion is obtained. With the spark energised, speed increases of 2000–4000 rpm are noted and the power increases from 1 to 3 W, as seen in Figure 9. By subtracting the amount of power generated with the spark off from the power generated with the spark on, the net power generated by the engine can be calculated. It is important to note that the energy of the compressed gas is not considered in these calculations. The results of power tests over a range of engine speeds can be seen in Figure 10. Notice the linear rise in power with speed with no drop in power at high speeds, indicating that the residence time is still greater than the chemical reaction time for all engine speeds tested. The equivalence ratio for the tests in Figure 10 is in the range of 0.37–0.42. Higher equivalence ratios would result in more power, but flashback is noted, preventing the experiment from achieving safe operation at elevated equivalence ratios. The flashback is attributed to excess porting overlap, which allows the flame from the exhaust to enter the intake. The spark timing is 0° After Top Dead Centre (ATDC) for all conditions, with similar results being obtained with a glow plug.
Development and characterisation of small-scale rotary engines 287 Figure 9 Engine power output and engine speed of the P348 engine operating on hydrogen–air with spark ignition 0 1 2 3 4 5 6 0 25 50 75 100 125 150 175 200 225 Time (sec) Power (W) 0 2000 4000 6000 8000 10000 12000 Engine Speed (RPM) Power Speed Spark On Spark On Spark On Spark On Figure 10 Net power output of the P348 engine operating with hydrogen–air mixture 0 1 2 3 4 2000 3000 4000 5000 6000 7000 8000 9000 10000 Engine Speed (RPM) Power (W) Spark Ignition Glow Plug Ignition Using the lower heating value for hydrogen of 120 MJ/kg and multiplying by the fuel rate and density, the chemical energy of the hydrogen can be calculated. With a hydrogen flow rate of 7.9 SLPM, the chemical rate of energy is 1400 W. Using the values of the chemical energy rate in and the electrical power out, the efficiency can be calculated as the ratio of the electrical power out divided by the energy rate in. For the conditions tested, the efficiency at the maximum output power of 3.8 W is 0.27%. 5.3 S367 side-ported engine Tests on the S367 with methanol/nitromethane mixture as the fuel does not produce positive power, although combustion and a significant reduction in the motoring power required are observed. For the combustion tests, the engine is driven by the electric motor and excess fuel is supplied to the engine with the ignition system on. The fuel
288 S.B. Sprague et al. rate is reduced until combustion is found to occur and then reduced further until no combustion is detected. This range of mass flow rates is shown in Figure 11 as a function of engine speed. There are two regimes in the flow rate versus speed plot, a rich region at low speeds and nearly stoichiometric region at high speeds. This change in required fuel rate at 4000 rpm may be partially attributed to a transition from laminar to turbulent flow enhancing the fuel and air mixing. This effect is similar to the high mean inlet gas velocity required for rotary racing engines to promote combustion at the lower speed range (Ansdale, 1968). The calculated Reynolds number for the S367 operating condition is in the range of 1000 and therefore additional effects are most likely also occurring. At low speeds, the excess fuel may be needed to fill the gaps between the rotor and housing and to create additional sealing in the 0.004 mm gap. This sealing by liquid fuel results in increased compression, reaching a threshold level at 4000 rpm that results in a more complete combustion process. As the total amount of mass loss is a function of both gap size and time, leakage at high speeds is not as critical as there is less time for leakage to occur. Figure 11 Fuel rate as a function of engine speed for S367 engine showing rich region at low speed and stoichiometric region at high speed 0 5 10 15 20 25 30 35 40 45 50 0 1000 2000 3000 4000 5000 6000 Engine Speed (RPM) Mass Flow Rate (mg/s) Measured fuel consumption rate Stoichiometic fuel consumption rate 5.4 S1500 side-ported engine The S1500 generates positive power with naturally aspirated, liquid-fuelled operation. A fuel blend with 50% methanol, 30% nitromethane and 20% castor oil is used with a flow rate of 47±3 mg/s. To motor the engine at 10000 rpm with no spark, 77 W of input power is needed. With the spark on, the engine speed increases to 11000 rpm and the input power required drops to 2.6 W. When power to the electric motor is turned off, the engine speed is reduced to 8600 rpm, and the engine continues to operate. To load the engine and make positive power, a bank of rheostats is put in series with the rectified output of the drive motor. The spark timing is adjusted to find the optimum operating range and it is observed that the engine operates best with retarded spark timing, ranging from 5 to 25° ATDC.
Development and characterisation of small-scale rotary engines 289 The maximum sustained mechanical power during these tests has been determined to be 33 W. The conditions are a speed of 10500 rpm and 15° ATDC spark timing with 45±3 mg/s of a fuel blend with 60% methanol, 20% nitromethane and 20% castor oil. A representative engine test is shown in Figure 12. Using the positive power generated and the chemical energy of methanol of 19 MJ/kg, the efficiency is calculated to be 3.9%. With an engine mass of 210 g, this results in a peak specific power of 158 W/kg. Further, assuming a 1 l fuel storage vessel, the resulting specific energy of 157 W-h/kg is achieved when only the mass of the engine block and fuel are considered. Fuel storage, delivery and control as well as power conditioning and conversion will add significant mass and reduce the system-specific energy. Figure 12 Power testing with naturally aspirated S1500 engine -4000 -2000 0 2000 4000 6000 8000 10000 12000 0 5 10 15 20 25 30 35 40 45 Test Time (sec) Speed (RPM) -20 -10 0 10 20 30 40 50 60 Mechanical Power (W) speed (RPM) ave power (W) Engine running on own Engine being motored 6 Discussion From the above results, it is seen that there is an increase in power and efficiency between the second and fourth engines, the P348 and S1500. The displacement is 4.3 times larger, but the power is greater by a factor of 9. The improved efficiency is attributed to several factors, including better sealing, no port overlap, deeper combustion pocket depth and reduced blowby. 6.1 Effect of engine seals Improvements in sealing from the P348 engine to the S1500 are due to three mechanisms, reduced gap clearance due to better tolerance, higher spring force on the apex seals, and increased viscosity of fuel. Breakage due to cyclic loading has been found to be a problem with early spring designs using brass and 316 stainless steel. The longest reliable performance has been achieved with the use of 17-4 stainless steel springs with slight design changes to prevent cyclic failure. The 17-4 stainless steel springs used in the
290 S.B. Sprague et al. S1500 engine provide sufficient force to keep the apex seals in contact with the engine housing. The improvement in fabrication tolerance of the rotor and housing from 0.02 to 0.003 mm allows for a closer fit between the rotor face and the endplates, providing a smaller leakage pathway. The use of a continuous supply of lubricant in the S1500 engine fills the gap between the rotor face and endplates, which also increases the sealing performance of this design. However, the measured value for the maximum pressure of the S1500 while being motored at 10000 rpm is 6.0 atm, indicating a high level of leakage. The amount of leakage can be modelled using a mass loss model similar to the one described by Aichlmayr et al. (2002). It is calculated that the corresponding leakage area to obtain a maximum pressure of 6.0 atm is 60 mm 2 for the isothermal case. Assuming a constant gap between the housing and apex seal, and between the rotor face and wear plate, 60 mm 2 corresponds to a calculated gap of 8 µm. With this size gap, the calculated mass loss is over 50% before combustion occurs, indicating that there is an opportunity for increased performance with further improvements in sealing. 6.2 Effect of port timing Port overlap occurs when both the intake and exhaust ports are open to the same working chamber at the same time. This allows combustion products to be drawn into the intake from the exhaust port. These gases decrease the volumetric efficiency since the exhaust gases take the place of a fresh intake charge. As with blowby, the compression efficiency is also reduced. Port overlap particularly affects peripheral ported engines, the peripheral ports on P348 are 3.5 and 4.5 mm diameter holes located at ±18° off the minor axis. This results in a large amount of overlap of approximately one quarter of the rotor revolution, which contributes to the low efficiency of the P348 engine. Since the ports on the S1500 are located on the side of the endplates, the port opening and closing can be adjusted independently. This allows for zero degrees of port overlap since the intake can be opened after the exhaust is closed. These improvements reduce contamination of the fresh charge with exhaust gases and contribute to the increase in fuel efficiency. 6.3 Effect of combustion chamber design A portion of the total engine efficiency improvement is addressed by the improved combustion efficiency. Quenching effects are reduced due to the smaller heat loss of the S1500 since the combustion pocket depth is 1.5 mm compared to 0.67 mm for the P348. The deeper combustion pocket increases conduction resistance since the combustion heat flux is required to travel a longer distance before reaching the rotor housing. The increase of thermal resistance reduces heat loss to the engine, and the combustion efficiency is improved. 6.4 Effect of blowby Blowby occurs when high-pressure exhaust gases travel past the apex seal from the combustion chamber to the following chamber undergoing compression. The high-pressure exhaust gases contaminate the following fresh charge with combustion products, leading to a reduction in compression and combustion efficiency. The former is due to the preheating of the incoming charge by the hot exhaust gases that hampers the
Development and characterisation of small-scale rotary engines 291 compression of the mixture in the compression stroke. The later effect is due to contamination of the fresh charge and is similar to extreme cases of engine exhaust gas recirculation (EGR), above the typical range of 5–10% (Heywood, 1988). EGR recirculates engine exhaust gas back to the intake charge. This mixing dilutes the mix with inert gas, which slows the combustion, and lowers the peak temperatures to reduce NO x formation. In the case of small-scale engines, with already reduced gas temperatures, the impact is compounded and can lead to reduced power and instability of the combustion event. This blowby generally occurs at the spark plug recess since a direct path is opened from the combustion chamber to the compression chamber when the apex crosses the recess (see Figure 13). Figure 13 Blowby occurs when apex seals cross the spark plug location The path of blowby is observed with visual inspection of the peripheral-ported P348 rotor after testing. The soot pattern from the burning of lubricating oil can be seen in Figure 14 and is largest at the leading edge of the rotor and tapers to a central point on the trailing side. This is due to the fact that at 180° ATDC, the trailing apex of the rotor passes by the spark plug recess, located at the minor axis for the P348 design. With a deep recess for the spark plug, a large path is open between the two chambers. The peripheral exhaust port is not open when the apex crosses the spark plug location, forcing high-pressure exhaust gases into the following chamber. Figure 14 Soot patterns on P348 after hydrogen–air testing showing effect of blowby
Sorry, preview is currently unavailable. You can download the paper by clicking the button above.
References (25)
Aichlmayr, H.T., Kittelson, D.B. and Zachariah, M.R. (2002) Micro-Homogeneous Charge Compression Ignition (HCCI) Combustion: Investigations Employing Detailed Chemical Kinetic Modeling and Experiments, Western States Section of the Combustion Institute, La Jolla, CA.
Annen, K.D., Stickler, D.B. and Woodroffe, J. (2003) 'Linearly-oscillating miniature internal combustion engine (MICE) for portable power electric power', 41st Aerospace Sciences Meeting and Exhibit, Reno, NV.
Ansdale, R.F. (1968) The Wankel RC Engine, Iliffe, London.
Cardes, A., McCoy, C., Inaoka, K., Walther, D.C., Pisano, A.P. and Fernandez-Pello, A.C. (2005) 'Characterization of fuel flexibility in a 4.97 cm 3 rotary engine', Proceedings of the 4th Mediterranean Combustion Symposium, Combustion Institute, Lisbon, Portugal.
Dellimore, K. and Cadou, C. (2004) 'Fuel-air mixing challenges in micro-power systems', 42nd AIAA Aerospace Sciences Meeting and Exhibit, Reno, NV.
Dunn-Rankin, D., Leal, E.M. and Walther, D.C. (2005) 'Personal power systems', Progress in Energy and Combustion Science, Vol. 31, pp.422-465.
Epstein, A.H. and Senturia, S.D. (1997) 'Macro power from micro machinery', Science, Vol. 276, No. 5316, p.1211.
Fernandez-Pello, A.C. (2002) 'Micropower generation using combustion: issues and approaches', Proceedings of the Combustion Institute, Vol. 29, pp.965-972.
Fu, K. (2001) Miniature-Scale and Micro-Scale Rotary Internal Combustion Engines for Portable Power Systems, PhD Dissertation, University of California, Berkeley, CA.
Fu, K., Knobloch, A.J., Martinez, F.C., Walter, D.C., Fernandez-Pello, A.C., Pisano, A.P. and Liepmann, D. (2001) 'Design and fabrication of a silicon-based MEMS rotary engine', Proceedings of the 2001 ASME International Mechanical Engineering Congress and Exposition (IMECE), American Society of Mechanical Engineers, New York.
Glassman, I. (1987) Combustion, Academic Press, Orlando.
Gorla, R.S.R. and Bartrand, T.A. (1996) 'Couette flow heat loss model for the rotary combustion engine', Proceedings of the Institute of Mechanical Engineers, Vol. 210, pp.587-596.
Heywood, J.B. (1988) Internal Combustion Engine Fundamentals, McGraw-Hill, New York.
Leach, T.T. and Cadou, C.P. (2005) 'The role of structural heat exchange and heat loss in the design of efficient silicon micro-combustors'. Proceedings of the Combustion Institute, Vol. 30, pp.2437-2444.
Lee, D.H. and Kwon, S. (2003) 'Scale effects on combustion phenomena in a microcombustor', Microscale Thermophysical Engineering, Vol. 7, pp.235-251.
Lee, S.T. and Tsai, C.H. (1994) 'Numerical investigation of steady laminar flame propagation in a circular tube', Combustion and Flame, Vol. 99, pp.484-490.
Maruta, K., Kataoka, T. and Kim, N. (2005) 'Characteristics of combustion in a narrow channel with a temperature gradient', Proceedings of the Combustion Institute, Vol. 30, pp.2429-2436.
Miesse, C.M., Masel, R.I., Jensen, C.D., Shannon, M.A. and Short, M. (2004) 'Submillimeter-scale combustion', AIChE Journal, Vol. 50, No. 12, pp.3206-3214.
Papac, J., Figueroa, I. and Dunn-Rankin, D. (2004) Performance Assessment of a Centimeter-Scale Four-Stroke Engine, Western States Section of the Combustion Institute, Los Angeles, CA.
Park, S.W., Walther, D.C., Pisano, A.P. and Fernandez-Pello, A.C. (2006) 'Development of liquid fuel injection system for small-scale rotary engines', 44th AIAA Aerospace Sciences Meeting and Exhibit, Reno, NV.
Tsuji, Y., Sprague, B., Walther, D., Pisano, A. and Fernandez-Pello, C. (2004) 'Effect of initial pressure, temperature, and chamber size on pressure rise in reduced scale IC engine combustion chambers', Proceedings of PowerMEMS 2004, November 28-30, Kyoto.
Yamamoto, K. (1981) Rotary Engine, Sankaido Co., Tokyo.
Zamashchikov, V.V.E. (1995) 'Combustion of gases in thin-walled diameter tubes', Combustion, Explosion, and Shock Waves, Vol. 31, No. 1, pp.20-22.
FAQs
AI
What performance metrics were achieved with the S1500 engine design?add
The S1500 engine achieved a maximum sustained mechanical power of 33 W with an efficiency of 3.9%.
How do sealing improvements impact small-scale rotary engine performance?add
Improved sealing in the S1500 resulted from better tolerances, higher spring forces, and increased fuel viscosity, contributing to reduced mass loss.
What role does port timing play in combustion efficiency?add
Reducing port overlap from 260° to 0° prevents fresh charge contamination with exhaust gases, improving combustion variability.
What effects do mixing and turbulence have on small-scale engine output?add
Low Reynolds numbers limit turbulence in small-scale engines, which affects mixing and subsequently reduces the overall reaction rate.
How does engine scale influence heat loss versus power generation?add
As engine size decreases, surface area-to-volume ratios increase, leading to heat loss dominating heat generation, particularly below 1 mm.
A research project is currently underway to develop small-scale internal combustion engines fueled by liquid hydrocarbons. The ultimate goal of the MEMS Rotary Internal Combustion Engine Project is to develop a liquid hydrocarbon fueled MEMS-size rotary internal combustion micro-engine capable of delivering power on the order of milli-watts. This research is part of a larger effort to develop a portable, autonomous power generation system with an order of magnitude improvement in energy density over alkaline or lithium-ion batteries. The rotary (Wankel-type) engine is well suited for the fabrication techniques developed in the integrated chip (IC) community and refined by the MicroElectroMechanical Systems (MEMS) field. Features of the rotary engine that lend itself to MEMS fabrication are its planar construction, high specific power, and self-valving operation. The project aims at developing a “micro-rotary” engine with an epitrochoidal-shaped housing under 1 mm3 in size and with a...
thesis by Andrew L. Blackshaw 1973 94 pages deals with a Fichtel + Sachs KM37 rotary engine german keywords: Wankelmotor / Kreiskolbenmotor English Keywords: Wankel Engine / Wankel Rotary Engine / Rotary Piston Engine / Rotary Combustion Engine > Table of Contents » Acknowledgements » List of Tables » List of Illustrations » Summary » 1 - Introduction » The Energy Problem » Gaseous Prime Movers » The Wankel » Pollution Consideration » Purpose of Research » 2 - Description of Equipment » Basic Engine-Dynamometer Test Setup » Vacuum operated Micro-Switch Assembly » Engine Lubrication System » Fuel System » High RPM Shutoff » Remote Telephone Signalling System » Speed Control » Engine Hourmeter » Emissions Sampling + Measurement Apparatus » Sample Train System » 3 - Test Procedures » Power + Efficiency Tests (Gasoline) » Measurement of Oiling Rate » Engine Exhaust Emissions Measurement » Power + Efficiency Tests (Propane) » Seal Wear Test » 4 - Results + Discussion » Power + Efficiency Data » Exhaust Emissions » Seal Wear » Emissions Comparison of various Heating Systems » 5 - Conclusions » Appendix » A. Sample Calculation of Horsepower + Torque Values » B. Sample Calculation of the Gasoline fueled Engine » C. Sample Calculation of Efficience of the Propane fueled Engine » D. Sample Calculation of Mass Emissions from dry Volume Concentrations » E. Derivation of Equation for calculating Air-Fuel Ratios from Intake Mixture Analysis » F. Sample Calculation for comparing Emissions from different Heating Systems » G. Tables » Bibliography
Courtesy of Mr Kweon 96 pages ARL-TR-5546 german keywords: Wankelmotor / Kreiskolbenmotor English Keywords: Wankel Engine / Wankel Rotary Engine / Rotary Piston Engine / Rotary Combustion Engine > Content ... > List of Figures iv > List of Tables vii > Executive Summary ix > 1. Introduction 1 > 2. Brief History and Principles of the Rotary Engine 2 » 2.1 Brief History 2 » 2.2 Operating Principles of the Rotary Engine 4 » 2.3 Advantages and Disadvantages of the Rotary Engine 7 > 3. Rotary Engines for Heavy Fuels 9 » 3.1 Compression Ratio 9 » 3.2 Ignition 11 » 3.3 Direct-Injection Stratified-Charge Rotary Engine (DI-SCRE) 11 » 3.4 Small Heavy-Fueled Rotary Engines 13 > 4. Review of Heavy-Fueled Rotary Engine Research 13 » 4.1 Combustion Chamber Designs 14 » 4.2 Fuel Spray 26 » 4.3 Ignition System 37 » 4.4 Apex and Side Seal Designs 47 » 4.5 Heat Loss and Flame Quenching 56 » 4.6 Turbocharging and Supercharging 61 > 5. Conclusions and Recommendations 66 > 6. References 70 > List of Symbols, Abbreviations, and Acronyms 79 > Distribution List 82 Executive Summary In recent years, rotary engines have been used for various applications, including automobiles, motorcycles, and unmanned aerial vehicles (UAVs). The power range of the current rotary UAV engines around the world is between 20 and 90 hp. The UAVs that use a rotary engine as its powerplant include Harpy, Hermes, Shadow, and Searcher. The demand for UAVs is projected to dramatically increase around the world. However, our knowledge of the rotary engine is surprisingly inadequate, particularly for heavy-fueled rotary engines. This report summarizes the understanding and finding from the currently available literature in rotary engines, more specifically heavy-fueled rotary engines. A rotary engine has many advantages compared to a reciprocating engine, such as higher power density, smooth operation, simple design, low vibration, compact size, and light weight. But, it has also disadvantages like higher fuel consumption and more frequent maintenance requirements. However, these drawbacks have been steadily improved upon for gasoline-fueled rotary engines by some manufacturers, such as Mazda. Recently, the rotary engine has become attractive to some applications, where the merits are becoming more important. Today’s advanced combustion control and sophisticated fuel injection system may make the rotary engines more efficient and quite. Manufacturing accuracy and materials technology may resolve the issues of sealing leaks. Rotary engines, particularly heavy-fueled rotary engines, have not been extensively researched and developed compared to the reciprocating engines. Hence, considerable opportunities exist to improve the efficiency and performance of the rotary engines by implementing advanced fuel systems, ignition systems, control systems, and system optimization. In addition, the rotary engine configuration itself can be further optimized with the currently available sophisticated computational fluid dynamics tools. Engine efficiency can be improved by improving combustion efficiency and reducing cooling, exhaust, and friction losses, while maintaining combustion noise levels below a threshold. Improving combustion efficiency requires a thorough understanding of fuel spray, fuel-air mixing, ignition, and combustion processes. An inherently low compression ratio of the rotary engine requires external ignition sources, such as spark or glow plugs. Direct-injection fuel stratification would enable the rotary engine to improve combustion efficiency by keeping the fuel-air mixture from near the leading and trailing sides of the combustion chamber. This improved efficiency would reduce engine-out unburned and incompletely burned gases. Use of a turbocharger or supercharger would deliver higher airflow into the combustion chamber for lean combustion. As it is already proven in diesel engines compared to gasoline engines, lean combustion achieves higher combustion efficiency. Cooling heat loss can be reduced by an optimized combustion rate and the use of low thermal conductivity materials on the inner surfaces of the combustion chamber. Friction loss can be decreased by optimizing the seal loading and by using lower friction materials for the seals with minimal seal wear. Friction loss can also be decreased by reducing the seal area. Various areas for further research and development are proposed in the conclusion and recommendations section to improve efficiency, performance, durability, and reliability of the rotary engines. Several of these areas were studied in the past; however, the scope of work was insufficient, and crucial conclusions were not made. Furthermore, most of these works were performed more than a decade or two ago. Thus, the currently available advanced technologies were not used in their research and development. It is worthwhile to more thoroughly research the rotary engines by using advanced systems and tools available today.
Early technical paper by Kenichi Yamamoto, Kazuo Takata, Nagao Takeuchi, + Masaharu Shimoji 1967, 7 chapters, 7 pages > Content ... » 1. Introduction 1 » 2. Peculiar features of the rotary piston engine 1 » 3. Testing methods + test engines 2 » 3.1 Neasuring the pressure in the combustion chamber 2 » 3.2 Measuring the flame speed 2 » 3.3 Test condition 2 » 3.4 Test engines 3 » 4. Combustion during engine idling 3 » 4.1 Effects of induction system 3 » 4.2 Effects of port valve 4 » 4.3 Effects caused by number of spark plugs 4 » 5. Indicator diagrams at full throttle running 4 » 5.1 Effects of ignition timing 4 » 5.2 Effects caused by number of spark plugs 6 » 6. Flame speed 6 » 6.1 Relation between measuring position + flame speed measured 6 » 6.2 Effects of induction system 7 » 6.3 Effects of air/fuel ratio 7 » 6.4 Effects of ignition timing 8 » 7. Afterword 8 This paper deals with the problem of combustion in the NSU-Wankel type rotary piston engine, and presents a summary of the test results. The authors conducted many tests using both l-rotor engine and 2-rotor engines and cleared up the influences of variation of induction system, number of spark plugs, ignition timing and air-fuel ratio on combustion of fuel-air mixture in this new engine by measuring the gas pressure and flame speed by means of pressure indicators and ionization gaps, respectively. german keywords: Wankelmotor / Kreiskolbenmotor English Keywords: Wankel Engine / Wankel Rotary Engine / Rotary Piston Engine / Rotary Combustion Engine
Analysis of design features of small combustion engines produced within last years by worldwide best-known companies has been performed. The application areas of particular engine type (two-stroke engines, four-stroke engines) have been analyzed with regard to their design features. Engine swept volume has been taken as the common reference value for all types of engines. Trends in development of small combustion engines have been shown.
55 pages including patents Wo 2013,017,232 (AVL) US 3,39,724 by Daimler-Benz JP 60,001,327 (Mazda) + the papers: » Effect of spark plug arrangement on flame propagation of rotary engine » Amelioration of combustion of hydrogen rotary engine (influence of turbulence) german keywords: Wankelmotor / Kreiskolbenmotor English Keywords: Wankel Engine / Wankel Rotary Engine / Rotary Piston Engine / Rotary Combustion Engine
International Journal of Engineering Sciences & Research Technology, 2014
This document reviews some models of different advance engines such as rotary engine and free piston engine. Rotary engine and free piston engine have been used as one of the powerplants for unmanned aerial vehicles because of its many unique features, such as higher power density, light weight, simple design, smooth operation, low vibration, and compact size. However, it also has demerits, such as high fuel consumption and higher maintenance requirements. This report reviews the current status of the heavy-fueled rotary engine combustion technologies and overviews the technology gaps that need further research and development to improve its efficiency, performance, and durability and also reviews the history of rotary engine and free-piston gas Generators.
frank herfert
