References Aberger M, Otter M (2002) Modeling friction in Modelica with the Lund- Grenoble friction model. Proc 2nd Int Modelica Conf, Oberpfaffenhofen, pp 285–294 Adams G O, Bonnell R D (1968) Computer simulation of fluid power systems. Proc Nat Conf on Fluid Power, accessed via http://www.nfpa.com, pp 169– 182 Adler M (1934) Strömung in gekrümmten Rohren. Zeitschrift für angewandte Mathematik und Mechanik 14(5): 257–275 Afanasyev V V (1968) Variations of the effective areas of diaphragms. In: Aizer- man M A (ed) Pneumatic and hydraulic control systems. Pergamon Press, Ox- ford London Edinburgh New York, pp 311–319 Agel J S, Codina E (1996) Relation between sound pressure level and flow rate parameters of pneumatic silencers. Proc 47th Nat Conf on Fluid Power, Chi- cago, accessed via http://www.nfpa.com Al-Ibrahim A M, Otis D R (1992) Transient air temperature and pressure meas- urements during the charging and discharging processes of an actuating pneumatic cylinder. Proc 45th Nat Conf on Fluid Power, Chicago, accessed via http://www.nfpa.com, pp 233–239 Ams F, Oehrle U (1995) Eigensicheres Piezo-Ventil. Geringer Energieverbrauch und erweiterter Anwendungsbereich. Verfahrenstechnik 29(12): 33–34 Andersen B W (1967) The analysis and design of pneumatic systems. John Wiley & Sons, New York London Sydney Andersson S B, Bévengut G, Eckersten J, Ek G, Kalldin B (eds) (1975) Atlas Copco Air Compendium. Atlas Copco AB, Stockholm anon. (1956) ARCA 01065 pneumatic positioner - Technical description. ARCA- Regler GmbH, Tönisvorst anon. (1962) VDI/VDE-Richtlinie 2173 Strömungstechnische Kenngrößen von Stellventilen. Verein Deutscher Ingenieure, Düsseldorf anon. (1975) ISO 2533 Standard-Atmosphere. International Organization for Standardization, Genéve anon. (1984) ISO 2787 Rotary and percussive pneumatic tools – Performance tests. International Organization for Standardization, Genéve anon. (1985a) ISO 6432 Pneumatic fluid power – Single rod cylinders – 10 bar (1.000 kPa) series – Bores from 8 to 25 mm – Mounting dimensions. Interna- tional Organization for Standardization, Genéve anon. (1985b) ISO 5598 Fluid power systems and components – Vocabulary. In- ternational Organization for Standardization, Genéve
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References
Aberger M, Otter M (2002) Modeling friction in Modelica with the Lund-Grenoble friction model. Proc 2nd Int Modelica Conf, Oberpfaffenhofen, pp285–294
Adams G O, Bonnell R D (1968) Computer simulation of fluid power systems.Proc Nat Conf on Fluid Power, accessed via http://www.nfpa.com, pp 169–182
Adler M (1934) Strömung in gekrümmten Rohren. Zeitschrift für angewandteMathematik und Mechanik 14(5): 257–275
Afanasyev V V (1968) Variations of the effective areas of diaphragms. In: Aizer-man M A (ed) Pneumatic and hydraulic control systems. Pergamon Press, Ox-ford London Edinburgh New York, pp 311–319
Agel J S, Codina E (1996) Relation between sound pressure level and flow rateparameters of pneumatic silencers. Proc 47th Nat Conf on Fluid Power, Chi-cago, accessed via http://www.nfpa.com
Al-Ibrahim A M, Otis D R (1992) Transient air temperature and pressure meas-urements during the charging and discharging processes of an actuatingpneumatic cylinder. Proc 45th Nat Conf on Fluid Power, Chicago, accessedvia http://www.nfpa.com, pp 233–239
anon. (1962) VDI/VDE-Richtlinie 2173 Strömungstechnische Kenngrößen vonStellventilen. Verein Deutscher Ingenieure, Düsseldorf
anon. (1975) ISO 2533 Standard-Atmosphere. International Organization forStandardization, Genéve
anon. (1984) ISO 2787 Rotary and percussive pneumatic tools – Performancetests. International Organization for Standardization, Genéve
anon. (1985a) ISO 6432 Pneumatic fluid power – Single rod cylinders – 10 bar(1.000 kPa) series – Bores from 8 to 25 mm – Mounting dimensions. Interna-tional Organization for Standardization, Genéve
anon. (1985b) ISO 5598 Fluid power systems and components – Vocabulary. In-ternational Organization for Standardization, Genéve
298 References
anon. (1985c) Druckluftmotoren laufen trocken. VDI Nachrichten 39(19): 38anon. (1989) ISO 6358 Pneumatic fluid power – Components using compressible
fluids – Determination of flow-rate characteristics. International Organizationfor Standardization, Genéve
anon. (1996a) Das A und O der Endlagendämpfung. AB Rexroth Mecman, Stock-holm
anon. (1996b) Air braking equipment for towed vehicles in accordance with coun-cil directive 71/320/ EEC. Diagrammatic views and description of brakingsystems and air braking equipment. WABCO Fahrzeugbremsen GmbH, Han-nover
anon. (1998) ISO 4414 Pneumatic fluid power – General rules relating to systems.International Organization for Standardization, Genéve
anon. (2000a) ISO/DIS 8778 Pneumatic fluid power – Standard reference atmos-phere. International Organization for Standardization, Genéve
anon. (2000b) ISO 6953-1 Pneumatic fluid power – Compressed air pressureregulators and filter-regulators – Part 1: Main characteristics to be included inliterature from suppliers and product-marking. International Organization forStandardization, Genéve
anon. (2000c) ISO 6953-2 Pneumatic fluid power – Compressed air pressureregulators and filter-regulators – Part 2: Test methods to determine the maincharacteristics to be included in literature from suppliers. International Or-ganization for Standardization, Genéve
anon. (2000d) Know How in Pneumatics – components catalogue. Rexroth Mec-man, Hannover
anon. (2000e) C4 Katalog im PDF-Format. SMC Pneumatik GmbH, Egelsbachanon. (2000f) Japanese Industrial Standard JIS B 8390 Pneumatic fluid power –
Components using compressible fluids – Determination of flow-rate charac-teristics. Translated and published by Japanese Standards Association, Tokyo
anon. (2001a) ISO 10099 Pneumatic fluid power – Cylinders – Final examinationand acceptance criteria. International Organization for Standardization,Genéve
anon. (2001b) ISO 12238 Pneumatic fluid power – Directional control valves –Measurement of shifting time. International Organization for Standardization,Genéve
anon. (2003) Technische Information Prozessmodul SPEEDy. Kuhnke GmbH,Malente
anon. (2004a) ISO 15552 Pneumatic fluid power – Cylinders with detachablemountings, 1.000 kPa (10 bar) series, bores from 32 mm to 320 mm – Basic,mounting and accessories dimensions. International Organization for Stan-dardization, Genéve
anon. (2004b) Product service life at Festo. Brochure 906.FIF. Festo AG & Co,Esslingen
anon. (2005) High-Speed – gewußt wie. Ölhydraulik und Pneumatik o+p49(9): 538–540
299
anon. (2006a) Dymola – Multi-engineering modeling and simulation. Accessedvia http://www.Dynasim.com
anon. (2006b) Modelica portal. Accessed via http://www.modelica.org/http://www.modelica.org/
library/PneuLibAraki K, Chen N (1999) Pressure versus flow characteristics of a diaphragm type
pneumatic pressure control proportional valve. Proc 4th JHPS Int Symp onFluid Power, Tokyo, pp 413–418
Araki K, Tanahashi T, Nishimura M (1982) Measurement of the friction forces ofpneumatic cylinders. Proc 5. Aachener Fluidtechnisches Kolloquium, Aachen,vol 3, pp 55–74
Araki K, Yumuro A, Chen N, Ishino Y (1993) Static characteristics of a pneu-matic pressure control proportional valve with nozzle-flapper mechanism.Proc 2nd JHPS Int Symp on Fluid Power, Tokyo, pp 719–72
Atherton P D, Uchino K (1998) New development in piezo motors and mecha-nism. Proc Actuator 98, Bremen, pp 164–169
Backé W, Ohligschläger O (1989) A model of heat transfer in pneumatic cham-bers. The Journal of Fluid Control 20: 61–78
Backé W, Bialas V, Egberts M (1974) Untersuchungen über das dynamische Ver-halten pneumatischer Stellantriebe. Forschungsberichte des Landes Nord-rhein-Westfalen Nr. 2434, Westdeutscher Verlag, Opladen
Baehr H D, Schwier K (1961) Die thermodynamischen Eigenschaften der Luft imTemperaturbereich zwischen minus 210 Grad C und plus 1250 Grad C bis zuDrücken von 4500 bar. Springer, Berlin Göttingen Heidelberg
Bala H, Giesen N, Schmidtke W (1986) Positionierbare Pneumatikantriebe mitgroßer Variantenvielfalt. Ölhydraulik und Pneumatik o+p 30(11): 843–846
Balje O E (1981) Turbomachines, a guide to design, selection, and theory. Wiley,New York
Ballard R L (1974) The dynamic characteristics of pneumatic actuator and valvesystems. Ph.D. thesis, University of Bath
Baoren L, Zhuangyun L (1997) Study on adaptive control for a pneumatic positionservo system. Advances in Modelling and Control 49: 21–28
Barber A (1997) Pneumatic Handbook. 8th edn. Elsevier Advanced Technology,Oxford
Barker H F (1976) Design of a state observer for improving the response of a lin-ear pneumatic servo-actuator. Proc Int Conf on Hydraulics, Pneumatics andFluidics in Control and Automation, Toronto, pp 43–56
Barth H-J (1994) Einfache Kennzeichnung und Berechnung von Druckverlustenin der Pneumatik. Ölhydraulik und Pneumatik o+p 38(9): 564–569
Barth H-J (2000) Ungekühlte Druckluft für optimale Energienutzung in derPneumatik. Ölhydraulik und Pneumatik o+p 44(5): 304–306
Barth H-J (2003) Wie kalt wird ausströmende Druckluft? Ölhydraulik und Pneu-matik o+p 47(1): 43–46
anon. (2006c) Modelica portal – PneuLib. Accessed via
References
300 References
Bauer F (2002) Maßnahmen und Methoden zur Flexibilisierung pneumatischerGreifsysteme. Doctoral dissertation, Rheinisch-Westfälische TechnischeHochschule Aachen
Beater P (1999) Entwurf hydraulischer Maschinen. Springer, Berlin HeidelbergNew York
Beater P (2000) Modeling and digital simulation of hydraulic systems in designand engineering education using Modelica and HyLib. Proc Modelica Work-shop 2000, Lund, pp 33–40
Beater P (2004) Modelling and control of pneumatic vane motors. InternationalJournal of Fluid Power 5(1): 7–16
Becker R J, Mueller J G (1993) Electronically controlled turbine-driven airstartermotor. Proc Int Truck and Bus Meeting and Exposition, Detroit, Michigan,SAE Technical Paper Series 933064
Belforte G, Raparelli T (1997) Friction analysis of pneumatic semi-rotary actua-tors. Tribology Transactions 40: 57– 62
Belforte G, D’Alfino N, Raparelli T (1989) Experimental analysis of frictionforces in pneumatic cylinders. The Journal of Fluid Control 20(1): 42–60
Belforte G, Carello M, D’Alfio N (1995a) Effects of geometry on flow in noncon-ventional pneumatic valves. Proc 9th World Congress on Theory of Machinesand Mechanisms IFToMM, pp 2680–2685
Belforte G, Carello M, D’Alfio N (1995b) Study of digital pneumatic valves ge-ometry. Proc 4th Scandinavian Int Conf on Fluid Power, Tampere, pp 467–480
Belforte G, Gastaldi L, Sorli M (1998) Properties and mechanical performance ofPZT actuators. Proc Actuator 98, Bremen, pp 313–317
Belforte G, Manuello Bertetto A, Liu S, Mazza L (1999) Wear and failure analysisin pneumatic cylinders under radial load. Proc 11th Int Sealing Conf, Dresden,pp 317–330
Belforte G, Mattiazzo G, Mauro S (2000) Design criteria for flow proportionalcontrol valves. Proc FLUCOME 2000, Sherbroke (QC)
Belforte G, Sorli M, Gastaldi L (2002) Experimental and numerical analysis onbimorph piezo-actuators. Proc Actuator 2002, Bremen, pp 417–420
Belforte G, Raparelli T, Mazza L, Trivella A (2005) Analysis, design, and com-parison of different types of pistons for sealless pneumatic cylinders andvalves. Tribology Transactions 48(3): 377–388
Benchabane S, Lecerf J P, Bonis P M (1994) Economic measurement of ISOpneumatic coefficients. Proc 11. Aachener Fluidtechnisches Kolloquium,Aachen, pp 131–141
Benedict R P (1971) Generalized contraction coefficient of an orifice for subsonicand supercritical flow. Trans ASME – Journal of Basic Engineering93(6): 99–120
Beresowez G T, Dimitrijew W N, Nadshafow E M (1958) Über die zulässigenVereinfachungen bei der Berechnung pneumatischer Regler. Feinwerktechnik62(5): 159–167
301
Berninger J F (2002) Comparing ISO sonic flow to ANSI Cv in pneumatic direc-tional control valves. Proc 49th Nat Conf on Fluid Power, Las Vegas, Nevada,pp 153–160
Bharath S, Nakra B C, Gupta K N (1990) Mathematical model of a railway pneu-matic brake system with varying cylinder capacity effects. Trans ASME –Journal of Dynamic Systems, Measurement, and Control 112(9): 456–462
Bialas V (1973) Ein Beitrag zur Klärung des Verhaltens von Pneumatikzylindern.Doctoral dissertation, Rheinisch-Westfälische Technische Hochschule Aachen
Bideaux E, Scavarda S (2000) Pneumatic pipes – experimental and simulation ap-proach. Proc Bath Workshop on Power Transmission and Motion ControlPTMC 2000, Bath, pp 157–169
Bowns D E, Ballard R L (1972) Digital computation for the analysis of pneumaticactuator systems. Proc Instn mech Engrs 186: 881–889
Brann R P (1966) Linear analysis of a pneumatic differential actuator with posi-tion feedback for prosthesis control. Control 8: 428–430
Brassart P, Scavarda S (1997) Modelling a pneumatic braking system. Proc 5thScandinavian Int Conf on Fluid Power, Linköping, pp 353–362
Brower W B (1990) Theory, tables, and data for compressible flow. HemispherePublishing, New York Washington Philadelphia London
Brower W B, Eisler E, Filkorn E J, Gonenc J, Plati C, Stagnitti J (1993) On thecompressible flow through an orifice. Trans ASME – Journal of Fluids Engi-neering 115: 660–664
Brückner W (1967) Die Hauptabmessungen nichtumsteuerbarer Druckluft-Lamellenmotoren mit radialer Lamellenanordnung für niedrigen spezifischenLuftverbrauch. Doctoral dissertation, Bergakademie Freiberg
Burrows C R (1969) Effect of position on stability of pneumatic servomechanism.Proc Instn mech Engrs – Part C Journal Mechanical Engineering Science11: 615–616
Burrows C R, Webb C R (1966) Use of root loci in design of pneumatic servo-motors. Control 8: 423–427
Burrows C R, Peckham R G (1977) Dynamic characteristics of a pneumatic flap-per valve. Proc Instn mech Engrs – Part C Journal Mechanical EngineeringScience 19(3): 113–121
Caldwell D G, Mecrano-Cerda G A, Goodwin M (1995) Control of pneumaticmuscle actuator. IEEE Control Systems 15: 40–48
Carello M, Ivanov A, Mazza L (2006) Experimental and theoretical methods toevaluate the pressure losses in air distribution lines. International Journal ofFluid Power 7(2): 5–9
Cellier F E (1992) Ordinary differential equation models: Numerical integration ofinitial-value problems. In: Atherton D P, Borne P (eds) Concise encyclopaediaof modelling & simulation. Pergamon Press, Oxford New York Seoul Tokyo
Çengel A (1997) Introduction to thermodynamics and heat transfer.Irwin/McGraw-Hill, Boston Burr Ridge Dubuque Madison New York
Chadwick T H, Brady P L (1957) New design concepts for high pressure pneu-matics systems. Proc 13th Nat Conf on Fluid Power, accessed viahttp://www.nfpa.com, pp 232–251
References
302 References
Champagne R P, Boyle S J (1996) Optimizing valve actuator parameters to en-hance control valve performance. ISA Transactions 35: 217–223
Chen M F (1995) Zustandsgrößengenerierung und ihre Rückführung bei fluid-technischen Positionierantrieben. Doctoral dissertation, Rheinisch-Westfälische Technische Hochschule Aachen
Chen N, Araki K (1995) Pressure versus flow characteristics of a pneumatic pres-sure control proportional valve with diaphragms. Proc 4th Scandinavian IntConf on Fluid Power, Tampere, pp 453–466
Cheng M P, Pourmovahed A, Griffith A M (1993) Comparison of electric andpneumatic power tools – Part I: Mechanical characteristics and cost. SAETrans – Journal of Passenger Cars 102(6): 2271–2285
Cherry C, Gibbons M, Ronayne J (1974) The origins of the air-turbine dentalhandpiece. British Dental Journal 136(6): 469–472
Chillari S, Guccione S, Muscato G (2001) An experimental comparison betweenseveral pneumatic position control methods. Proc 40th IEEE conf on decisionand control, vol 2, pp 1168–1173
Cho S, Fiedler M, Rüdiger F, Helduser S (2006) Virtual-design-model-based pres-sure-tracking control of high-dynamic pneumatic valves using a sliding modecontroller combined with a proportional-integral-derivative scheme. ProcInstn mech Engrs – Part I Journal of Systems and Control Engineering220(5): 353–365
Choi S B, Yoo J K (2004) Pressure control of a pneumatic valve system using apiezoceramic flapper. Proc Instn mech Engrs – Part C Journal MechanicalEngineering Science 218: 83–91
Chou C-P, Hannaford B (1996) Measurement and modeling of McKibben pneu-matic artifical muscle. IEEE Transactions on Robotics and Automation12(1): 90–102
Colin S, Bonnet A, Caen R (1996) A new high supply pressure pneumatic flapper-nozzle with linear behaviour. Trans ASME – Journal of Dynamic Systems,Measurement, and Control 118(6): 259–266
Coughran M T (2003) Dynamic air consumption of control valves. measurement +control 36(8): 235–238
Crnojevic C, Roy G, Bettahar A, Florent P (1997) The influence of the regulatordiameter and injection nozzle geometry on the flow structure in pneumaticdimensional control systems. Trans ASME – Journal of Fluid Engineering119(9): 609–615
Croser P, Ebel F (1999) Pneumatik - Grundstufe. 2nd edn. Springer, Berlin Hei-delberg NewYork
Csanady G T (1964) Theory of turbomachines. McGraw-Hill, New YorkCundiff J S (2001) Fluid power circuits and controls – Fundamentals and applica-
tions. CRC Press, Boca Raton New York Washington DCCzinki A (2001) Konstruktion, Aufbau und Regelung servopneumatischer Robo-
D'Alfio N, Ferraresi C (1988) Analysis of the air flow through pressure regulators.Proc XIth Int Conf on Fluidics, Jablonna, pp 84–91
303
Daerden F, Lefeber D (2001) The concept and design of pleated pneumatic artifi-cial muscles. International Journal of Fluid Power 2(3): 41–50
Daser E (1969) Das Reaktionsmoment hochtouriger Lamellenmotoren, seine Mes-sung und Bedeutung für die Auslegung der Motoren. Doctoral thesis, Tech-nische Universität Clausthal
Davis S, Caldwell D G (2006) Braid effects on contractile range and friction mod-eling in pneumatic muscle actuators. The International Journal of RoboticsResearch 25(4): 359–369
Denker K (1987) Pneumatisches Regelventil als Stellglied in der Automa-tisierungstechnik. Ölhydraulik und Pneumatik o + p 31(3): 244–246
Det F, Scavarda S, Richard E (1989) Simulated and experimental study of charg-ing and discharging of a cylinder by using an electro-pneumatic servovalve.Proc 1st JHPS Int Symp on Fluid Power, Tokyo, pp 321–328
Dixon S L (1978) Fluid mechanics, thermodynamics of turbomachinery. 3rd edn.Pergamon Press, Oxford
Dunn A L, Heydinger J, Rizzoni G, Guenther D A (2003) Empirical models forcommercial vehicle brake torque from experimental data. Proc SAE WorldCongress, Detroit, Michigan, pp 257–268, SAE Paper No. 2003-01-1325
Dyson J E, Darvell B W (1993) The development of the dental high-speed air tur-bine handpiece – Part 1 and 2. Australian Dental Journal 38(1): 49–58 and38(2): 131–143
Dyson J E, Darvell B W (1999a) Flow and free running speed characterization ofdental air turbine handpieces. Journal of Dentistry 27(7): 465–477
Dyson J E, Darvell B W (1999b) Torque, power and efficiency characterization ofdental air turbine handpieces. Journal of Dentistry 27(8): 573–586
Eby W R (2005) Feasibility analysis of a powered lower-limb orthotic for the mo-bility impaired user. Master thesis, University of Waterloo. Accessed viahttp://etd.uwaterloo.ca/etd/wreby2005.pdf
Eckersten J (1975a) Simplified flow calculations for pneumatic components. In:Andersson S B, Bévengut G, Eckersten J, Ek G, Kalldin B (eds) Atlas CopcoAir Compendium. Atlas Copco AB, Stockholm, pp 183–192
Eckersten J (1975b) Pneumatic transmission of signals. In: Andersson S B,Bévengut G, Eckersten J, Ek G, Kalldin B (eds) Atlas Copco Air Compen-dium. Atlas Copco AB, Stockholm, pp 211–218
Elmqvist H (1978) A structured model language for large continuous systems.Ph.D. thesis, Lund Institute of Technology
Elmqvist H, Boudaud F, Broenink J, Brück D, Ernst T, Fritzson P, Jeandel A, Jus-lin K, Klose M, Mattsson S E, Otter M, Sahlin P, Tummescheit H, Vanghe-luwe H (1997) Modelica – A unified object-oriented language for physical
http://www.Modelica.org/documents/
Eschmann R (1992) Reibkräfte an Pneumatikdichtungen. Proc 10. Aachener Flu-idtechnisches Kolloquium, Aachen, pp 49–69
Eschmann R (1994) Modellbildung und Simulation pneumatischer Zylinderan-triebe. Doctoral dissertation, Rheinisch-Westfälische Technische HochschuleAachen
References
systems – version 1 September 1997. accessed via
304 References
Esposito A (2000) Fluid power with applications. 5th edn. Prentice Hall Interna-tional Inc., Upper Saddle River, New Jersey
Falkman, H (1975a) Flow of gases in pipes. In: Andersson S B, Bévengut G, Eck-ersten J, Ek G, Kalldin B (eds) Atlas Copco Air Compendium. Atlas CopcoAB, Stockholm, pp 149–192
Falkman, H (1975b) Compressed air distribution. In: Andersson S B, Bévengut G,Eckersten J, Ek G, Kalldin B (eds) Atlas Copco Air Compendium. AtlasCopco AB, Stockholm, pp 473–494
Falkman H (1975c) The motor process. In: Andersson S B, Bévengut G, EckerstenJ, Ek G, Kalldin B (eds) Atlas Copco Air Compendium. Atlas Copco AB,Stockholm, pp 125–148
Fasol K H, Jörgl H P (1979) Zur Modellbildung und Simulation instationärerRohrströmungen. Regelungstechnik rt 27(12): 387–393
Fernandez R, Woods R L (2000) The use of helium gas for high-performance ser-vopneumatics. Proc 48th Nat Conf on Fluid Power, Chicago, IL, accessed viahttp://www.nfpa.com, pp 431–439
Ferraresi C, Giraudo P, Quaglia G (1994) Non-conventional adaptive control of aservopneumatic unit for vertical load positioning. Proc 46th Nat Conf on FluidPower, Anaheim, accessed via http://www.nfpa.com, pp 319–333
Ferraresi C, Franco W, Manuello Bertetto A (1999) Straight fibres pneumaticmuscle: an actuator with high traction force. Proc 6th Scandinavian Int Confon Fluid Power, Tampere, pp 787–798
Feuser A (1983) Ein Beitrag zur Auslegung ventilgesteuerter Vorschubantriebe imLageregelkreis. Doctoral dissertation, Universität Erlangen-Nürnberg
Fiedler M, Helduser S, Rüdiger F (2005) Virtual design of high dynamic pneu-matic valves. Proc Power Transmission and Motion Control PTMC, Bath, pp255–265
Figliolini G, Almondo A, Sorli M (2004) Modelling and experimental validationof a pneumatic servo-solenoid valve. Proc Power Transmission and MotionControl PTMC, Bath, pp 85–98
Fleischer H (1995) Manual of pneumatic system operation. McGraw-Hill, NewYork San Francisco Washington
Fok S C, Ong E K (1995) Position control and repeatability of a pneumatic rodlesscylinder system for continuous positioning. Robotics and Computer IntegratedManufacturing 15: 365–371
Fox R W, McDonald A T, Pritchard P J (2004) Introduction to fluid mechanics.6th edn. John Wiley and Sons, Inc., Hoboken, NJ
French M, Ramirez A C (1996) Towards a comparative study of quarter-turnpneumatic valve actuators. Proc Instn Mech Engrs 210: 543–552
Fritzson P A (2004) Principles of object-oriented modeling and simulation withModelica 2.1. IEEE Press, Piscataway, NJ
Frühauf F, Jäker K P, Siemensmeyer H (1983) Rechnergestützte Positionierungeines Pneumatikzylinders mit Magnetventilen. Ölhydraulik und Pneumatiko+p 27(5): 359–363
Fujita T, Kagawa T, Takeuchi M (1994) Disturbance characteristics of controlvalve positioner. Proc FLUCOME’94, Toulouse, pp 847–852
305
Fujita T, Jang J, Kagawa T, Takeuchi M (1996) Dynamics of pneumatic cylindersystems. Proc 3rd JHPS Int Symp on Fluid Power, Yokohama, pp 259–264
Fujita T, Tokashiki L R, Kagawa T (1999) Stick-sip motion in peumatic clindersdriven by meter-out circuit. Proc 4th JHPS Int Symp on Fluid Power, Tokyo,pp 131–136
Funk J E, Robe T R (1970) Transients in pneumatic transmission lines subjectedto large pressure changes. Int J mech Sci 12: 245–257
Gerts E V, Gerts M E (1999) Selection of the parameters of a reversible pneumaticactuator. Journal of Machinery Manufacture and Reliability 6: 1–6
Gidlund P L (1977) Auslegung pneumatischer Schaltungen – Sizing pneumaticcomponents. Proc Internationale Fachtagung zur Systemschau “Antreiben –Steuern – Bewegen”, Hannover, pp 240–261
Goedecke W D (1980) Möglichkeiten zur Steuerung und Regelung pneumatischerAntriebe. Proc 4. Aachener Fluidtechnisches Kolloquium, Aachen, pp 3–24
Gödert H (1995) Der geregelte Pneumatikantrieb – eine interessante Alternative.Ölhydraulik und Pneumatik o+p 39(5): 397–400
Gödert H (2001) Pneumatisches Proportional-Druckregelventil mit digitaler On-board-Elektronik. Ölhydraulik und Pneumatik o+p 45(6): 429–433
Göttert M (2004) Bahnregelung servopneumatischer Antriebe. Shaker Verlag,Aachen
Göttert M, Neumann R (1997) Genaue Bahnregelung für servopneumatische An-triebe. Proc II. Deutsch-Polnisches Seminar “Innovation und Fortschritt in derFluidtechnik”, Warschau, pp 34–53
Goldfarb M, Celanovic N A (1997) A lumped parameter electromechanical modelfor describing the nonlinear behavior of piezoelectric actuators. Trans ASME– Journal of Dynamic Systems, Measurement, and Control 119: 478–485
Goodman R B (1997) A primer on pneumatic valves and controls. Krieger Pub-lishing Company, Malabar, Florida
Goodson R E, Leonard R G (1972) A survey of modeling techniques for fluid linetransients. Trans ASME – Journal of Basic Engineering 94(2): 474–482
Graham J E (1965) Pneumatic cushioning. February 3, 1965 Machinery (London),pp 264–266
Graham R G (1981) Turbine air motors shed their high-cost image. Machine De-sign 53(11): 93–98
Grassl H (1981) Pneumatische Schwingungsdämpfung – Theorie und Anwendun-gen. Reihe H, Ingenieurwissenschaften. Schweizer Buchagentur, Bern
Guenther R, Perondi E C, DePieri E R, Valdiero A C (2006) Cascade controlledpneumatic positioning system with LuGre model based friction compensation.J of the Braz Soc of Mech Sci & Eng 28(1): 48–57
Güvenc L, Srinivasan K (2000) Modeling and parameter identification of a pneu-matic constant force device. Turk J Engin Environ Sci 24: 383–399
Haack S (1991) Theoretische und experimentelle Untersuchungen zur Aussage-fähigkeit strömungstechnischer Kenngrößen an ausgewählten Strukturenpneumatischer Steuerventile. Doctoral dissertation, Pädagogische HochschuleErfurt/Mühlhausen
References
306 References
Haaland S E (1983) Simple and explicit formulas for the friction factor in turbu-lent pipe flow. Trans ASME – Journal of Fluids Engineering 105(3): 89–90
Haden D (1980) Rolling diaphragm air cylinders. OEM Design 78(Nov): 78–79Hahn H (2000) Nichtlineare Regelung eines servopneumatischen Antriebs. Auto-
matisierungstechnik at 48(3): 140–150Haller R, Latino F (1996) Design considerations and future trends in pneumatics
and electropneumatic systems. Proc 47th Nat Conf on Fluid Power, Chicago,accessed via http://www.nfpa.com
Han B, Fujita T, Kagawa T, Kawashima K, Cai M (1999) Flow rate coefficientmeasurement by using pressure discharge velocity of pneumatic RC circuit.Proc 4th JHPS Int Symp on Fluid Power, Tokyo, p 143–148
Han Wee Ng, Alleyne A (2000) Modeling and bumpless learning control of posi-tion and pressure for an electropneumatic actuator. Proc Fluid Power Systems& Technology 2000, Orlando, Florida, pp 7–8
Han B J, Kawashima K, Fujita T, Kagawa T (2001) Flow rate characteristicsmeasurement of pneumatic valves by pressure response. Proc 5th Int Conf onFluid Power Transmission and Control, Hangzhou, pp 200–204
Hansson C (1975) Rotary air motors. In: Andersson S B, Bévengut G, Eckersten J,Ek G, Kalldin B (eds) Atlas Copco Air Compendium. Atlas Copco AB,Stockholm, pp 329–362
Hantke P (2003) Wasserhydraulik im Bergbau – Entwicklung eines piezo-betätigten Vorsteuerschaltventils. Ölhydraulik und Pneumatik o+p 47(6): 424-–430
Hehn A H (1995) Fluid power troubleshooting. 2nd edn. Marcel Dekker, Inc.,New York Basel Hong Kong
Hennig H (1977) Warum vereisen Pneumatikanlagen? msr 20(6): 335–358Hennig H (1979) Zeit- und Bewegungsverhalten pneumatischer Linearantriebe.
Proc 3. Fachtagung Hydraulik und Pneumatik, Dresden, pp 257–272Hennig H (1982) Dimensionierung pneumatischer Übertragungsleitungen. msr
25(4): 198–204Henningson G (1975) Linear motors. In: Andersson S B, Bévengut G, Eckersten J,
Ek G, Kalldin B (eds) Atlas Copco Air Compendium. Atlas Copco AB,Stockholm, pp 360–390
Henri P D, Hollerbach J M, Nahvi A (1998) An analytical and experimental in-vestigation of a jet pipe controlled electropneumatic actuator. IEEE Trans RobAutonm 14(4): 601–611
Heras de las S (2001) A new experimental algorithm for the evaluation of the truesonic conductance of pneumatic components using the characteristic unload-ing time. International Journal of Fluid Power 2(1): 17–24
Heras de las S (2003) Improving gas dynamic models for pneumatic systems. In-ternational Journal of Fluid Power 4(4): 47–56
Hesse S (2003) The fluidic muscle in application. Blue digest on automation.Festo AG & Co. KG, Esslingen
307
Hippe P (1988) Digitale Regelung eines pneumatischen Linearantriebs mit schal-tendem Stellglied. Proc 8. Aachener Fluidtechnisches Kolloquium, Aachen,pp 67–84
Hong Y-S (1986) Berechnung, Verbesserung und Weiterentwicklung von Propor-tionalmagneten als elektromechanischer Signalumformer für Proportional-ventile. Doctoral dissertation, Rheinisch-Westfälische Technische HochschuleAachen
Hougen J O, Martin O R, Walsh R A (1963) Dynamics of pneumatic transmissionlines. Control Engineering 10(9): 114–117
Howe R E (2004) Five myths of pneumatic motion control. Hydraulics and pneu-matics 36(9): 36–38
Hübl W, Giesen N (1996) Pneumatische Türantriebe. Ölhydraulik und Pneumatiko+p 40(3): 196–201
Hullender D A, Woods R L (1985) Modeling of fluid control components. ProcInt Conf on Global Techniques, University of Texas at Arlington, pp 608–619
Iberall A S (1950) Attenuation of oscillatory pressures in instrument lines. Journalof the Research of the National Bureau of Standards 45: 85–108
Ikebe Y, Nakada T (1974) On a piezoelectric flapper type servovalve operated bya pulse-width-modulated signal. Trans ASME – Journal of Dynamic Systems,Measurement, and Control 96(1): 88–94
Ikeo S, Zhang H, Takahashi K, Sakurai Y (1993) Simulation of pneumatic sys-tems using BGSP (Bond Graph Simulation Program). Proc 6th Bath Int FluidPower Workshop, Bath, pp 80–94
Inoue K (1988) Rubbertuators and applications for robots. In: Bolles R and Roth B(eds) Robotics Research. 4th Int Symp, MIT Press, pp 57–63
Ioannidis I (1987) Servopneumatische Drehantriebe für Lageregelungen. Doctoraldissertation, Rheinisch-Westfälische Technische Hochschule Aachen
Istók B, Szente V, Vad J (2003) Behavior of a pneumatic pressure regulator valveunder leakage circumstances. Proc 2nd Int Conf on Heat Transfer, Fluid Me-chanics and Thermodynamics HEFAT, Victoria Falls, Zambia
Itoh K, Machiyama T, Mori H, Outo E (1989) An experimental study on compari-son between two methods (steady flow method & discharging method) oftesting effective area of solenoid valve. Proc 1st JHPS Int Symp on FluidPower, Tokyo, pp 297–304
Jebar H S (1977) Design of pneumatic actuator systems. Ph.D. thesis, Universityof Nottingham
Jebar H S, Lichtarowicz A, Roylance T F (1975) Thermodynamic analysis ofcharging processes. Proc 4th BHRA Fluid Power Symp, Sheffield, pp 1–17
Jebar H S, Roylance T F, Lichtarowicz A (1978) Nomogram methods for the de-sign of pneumatic cylinder systems. Proc 5th Int Fluid Power Symp, ppA.4.47
Jelali M, Kroll A (2002) Hydraulic servo-systems – modelling, identification andcontrol. Springer, London Berlin Heidelberg New York
Jeschke N (1968) Untersuchung der Stopfbuchsenreibung an Stellventilen mitpneumatischem Membranantrieb. Regelungstechnische Praxis rtp 10(3): 105–108
References
308 References
Jiménez A F, García J P (2004) Compressible bench flow adaptions to the experi-mental characterization of pneumatic components. Application to the determi-nation of flow-rate characteristics of a Festo MPYE-5-3/8-010-B proportionalvalve. Proc 3rd FPNI Ph.D. Symp, Terrassa
Kaasa G-O, Chapple P J, Lie B (2004) Modeling of an electro-pneumatic cylinderactuator for nonlinear and adaptive control, with application to clutch actua-tion in heavy-duty trucks. Proc 3rd FPNI Ph.D. Symp, Terrassa
Kagawa T, Shimizu M (1988) Heat transfer effect on the dynamics of pneumaticRC circuit. Proc FLUCOME’88, Sheffield, pp 498–502
Kagawa T, Fujita T, Takeuchi M (1995) Dynamic response and simulation modelof pneumatic pipe system. Proc 8th Bath Int Fluid Power Workshop – Designand Performance, Bath, pp 286–298
Kagawa T, Cai M L, Fujita T, Takeuchi M (2000a) Energy consideration and tem-perature measurement of pneumatic cylinder actuating system. ProcFLUCOME 2000, Sherbroke (QC)
Kagawa T, Tokashiki L R, Fujita T, Sakaki K, Makino F (2000b) Accurate posi-tioning of a pneumatic servosystem with air bearings. Proc Bath Workshop onPower Transmission and Motion Control PTMC 2000, Bath, pp 257–268
Kage K, Kawagoe S, Matsuo K, Tanaka H, Hasegawa I (1985) Attenuation of ex-pansion waves in a pipe of railway’s pneumatic brake system. ProcFLUCOME’85, Tokyo, pp 137–142
Kajima T, Kawamura Y (1995) Development of a high-speed solenoid valve: in-vestigation of solenoids. IEEE Transactions on Industrial Electronics 42: 1–8
Kajima T, Nakamura Y, Sonoda K (1992) Development of a high-speed solenoidvalve: investigation of the energizing circuits. Proc 1992 Int Conf on Indus-trial Electronics, Control, Instrumentation and Automation, San Diego, Cali-fornia, pp 564–569
Kanai E, Sawada T, Tanahashi T, Ando T (1985) Dynamic characteristics ofpneumatic transmission lines. Proc FLUCOME’85, Tokyo, pp 123–128
Karam J T, Franke M E (1967) The frequency response of pneumatic lines. TransASME – Journal of Basic Engineering 90(6): 371–378
Kastner L J, Williams T J, Sowden R A (1964) Critical-flow nozzle meter and itsapplication to the measurement of mass flow rate in steady and pulsatingstreams of gas. Proc Instn mech Engrs – Part C Journal Mechanical Engi-neering Science 6(1): 88–98
Kawakami Y, Akao J, Kawai S, Machiyama T (1988) Some considerations on thedynamic characteristics of pneumatic cylinders. The Journal of Fluid Control19(2): 22–36
Kawakami Y, Takeda R, Kawai S (1991) Some considerations on the generalized
San Francisco, California, pp 543–548Kawashima K, Ishii Y, Funaki T, Kagawa T (2004) Determination of flow rate
characteristics of pneumatic solenoid valves using an isothermal chamber.Trans ASME – Journal of Fluids Engineering 126(2): 273–279
Kayihan A, Doyle F J III (2000) Friction compensation for a process controlvalve. Control engineering practice 8(7): 799–812
FLUCOME’91,conditions for high-speed driving of pneumatic cylinders. Proc
309
Kentschke T (2004) Druckluftmaschinen als Generatorantrieb in Warm-luftspeichern. Doctoral dissertation, Technische Universität Clausthal
Kim D S, Lee W H, Lee M C (2003) Design and experiment of the direct drive-type pneumatic servo valve. Proc Workshop Power Transmission and MotionControl PTMC 2003, Bath, pp 349–356
King T, Pozzi M, Manara A (2000) Piezoactuators for “real world” applications –Can they deliver sufficient displacement? Power Engineering Journal14(3): 105–110
Kirshner J M, Katz S (1975) Design theory of fluidic components. AcademicPress, New York San Francisco London
Koenig B, Ohligschläger O (1989) Ein “intelligenter” elektropneumatischer Stel-lungsregler. Automatisierungstechnische Praxis atp 31(8): 367–373
Kohl A (1973) Fluidische Leitungsdiskontinuitäten, Verzweigungen und ihre An-wendung in Filterschaltungen. Doctoral dissertation, Rheinisch-WestfälischeTechnische Hochschule Aachen
Kollmann E (1968) Wirkung wesentlicher Nichtlinearitäten auf die Stabilität undden statischen Fehler von Stellungsreglern. Automatik pp 379–383
Kolvenbach H (1990) Drehschieber-Servoventile für die Pneumatik. Proc 9.Aachener Fluidtechnisches Kolloquium, Aachen, pp 61–75
Kolvenbach H (1991) Drehschieber-Servoventile für die Pneumatik. Ölhydraulikund Pneumatik o + p 35(1): 43–47
Ko cielny J M, Syfert M, Barty M (1999) Fuzzy-logic fault diagnosis of indus-trial process actuators. Int J Appl Math and Comp Sci 9(3): 653–66
Künzel O (1970) Das Übertragungsverhalten pneumatischer Leitungen. Doctoraldissertation, Technische Hochschule München
Kukulka D J, Benzoni A, Mollendorf J C (1994) Digital simulation of a pneumaticpressure regulator. Simulation 63(4): 252–266
Lai J-Y, Menq C-H, Singh R (1990) Accurate position control of a pneumatic ac-tuator. Trans ASME – Journal of Dynamic Systems, Measurement, and Con-trol 112(12): 734–739
Latino F (1996) Air servo positioning systems, single and multiple axis. Proc 47thNat Conf on Fluid Power, Chicago, accessed via http://www.nfpa.com
Lebig H (1971) Das Durchflußvermögen von Pneumatik-Ventilen. Ingenieur di-gest – Part 1: 10(11): 59–63, Part 2: 10(12): 75–79
Lee S-Y, Blackburn J F (1952) Contributions to hydraulic control: 1 Steady-stateaxial forces on control-valve pistons. Trans ASME 74(8): 1005–111
Leonhard A, Helduser S, Rüdiger F (2006) CFD simulation and experimentalvisualisation of transient flow in pneumatic seated valves. Proc 5th Interna-tional Fluid Power Conference, Aachen, pp 97–108
Leufgen M (1988) Auslegung und Untersuchung geeigneter elektromechanischerWandler für stetige elektropneumatische Ventile. Proc 8th Aachener Fluid-technisches Kolloquium, Aachen, pp 261–278
Leufgen M (1992) Pneumatische Positionierantriebe – Komponenten und System-verhalten. Doctoral dissertation, Rheinisch-Westfälische Technische Hoch-schule Aachen
References
310 References
Leufgen M, Lü Y (1991) Pneumatischer Positionierantrieb mit Schaltventilen. Öl-hydraulik und Pneumatik o+p 35(2): 127–132
Lequesne B (1987) Finite element analysis of a constant force solenoid for fluidflow control. Proc IEEE Industrial Applications Society Meeting, pp 46–51
Lin X, Spettel F, Scavarda S (1996) Modeling and test of an electropneumatic ser-vovalve controlled long rodless actuator. Trans ASME – Journal of DynamicSystems, Measurement, and Control 118: 457–462
Liu Y T, Higuchi T (2001) Precision positioning device utilizing impact force ofcombined piezo-pneumatic actuator. IEEE/ASME Transactions on Mecha-tronics 6(4): 467–473
Lichtarowicz A, Duggins R K, Markland E (1965) Discharge coefficients for in-compressible non-cavitating flow through long orifices. Proc Instn mechEngrs – Part C Journal Mechanical Engineering Science 7(2): 210–219
Lloyd S G (1968) Guidelines for the use of positioners and boosters. Instrumenta-tion Technology 50–54
Louis R J, Logan E (1976) Experimental investigation of flow-induced forces inpneumatic spool valves. Technical Briefs. Trans ASME – Journal of DynamicSystems, Measurement, and Control 98(9): 316–318
Lu Y X, Hong Z (1988) Study on optimization of electro-pneumatic servo controlsystem. Proc FLUCOME’88, Sheffield, pp 295–299
Lü Y (1992) Elektropneumatische Positionierantriebe mit schnellen Schaltven-tilen. Doctoral dissertation, Rheinisch-Westfälische Technische HochschuleAachen
MacBain J A (1985) Solenoid simulation with mechanical motion. Int Journal forNumerical Methods in Engineering 21: 13–18
Mäkinen E, Virvalo T, Mattila J (1993) A model of on/off-valves for controlledpneumatics. Proc 3rd Scandinavian Int Conf on Fluid Power, Linköping,vol 1, pp 423–434
Manuello Bertetto A, Berretta A (1994) An innovative rod-less cylinder designwith electromagnetic coupling for linear transport systems. Proc Nat Conf onFluid Power, Anaheim, accessed via http://www.nfpa.com
Manuello Bertetto A, Mazza L, Pastorelli S, Raparelli T (2002) A model of con-tact forces in pneumatic motor vanes. Meccanica 36: 691–700
Maré J C, Geider O, Colin S (2000) An improved dynamic model of pneumaticactuators. International Journal of Fluid Power 1(2): 39–47
Matthys L, Marchetti P B (1980) Precise pneumatic positioning with diaphragmair cylinders. Machine Design 52(9): 80–83
Mattsson S E, Olsson H, Elmqvist H (2000) Dynamic selection of states in Dy-mola. Proc Modelica workshop 2000, Lund, pp 61–67
McCloy D, Martin H R (1963) Some effects of cavitation and flow forces in theelectro-hydraulic servomechanism. Proc Instn Mech Engrs vol 178, pt 1, no21, 1963–64
Merritt H E (1967) Hydraulic control systems. John Wiley & Sons, New YorkMetzner H (1993) Pneumatik-Dichtungen. In: Ebertshäuser H (ed) Dichtungen für
die Fluidtechnik. Vereinigte Fachverlage, Mainz
311
Miyata K, Hanafusa H (1988) Compensation and velocity control for high speedpositioning of pneumatic cylinders. Proc FLUCOME'88, Sheffield, pp 290–294
Miyata K, Yokota S-I, Hanafusa H (1991) Control of pneumatic drive systems byusing PCM valves. Proc FLUCOME'91, San Francisco, California, pp 373–378
Mo J P T (1989) Analysis of compressed air flow through a spool valve. ProcInstn Mech Engrs 203: 121–131
Monsen J (2000) In the flow with control valves. Chemical processing 63(3): 45–52
Moore P R (1986) Pneumatic motion control systems for modular robots. Ph.D.thesis, University of Loughborough
Müller R (1998) Pneumatics. Theory and applications. Omega Fachliteratur, Dit-zingen and Delta Press Ltd., Berkhamsted Herts
Münzer N, Müller-Lohmeier K (2004) Environmentally induced damage to pneu-matic tubing – causes, mechanisms and forms of manifestation. Proc 4th IntFluid Power Conf, Dresden, vol 2, pp 395–404
Muijtjens R (1998) Praktisches Positionieren mit pneumatischen Linearantrieben.Ölhydraulik und Pneumatik o+p 42(7): 473–476
Mundry S M (2002) Zustandsüberwachung an Prozessventilen mit intelligentenStellungsreglern. Shaker, Aachen
Murrenhoff H (1999) Grundlagen der Fluidtechnik – Teil 2: Pneumatik. Institutfür fluidtechnische Antriebe und Steuerungen, Aachen
Murrenhoff H (2002) Innovative designs and control circuits for proportionalvalves. Proc Nat Conf on Fluid Power, Las Vegas, Nevada, accessed viahttp://www.nfpa.com, pp 691–701
Murtaza M A, Garg S B L (1989) Brake modelling in train simulation studies.Proc Instn mech Engrs – Part F Journal of Rail and Rapid Transit 203: 87–95
Nabi A, Wacholder E, Dayan J (2000) Dynamic model for a dome-loaded pressureregulator. Trans ASME – Journal of Dynamic Systems, Measurement, andControl 122(6): 290–297
Neermann G (1989) In Paris kommt die Druckluft ins Haus. Ölhydraulik undPneumatik o+p 33(6): 522–524
Neff J A (1966) Timing with air. Proc Nat Conf on Fluid Power, accessed viahttp://www.nfpa.com, pp 93–98
Németh H (2004) Nonlinear modelling and control for a mechatronic protectionvalve. Ph.D. thesis, Budapest University of Technology and Economics
Nguyen N-T, Wereley S T (2002) Fundamentals and applications of microfluidics.Artech House, Boston London
Nguyen T (1987) Verhalten servopneumatischer Zylinderantriebe im Lageregel-kreis. Doctoral dissertation, Rheinisch-Westfälische Technische HochschuleAachen
Nguyen T (1996) Proportional- und Servotechnik in der Pneumatik. Ölhydraulikund Pneumatik o+p 40(1): 45–48
References
312 References
Nguyen T, Mauentöbben R (1993) Leckagefreies und robustes Servoventil für diePneumatik. Proc 9. Fachtagung Hydraulik und Pneumatik, Dresden, pp 473–485
Nichols N B (1962) The linear properties of pneumatic transmission lines. ISATransactions (1): 5–14
Noritsugu T (1986) Development of PWM mode electro-pneumatic servomecha-nism. Part II: Position control of a pneumatic cylinder. The Journal of FluidControl 17(2): 7–31
Noritsugu T (1987) Electro-pneumatic feedback speed control of a pneumaticmotor. Part I: With an electro-pneumatic proportional valve. The Journal ofFluid Control 17: 17–37
Noritsugu T, Wada T (1989) Adaptive variable structure control of pneumaticallyactuated robot. Proc 1st Int Symp on Fluid Power, Tokyo, pp 435–442
Ohligschläger O (1988) Pneumatische Ventile – Beschreibung und Vermessung.Ölhydraulik und Pneumatik o+p 32(9): 614–620
Ohligschläger O (1990) Pneumatische Zylinderantriebe – thermodynamischeGrundlagen und digitale Simulation. Doctoral dissertation, Rheinisch-Westfälische Technische Hochschule Aachen
Ohmer M, Neumann R (2004) Pneumatik vs. Elektrik. A&D Kompendium Auto-mation and Drives 2004, accessed via http://www.aud24.net, pp 202–204
Olsson H (1996) Control systems with friction. Doctoral dissertation, Lunds Uni-versitet, Department of Automatic Control
Pantring D (1996) Verfahren zur Berechnung der Durchflußkennlinie pneuma-tischer Druckregelventile. Doctoral dissertation, Universität Dortmund
Parker G A, White D E (1977) Modeling the steady-state characteristics of a sin-gle-state pneumatic pressure regulator. Fluidics Quaterly 9(2): 23–45
Pasieka L (1991) Untersuchungen zur Temperatur- und Energieverteilung inpneumatischen Arbeitszylindern unter den besonderen Aspekten von Tem-peraturgradienten und Wirkungsgraden. Doctoral dissertation, PädagogischeHochschule Erfurt/Mühlhausen
Paul A K, Mishra J K, Radke M G (1994) Reduced order sliding mode control forpneumatic actuator. IEEE Transactions on Control Systems Technology2(3): 271–276
Paulsen P (1989) Pneumatische Proportional-Druckregelventile und -Wegeventile.Drucklufttechnik 8(7–8): 50–52
Pawlak A M, Nehl T W (1988) Transient finite element modeling of solenoid ac-tuators: the coupled power electronics, mechanical, and magnetic field prob-lem. IEEE transactions on magnetics 24 (1): 270–273
Perry J A (1949) Critical flow through sharp-edged orifices. Trans ASME71(10): 757–764
Petersen E (1982) Anti-Blockiersystem für Nutzfahrzeuge. Proc 5. Aachener Flu-idtechnisches Kolloquium, Aachen, vol 3, pp 183–199
Pinches M J, Callear B J (1999) Power pneumatics. Prentice Hall, London NewYork Toronto Sydney
Pott H (1995) Mikropneumatik: Pneumatische Kennwerte und Systemverhalten.Ölhydraulik und Pneumatik o+p 39(2): 114–122
313
Pourmovahed A, Otis D R (1990) An experimental thermal time-constant correla-tion for hydraulic accumulators. Trans ASME – Journal of Dynamic Systems,Measurement, and Control 112(3): 116–121
Prest P, Vaughan N D (1987) Drive circuits of pulse width modulated valves. ProcInt Conf on Fluid Power, Tampere, Finland, pp 217–225
Pu J (1988) Advancements in the programmable motion control of pneumaticdrives for robots and other flexible machines. Ph.D. thesis, LoughboroughUniversity
Pu J, Weston R H (1988) Position control of pneumatic drives and the use oflearning methodologies. Proc 8th Int Symp on Fluid Power, Birmingham, pp169–198
Pu J, Wong C B, Moore P R (1995) An investigation into the profile following ca-pability of servo-controlled air motors. Proc 4th Scandinavian Int Conf onFluid Power, Tampere, Finland, pp 545–555
Pugi L, Malvezzi M, Allotta B, Banchi L, Presciani P (2004) A parametric libraryfor the simulation of a Union Internationale des Chemins de Fer (UIC) pneu-matic braking system. Proc Instn mech Engrs – Part F Journal of Rail andRapid Transit 218(2): 117–132
Purdue D R, Wood D, Townsley M J (1969) The design of pneumatic circuits.Fluid Power International pp 27–36
Pyötsiä J (1991) A mathematical model of a control valve. Doctoral dissertation,University Helsinki
Quaglia G, Sorli M (2001) Air suspension dimensionless analysis and design pro-cedure. Vehicle System Dynamics 35(6): 443–475
Quaglia G, Guala A (2003) Evaluation and validation of an air spring analyticalmodel. International Journal of Fluid Power 4(2): 43–54
Radgen P, Blaustein E (2001) Compressed air systems in the European Union.Energy, emissions, savings potential and policy actions. LOG_X VerlagGmbH, Stuttgart
Raparelli T, Bertetto A M, Mazza L (1997) Experimental and numerical study offriction in an elastomeric seal for pneumatic cylinders. Tribology International30(7): 547–552
Raymond E T, Chenoweth C C (1993) Aircraft flight control actuation system de-sign – Alternate command systems. Society of Automotive Engineers, Inc.,Warrendale PA
Reethof G (1955) The analog computer as a design tool in the study of a velocity-control hydraulic system. Proc 11th Nat Conf on Industrial Hydraulics, Chi-cago
Reid J, Stewart C D (1988) A review of critical flow nozzles for the mass flowmeasurement of gases. Proc FLUCOME’88, Sheffield, pp 454–457
Renn J C, Lin T I (2001) Research on a pneumatic proportional pressure controlvalve using the CFD analysis. Journal of the Chinese Society of MechanicalEngineers 22(5): 443–50
Reynolds W C, Kays W M (1958) Blowdown and charging processes in a singlegas receiver with heat transfer. Trans ASME 80: 1160–1168
References
314 References
Reynolds D B, Repperger D W, Phillips C A, Bandry G (2003) Modeling the dy-namic characteristic of pneumatic muscle. Annals of Biomedical Engineering31: 310–317
Richer E, Hurmuzlu Y (2000) A high performance pneumatic force actuator sys-tem. Part 1 – Nonlinear mathematical model. Trans ASME – Journal of Dy-namic Systems, Measurement, and Control 122(3): 416–425
Rockstroh M, Hofmann B (1996) Über digitale elektro-pneumatische Stel-lungsregler zur Positionierung von Regelventilen. Proc 28. Kraftwerkstech-nisches Kolloquium und 6. Kolloquium Meßtechnik für Energieanlagen,Dresden, pp 113–122
Rogers G, Mayhew Y (1992) Engineering thermodynamics – work and heat trans-fer. 4th edn. Longman, Harlow
Rohner P, Smith G (1989) Pneumatic control for industrial automation. JohnWiley & Sons, Brisbane New York Singapore Chichester Toronto
Roth P (1972) Zum dynamischen Verhalten des Stellungsregelkreises. Rege-lungstechnik und Prozeß-Datenverarbeitung 20(3): 101–108
Ruppelt E (2003) Druckluft Handbuch. 4th edn. Vulkan, EssenRusterholz R (1986) Vergleich verschiedener Regelkonzepte für die Auslegung
Rusterholz R, Widmer U (1985) Grundlagenbetrachtungen zur Auslegung pneu-matischer Servoantriebe. Ölhydraulik und Pneumatik o+p 29(10): 757–761and 29(11): 814–816
Sanville F E (1971) A new method of specifying the flow capacity of pneumaticfluid power valves. Proc 2nd Fluid Power Symp, Guildford, pp 37–47
Sbahi A (1992) Druckluft-Lamellenmotor. Doctoral dissertation, TechnischeHochschule Zwickau
Scavarda S (1993) Some theoretical aspects and recent developments in pneumaticpositioning systems. Proc 2nd JHPS Int Symp on Fluid Power, Tokyo, pp 29–48
Schaedel H (1968) Theoretische und experimentelle Untersuchungen an Leitungenund konzentrierten Bauelementen der Fluidik. Doctoral dissertation,Rheinisch-Westfälische Technische Hochschule Aachen
Schillings K (1993) Neue Antriebe und Regelungverfahren für servopneumatischeHandhabungsgeräte. Ölhydraulik und Pneumatik o+p 37(3): 200–208
Schillings K (2000) Servopneumatische Antriebssysteme und Handhabungsgeräte.Shaker, Aachen
Schmidt E (1963) Einführung in die technische Thermodynamik. 10th edn.Springer, Berlin Göttingen Heidelberg
Scholz D, Schabbel U (1987) Regelungskonzept für Bahnsteuerungen mit Druck-luft-Lamellenmotoren. Ölhydraulik und Pneumatik o+p 31( 9): 688–692
315
Scholz D, Mostert E (1988) Geschwindigkeitsgeregelte servopneumatische Zylin-derantriebe. Ölhydraulik und Pneumatik o+p 32(1): 45–52
Scholz D, Schwenzer R (1992) Schnelles pneumatisches Proportionalventil mitintegrierter Elektronik für die breite Anwendung. Proc 10. Aachener Fluid-technisches Kolloquium, Aachen, pp 129–140
Schramm H (1983) Die Hydraulik stand Pate - Einsatzbereiche eines pneuma-tischen Proportional-Druckregelventils. Fluid 17(3): 76–77
Schroeder L E, Singh R (1993) Experimental study of friction in a pneumatic ac-tuator at constant velocity. Trans ASME Journal of Dynamic Systems, Meas-urement, and Control 115(9): 575–577
Schulte H F (1961) The characteristics of the McKibben artifical muscle. ProcApplication of external power in prosthetics and orthotics, National Academyof Science – National Research Council, Washington, DC, pp 95–115
Schultz A (2004) Transient simulation of pneumatic valve solenoids with themethods of finite elements. Proc 3rd FPNI Ph.D. Symp, Terrassa
Schwarz A, Hoffmann B, Schumann D, Rockstroh M, Streubel S (1990) ZumAufbau elektrisch-pneumatischer Stellungsregler mit Mikrorechner für Mem-branstellantriebe. Proc 8. Fachtagung Hydraulik und Pneumatik, ORSTA,vol 1, pp 93–100
Schwenzer R (1983) Entwurf und Auslegung servopneumatischer Antriebsrege-lungen. Doctoral dissertation, Rheinisch-Westfälische Technische HochschuleAachen
Sesmat S, Scavarda S (1996) Static characteristic of a three way electropneumaticservovalve. Proc 12. Aachener Fluidtechnisches Kolloquium, Aachen, pp643–652
Sethson K M R (1993) Identifying the dynamics of fast response solenoid valves.Proc 3rd Scandinavian Int Conf on Fluid Power, Linköping, pp 271–287
Shearer J L (1954) Continuous control of motion with compressed air. Ph.D. the-sis, Massachusetts Institute of Technology
Shen X (2006) Exploiting natural characteristics of pneumatic servo-actuationthrough multi-input control. Ph.D. thesis, Vanderbilt University, Nashville,
Shoukat Choudhury M A A, Thornhill N F, Shah S L (2005) Modelling valvestiction. Control engineering practice 13: 641–658
Song B (2002) Robust nonlinear control design via convex optimization and itsapplication to fault tolerant longitudinal control of vehicles. Ph.D. thesis, Uni-versity of California, Berkeley, accessed viahttp://vehicle.me.berkeley.edu/Publications/AVC/bsson_phdthesis.pdf
Sorli M, Pastorelli S (1999) Design analysis of a force controlled pneumatic ac-tuator. Proc 6th Scandinavian Int Conf on Fluid Power, Tampere, pp 861–871
Sorli M, Figliolini G, Pastorelli S (2001) Dynamic model of a pneumatic propor-tional pressure valve. Proc IEEE/ASME Int Conf on Advanced IntelligentMechatronics, Como, pp 630–635
Spanner K (2000) Breakthrough in piezo actuator application. Proc 7th Int Confon New Actuators, Bremen, pp 236–241
References
Tennessee, accessed via http://etd.library.vanderbilt.edu/ETD-
316 References
Stecki J S, Davis D C (1986) Fluid transmission lines – distributed parametermodels. Part 1: A revision of the state of the Art. Proc Instn Mech Engrs200: 215–228. Part 2: Comparison of models. Proc Instn Mech Engrs200: 229–236
Stenning A (1954) An experimental study on two-dimensional gas flow throughvalve-type orifices. ASME paper no 54 – A – 45
Stephan K, Lucas K (1979) Viscosity of dense fluids. Plenum Press, New YorkLondon
Stewart H L, Jefferis F D (1955) Hydraulic and pneumatic power for production –How air and oil equipment can be applied to the manual and automatic opera-tion of production machinery of all types with numerous existing installationsexplained in step-by-step circuit analyses. The Industrial Press, New York
Stoll K (1999) Pneumatik–Anwendungen – Kosten senken mit Pneumatik. 3rdedn. Vogel, Würzburg
Strauss J C, Augustine D C, Johnson B B, Linebarger R N, Sanson F J (1967) TheSCI continuous system simulation language (CSSL). Simulation IX(6):281–303
Stribeck R (1903) Die wesentlichen Eigenschaften der Gleit- und Rollenlager.Mitteilungen über Forschungsarbeiten. Verein deutscher Ingenieure 7: 1–47
Subramanian S C, Darbha S, Rajagopal K R (2004) Modeling the pneumatic sub-system of an S-cam air brake system. Trans ASME – Journal of DynamicSystems, Measurement, and Control 126(1): 36–46
Taft C K, Herrick B M (1981) A proportional piezoelectric electro-fluidic pneu-matic valve design. Trans ASME – Journal of Dynamic Systems, Measure-ment, and Control 103(12): 361–365
Takemura F, Pandian S R, Nagase Y, Mizutani H, Hayakawa Y, Kawamura S(2000) Improvement of vane-type pneumatic motors and trial of hybridpneumatic/electric motors. Proc 2000 Japan – USA Flexible Automation Con-ference, July 23–26, Ann Arbor, Michigan, pp 393–400
Taubitz G (1978) Experimentelle Untersuchung und Modellbildung eines elek-trisch-pneumatischen Ventilstellungsregelkreises. Doctoral dissertation, Uni-versität Erlangen-Nürnberg
Teichmann O E (1957) Analysis and design of air motors. Product Engineering28(2): 167–178
Thompson P A, Arena C C (1975) Prediction of the critical massflow and relatedproblems in the flow of real gases. ASME Paper 75 – FE 12
Tiller M (2001) Introduction to physical modeling with Modelica. Kluwer Aca-demic Publishers, Boston Dordrecht London
Tokhi M O, Al-Miskiry M, Brisland M (2001) Real-time control of air motorsusing a pneumatic H-bridge. Control Engineering Practice 9: 449–457
Tondu B, Lopez P (2000) Modeling and control of McKibben artificial muscle ro-bot actuators. IEEE control systems magazine 20(2): 15–38
Tormen A (1998) Turbo-Banane verändert die Schleifwelt. Schweizer Maschi-nenmarkt 43: 42–44
Tsai D H, Cassidy E C (1961) Dynamic behavior of a simple pneumatic pressurereducer. Trans ASME – Journal of Basic Engineering 83: 253–264
317
Tustin A (1947) The effects of backlash and of speed-dependent friction on thestability of closed-cylce control systems. IEE Journal 94: 143–151
Uchino K (1997) Piezoelectric actuators and ultrasonic motors. Kluwer, BostonDordrecht London
Ulne A, Wase J (2000) Konventionelle und digitale Stellungsregler – einLeistungsvergleich aus anwendungsspezifischer Sicht. Industriearmaturen8(4): 353–356
Ulrich R D, Wirtz D P, Nunn R H (1969) Transient heat transfer in closed con-
Upchurch E R, Vu H V (2000) Modeling a pneumatic turbine speed control sys-tem. Trans ASME – Journal of Dynamic Systems, Measurement, and Control122(1): 222–226
Vaughan N D, Gamble J B (1996) The modeling and simulation of a proportionalsolenoid valve. Trans ASME – Journal of Dynamic Systems, Measurement,and Control 118(3): 120–125
Virvalo T (1989) Designing a pneumatic position servo system. Power interna-tional, pp 141–147
Virvalo T (1993) Pressure and position control with electropneumatic on/offvalves. Proc 3rd Int Conf on Fluid Power '93 ICFP, Hangzhou, pp 489–494
Virvalo T (1995a) Modelling and design of a pneumatic position servo system re-alized with commercial components. Doctoral dissertation, Tampere Univer-sity of Technology
Virvalo T (1995b) Improving the use of the stroke of a pneumatic servo cylinder.Proc 4th Scandinavian Int Conf on Fluid Power, Tampere, pp 528–544
Virvalo T, Mäkinen E (1999) The influence of the supply line pressure on the per-formance of a pneumatic position servo system. Proc 4th JHPS Int Symp onFluid Power, Tokyo, pp 149–154
Völker B (1999) Stetige Pneumatikventile mit minimierter Ansteuerleistung.Doctoral dissertation, Rheinisch-Westfälische Technische Hochschule Aachen
Voss M (2002) Betriebsverhalten und Parameter-Ermittlung pneumatischer End-lagendämpfungen. Diploma thesis, Fachhochschule Südwestfalen, Soest, un-published.
Wakui T, Hashizume T, Nishijima T (2003) Hysteresis compensation loaded indigital positioner for pneumatic control valve with tightened grand packing.Proc SICE 2003 Annual Conf, Fukui, vol 3, pp 3075–3079
Wakui T, Hashizume T, Nishijima T (2004) Valve hysteresis compensation con-sidering flow conditions for digital valve positioner. Proc SICE 2004 AnnualConf, Sapporo, pp 1507a–1507f
Ward-Smith A J (1979) Critical flowmetering: the characteristics of cylindricalnozzles with sharp upstream edges. Int J Heat & Fluid 1(3): 123–131
Watts G P (1965) The response of pressure transmission lines. Proc 20th AnnualISA Conf and Exhibition, Los Angeles, pp 1–8
Wiedmann P (1979) Über das Durchflußvermögen pneumatischer Komponenten.Ölhydraulik und Pneumatik o+p 23(2): 105–110
References
tainers after gas injection. Trans ASME – Journal of Heat Transfer 91(8):461–463
318 References
Wikander J (1988) Adaptive control of pneumatic cylinders. Doctoral thesis, Roy-al Institute of Technology, Stockholm
Wilke G (1999) Take control of control valves. Chemical processing 62(11): 59–66
Will D, Ströhl H (eds) (1990) Einführung in die Hydraulik und Pneumatik, 5thedn. Verlag Technik, Berlin
Winckler R, Kramer K (1960) Näherungsweise Berechnung von pneumatischenDüse-Prallplatte-Systemen. Regelungtechnik rt 8(12): 439–446
Winterbone D E, Pearson R J (1999) Design techniques for engine manifolds –wave action methods for IC engines. Professional Engineering Publ., London
Wintergerst S (1950) Die Schwingungsneigung pneumatischer Verstärker und ihreBeeinflussung durch konstruktive Maßnahmen. Die Technik 5: 82–83
Woods R L, Hullender D A, Hsu C H (1985) State variable models for fluidtransmission line dynamics. Proc FLUCOME'85, Tokyo, pp 115–121
Woschni H-G (1965) Einige Untersuchungen zu dem pneumatischen Längen-meßverfahren. Doctoral dissertation, Technische Universität Dresden
Wroten C F (1969) Pneumatic line losses. Machine Design 41(28): 182–185Wünsch D, Mousa M (1987) Verschleißverhalten von schmierungsfrei betrie-
benen Druckluft-Lamellen-Motoren. Antriebstechnik at 26(2): 47– 50Wylie E B, Streeter V L (1993) Fluid transients in systems. Prentice Hall,
Englewood Cliffs, NJXiang F (2001) Block-oriented nonlinear control of pneumatic actuator systems.
Dotoral dissertation, Royal Institute of Technology, StockholmYoung C D (1955) Pneumatic-hydraulic cylinder positioners. Proc Nat Conf on
Fluid Power, accessed via http:\\www.nfpa.com, pp 41–48Yun S, Lee K, Kim H, So H (2005) Development of the pneumatic valve with bi-
morph type PZT actuator. Materials, Chemistry and Physics 97: 1–4Zalmanzon L A, Hardbottle R, Stainthorp F P (1965) Components for pneumatic
control instruments – The static and dynamic characteristics of pneumatic re-sistances, capacitances and transmission lines. Pergamon Press, Oxford Lon-don Edinburgh New York Paris Frankfurt
Zhang H, Oneyama T, Kagawa T, Kuroshita K (2005) Standard proposal on flow-rate characteristics of pneumatic components. Proc 50th Nat Conf on FluidPower, Las Vegas, Nevada, pp 439–450
Zhou H (1995) Intelligence in pneumatic servo positioning axis. Proc 4th Scandi-navian Int Conf on Fluid Power, Tampere, pp 556–568