Introduction and Summary
Page: 1-8 (8)
Author: Alfred Rufer*
DOI: 10.2174/9789815179095123010002
PDF Price: $15
Abstract
The motivation for the use of compressed air as an energy carrier and as a
storage means for many industrial applications resides in the simplicity and low-cost
conditions of its implementation. However, conventional pneumatic technology suffers
from a very low energetic efficiency even if the production, use and recycling of the
components can be said to be environmentally friendly, and it does not use problematic
materials. This introductory chapter positions pneumatic technology and discusses a
possible extension of the applications to the sector of energy storage in a general
manner. The chapter gives the historical background of the presented developments of
the book and gives an overview of the content of the document.
Compressed Air Systems and Storage
Page: 9-23 (15)
Author: Alfred Rufer*
DOI: 10.2174/9789815179095123010003
PDF Price: $15
Abstract
The elementary principles related to compressed air are presented,
describing the basic compression and expansion characteristics. The adiabatic,
polytropic and isothermal phenomena are described together with the definitions of the
energy content of a given volume. Different loss factors related to compressed air are
enumerated together with the advantages and drawbacks of pneumatic technology.
Then, the possibility of storing energy under low pressure conditions as the so-called
Underwater CAES system is discussed. Such systems have the interesting property of
being realized with a very low amount of grey energy.
Increasing the Energetic Efficiency of Pneumatic Devices
Page: 24-33 (10)
Author: Alfred Rufer*
DOI: 10.2174/9789815179095123010004
PDF Price: $15
Abstract
The chapter presents the main principle on which the proposals of this book
are based. In this principle, the energetic efficiency of pneumatic actuators is strongly
increased by adding an amount of expansion work to the classical work produced by
constant pressure displacement. Such a principle has already been applied in steam
machines at the beginning of the 20th century or in existing pneumatic converters used
as motors for automotive vehicles.
Coupling Two Rotary-Type Actuators
Page: 34-74 (41)
Author: Alfred Rufer*
DOI: 10.2174/9789815179095123010005
PDF Price: $15
Abstract
This chapter presents the first example of the combination of two actuators
of different volumes with which the principle of adding an expansion work can be
realized. The two semi-rotary actuators are mechanically coupled and describe an
oscillatory motion. Then the oscillatory motion is transmitted to an electric generator
through a so-called motion rectifier. The structure of the new system is presented with
the control valves and control circuitry. The different variables of the system as
pressure, torques, and mechanical work are calculated by simulation. The efficiency of
the new system is calculated and compared with the efficiency of a single actuator
without expansion. The principle of adding an expansion work with semi-rotary
actuators is then presented but with one actuator only where the expansion occurs in
the same and unique chamber. Efficiency, torque waveform and produced mechanical
work are presented, as well the control circuits.
The power reversibility of a system using semi-rotary actuators is addressed, and a
solution with a crankshaft is studied.
The Pneumatic Motor with Linear Cylinders
Page: 75-109 (35)
Author: Alfred Rufer*
DOI: 10.2174/9789815179095123010006
PDF Price: $15
Abstract
A pneumatic motor is studied where the pneumatic actuators consist of
linear cylinders. This mechanical principle based on the use of a crankshaft and piston
rods has the inherent property of being reversible. For this system, the same principle
of adding expansion work with an additional volume is applied as it was in the previous
chapter for semi-rotary actuators.
The mechanical behavior of the crankshaft and piston rod is described, and the
following pneumatic displacement and expansion work is simulated. Two different
architectures are simulated, namely, first, a system with pistons operating in phase and
second, with alternating pistons. The energy efficiency of the new motor is calculated
and compared with the efficiency of a system using a single linear cylinder.
Further, the principle of realizing the expansion work in the same cylinder as for the
displacement work is applied to the motor with linear cylinders. The torque, power and
converted work are presented with the simulation results. The study is completed with
the presentation of a physical demonstrator system.
Linear Pneumatic Cylinder Assembly with Reduced Air Consumption
Page: 110-131 (22)
Author: Alfred Rufer*
DOI: 10.2174/9789815179095123010007
PDF Price: $15
Abstract
The method of adding expansion work to pneumatic actuators is studied for
classical linear cylinders. The operating principle of new cylinder assemblies is
presented. A first simulation set illustrates the performance of the new assembly and
tries to define the parameters of a single cylinder which produces the same mechanical
performance. Acceleration, speed and reached position within a given time are the
conditions for the comparison. Then, the air consumption of both compared systems is
calculated. With an experimental set-up, a parasitic effect is observed, which consists
of a pre-expansion transient due to parasitic dead volumes related to the tubing and
internal volumes of the valves. A second assembly is realized with larger volumetry in
order to observe the dependency of the parasitic effect from the size of the cylinders.
For the control, a system with simpler control valves is also studied.
The Effect of the Dead Volumes and Pre-Expansion on the Produced Work
Page: 132-137 (6)
Author: Alfred Rufer*
DOI: 10.2174/9789815179095123010008
PDF Price: $15
Abstract
In Chapter 6, the parasitic effect of pre-expansion due to the presence of
dead volumes has been observed. This effect will now be analyzed in more detail in
this chapter. Especially the influence of this pre-expansion on the total produced
mechanical work is calculated. Different pre-expansion factors are considered and the
mechanical work of an ideal system without pre-expansion will be compared with the
reduced mechanical work of a cylinder assembly affected by pre-expansion.
Application Example: A Pneumatic Driven Hydrogen Compressor with Increased Efficiency
Page: 138-152 (15)
Author: Alfred Rufer*
DOI: 10.2174/9789815179095123010009
PDF Price: $15
Abstract
In this chapter, an application example is studied where the energetic
efficiency of a pneumatically driven device is of importance. The chosen example
consists of an air-driven gas booster used as a Hydrogen compressor in a refuel station
for H2
driven cars. The needed force for the driving of the compression cylinders is
calculated, and a new pneumatic motor based on the principle of adding expansion
work is proposed. The new motor is designed for sufficient effort for moving the
mobile equipment under the maximum compression force.
The air consumption of the new system is calculated, and finally, the air savings in
comparison to a classical air-driven booster. The simulation is completed with a
dynamic part showing the dynamic performance in terms of velocity and time to reach
the final position of the pistons.
Conclusion
Page: 153-155 (3)
Author: Alfred Rufer*
DOI: 10.2174/9789815179095123010010
PDF Price: $15
Abstract
The chapter serves as a conclusion to the different principles, systems and
application examples described in this book.
From the original air-powered diving lamp driven by a semi-rotary pneumatic actuator
to the final example of the gas booster, different systems have been proposed with a
large benefit in terms of energetic efficiency or in other terms, in the reduced amount
of air consumed.
References
Page: 156-157 (2)
Author: Alfred Rufer*
DOI: 10.2174/9789815179095123010011
PDF Price: $15
Appendix 1
Page: 158-160 (3)
Author: Alfred Rufer*
DOI: 10.2174/9789815179095123010012
PDF Price: $15
Appendix 2
Page: 161-165 (5)
Author: Alfred Rufer*
DOI: 10.2174/9789815179095123010013
PDF Price: $15
Subject Index
Page: 166-171 (6)
Author: Alfred Rufer*
DOI: 10.2174/9789815179095123010014
PDF Price: $15
Introduction
This text explains the use of compressed air for energy storage and efficient pneumatic applications. Chapters cover the elementary physical and engineering principles related to compressed air, including compression and expansion characteristics, adiabatic, polytropic, and isothermal phenomena, and energy content within a given volume. The author also discusses the advantages and drawbacks of pneumatic technology and presents innovative ways to increase the energy efficiency of pneumatic actuators. A key highlight of the book is the introduction of a method to enhance efficiency by incorporating expansion work alongside constant pressure displacement. The author presents an analysis of various cylinder assemblies where energy efficiency is notably improved compared to conventional pneumatic actuators. The book serves as a primary reference for mechanical engineering students and as a handbook for engineers designing efficient pneumatic devices. Key Features: Fundamental and advanced information about actuators and their pneumatic applications Focus on energy efficiency testing Systematic chapter order for effective learning progression, with a working example to support comprehension References for further reading Appendices providing additional insights and resources .