ENERGY HARVESTED FROM RESPIRATORY EFFORT
David Cavalheiro
1,2
, Ana Catarina Silva
1
, Stanimir Valtchev
2
, J. Pamies Teixeira
4
and Valentina Vassilenko
1,3
1
NMT- Tecnologia, Inovação e Consultoria, Lda., Portugal
2
Electrical Engineering Department, Faculdade de Ciências e Tecnologia, Universidade Nova de Lisboa, Lisboa, Portugal
3
Physics Department, Faculdade de Ciências e Tecnologia - Universidade Nova de Lisboa, Lisboa, Portugal
4
Mechanical and Industrial Engineering Department, Faculdade de Ciências e Tecnologia
Universidade Nova de Lisboa, Lisboa, Portugal
Keywords: Respiratory effort, Energy harvesting, Piezoelectric power converter.
Abstract: Presently, a high cost of some medical equipment is due not only the sophisticated technology, but also
because the cost of his maintenance. The electronic devices implanted in the human body are examples for
this constant maintenance, requiring sophisticated medical operations. Extra weight and volume addition to
the electronic devices are also a disadvantage, limiting the autonomy of such devices. An alternative to
replace the batteries as power sources is to obtain the energy from the human body. In this work we present
our prototype of Breathing Energy Transducer (BET) for an efficient energy conversion at fixed 2.6V from
chest movements during breathing. A series of experiments were performed in order to calculate the power
that could be generated from the respiratory effort during normal and deep breathings.
1 INTRODUCTION
Currently, the energy supply for the portable and
autonomous equipment comes almost exclusively
from the battery. Unfortunately the maintenance of
those sources of energy brings disadvantages due to
the need for frequent recharging or replacement. In
many cases the battery brings extra weight and
volume to the electronic equipment, limiting its
autonomy. Some possible alternative methods to
replace the batteries as power source, or to achieve
better maintenance of existing (or smaller) batteries,
are the so called Energy Harvesting (EH) methods,
i.e. to obtain energy from the environment. For the
medical equipment, there is also a possibility to
recover and store energy generated by the human
body in its usual activities.
This article we explore a possibility to obtain and
convert an energy from the chest expansion during
the normal and deep breathings. The harvested
energy is either converted to a fixed 2.6V value, by
an extremely efficient converter developed by our
team for this purpose. The low amount of energy
harvested from the chest expansion can be enough
for the proper functioning of certain systems, e.g.
MEMS systems.
2 ENERGY SOURCE
There are several techniques to obtain energy from
the environment, either for storage or for direct
supplying the electronic consumers. The energy
harvesting device generates electrical energy from
the environment applying different conversion
methods. In an early work, S. W. Angrist calls this
conversion a “Direct Energy Conversion” (Angrist,
1971). In the present time the converters are
carefully designed for each different source of
environmental power. They are expected to have
high conversion efficiency, mostly due to the lowest
values of energy collected from the environment.
Kinetic, thermal and electromagnetic energy are
some of the possible examples of energy source.
2.1 Kinetic Energy
This source of energy is one of the most readily
available to be converted from the human body. The
mechanical deformation of a certain structure and
the displacement of a mass are the basic principles
of the kinetic energy conversion. Using the principle
of piezoelectricity is one method to convert
mechanical deformations and movements into
388
Cavalheiro D., Silva A., Valtchev S., Pamies Teixeira J. and Vassilenko V..
ENERGY HARVESTED FROM RESPIRATORY EFFORT.
DOI: 10.5220/0003876703880392
In Proceedings of the International Conference on Biomedical Electronics and Devices (BIODEVICES-2012), pages 388-392
ISBN: 978-989-8425-91-1
Copyright
c
2012 SCITEPRESS (Science and Technology Publications, Lda.)
electrical energy.
Grate research has been carried out to collect as
much energy as possible from the human body. A
work done by T. Starner and J. Paradiso presents the
actively and passively dissipated energy during the
simple human activities(Starner and Paradiso, 2004).
One of the most explored energy sources from the
human body were the energy generated through the
force applied by the foot in a piezoelectric insole
during a walk (Kymissis et al., 1998).
Breathing is another possible source of energy.
The mechanical energy of the exhaled air can be
converted to the electricity. For example, using a
special mask with a turbine it possible to generate
the mechanical power of approximately 1W
(Starner, 1996).
From other side, the mechanical chest
movements during breathing can be used as another
way to harvest energy. In this process the
piezoelectric effect can be used to convert the
mechanical strain into electricity. It was estimated
that breathing with a mean frequency of the 10
breaths per minute can develop a mechanical power
of 0.83W (Starner, 1996).
However, the mechanical energy cannot be
converted completely in electricity due to losses in
harvesters and the other mechanisms. As a rule, the
electronic devices must have extremely high
efficiency both in energy conversion (harvestes) and
energy consumption (the control circuits). Larger
losses in the various components are translated into
lower conversion efficiencies. Usually the data
presented in the literature consider that the
mechanical generator have 50% efficiency; the
turbine + generator reach 40% efficiency; the
piezoelectric generator have 11% efficiency and the
double (including mechanical to mechanical and
other) conversion reach 12.5% efficiency (Starner,
1996).
3 POWER EXTRACTED FROM
HUMAN BREATH
In the present work were performed a series of
experiments in order to analyse the power generated
from human respiratory effort. For this purpose we
develop a Breath Energy Transducer (BET) working
as a piezoelectric generator.
The piezoelectric effect characterizes a class of
certain crystalline structures that become electrically
polarized when subjected to pressure. The reverse
effect is also known, i.e. when electric field is
applied to the crystal, its dimensions change
according to the applied electric field (inverse
piezoelectric effect). Initially, quartz was the most
well-known piezoelectric material, but now mostly
ceramic materials based in metal-oxide are used due
to the lower price.
The piezoelectric generator used to harvest
energy from chest expansion, contain one
piezoelectric transducer (Breath Energy Transducer),
producing electric charge when subjected to
compression. The generated voltage in this kind of
transducers may be high, but the value of the
produced current is (unfortunately) low. Some
piezoelectric systems tend to achieve better
performance through applying higher frequencies of
mechanical vibrations.
3.1 Breath Energy Transducer
The Breath Energy Transducer (BET) is a home-
made prototype of piezoelectric generator with
sensor composed by Macro Fibers (MFC) that offers
high performance, durability and flexibility. It
consists of rectangular piezoceramic rods (wires)
sandwiched between layers of epoxy polymer,
electrodes and polyimide film. The piezoelectric
sensor used in this work is the M-1700-P2 (170mm
x 7mm), developed for NASA. It presents a
capacitance of 91nF, free strain of -670ppm and a
blocking force of -42N.
Figure 1: Piezoelectric Breath Energy Transducer.
A BET was attached to a band (Figure 1), which
allow it fixing around the chest of a person.
3.2 Respiratory Effort Transducer
For measuring the amplitude of the chest during the
breathing was used a commercial respiratory effort
transducer SS5LB from BIOPAC
©
, also fixed
around the chest of a person (Figure 2). It measures
the respiratory effort and transmits the signal from
the chest expansion and contraction. The transducer
was applied to determine the depth of the breathing
and to calculate the breathing rate. By this
measurement it was possible to compare the normal
breathing to the deeper one, and to observe the
ENERGY HARVESTED FROM RESPIRATORY EFFORT
389
power generated by the harvesting piezoelectric
tape.
Figure 2: Respiratory effort transducer SS5LB and its
location.
The respiratory effort transducer was connected
to the BIOPAC
©
MP35 measuring system with
internal microprocessor to control the data
acquisition and recording software BSL Pro.
This measuring unit was necessary for
comparing the recorded breathings to the power
converted by the piezoelectric Breath Energy
Transducer.
4 EXPERIMENTAL RESULTS
The first step on the experimental procedure was to
find a correlation between the power consumed by
the load resistor, attached to the piezoelectric BET,
and the chest expansion while breathing normally
and deeply. The relation between the SS5LB sensor
signal and the SS5LB extension is shown in
Figure 3.
Considering that the maximum output of the SS5LB
sensor is proportional to the maximum depth of
breathing, a relation between the chest expansion (in
mm) and the output signal is possible to be achieved
for each individual person. This calibration have
allowed to find the relation between the chest
expansion and sensor extension (in mm), useful for
the proper construction of the Breath Energy
Transducer.
Figure 3: Relation between SS5LB output and SS5LB
extension.
The second step was aimed at finding the ideal
load for the piezoelectric Breath Energy Transducer.
Figure 4 shows the continuous power absorbed
during the loads in the range from 1kΩ to 2MΩ.
Figure 4: Power produced by the piezoelectric BET at
different loads.
As it can be seen from the graphic in the Fig. 4, a
maximum of dissipated power is reached with a
resistive value of load around 200kΩ, where will
continuously dissipating 620μW. This load has been
used in the experiments to achieve a relation
between the chest expansions and the extracted
power values from the Breath Energy Transducer.
The third step consists in finding the relation
between the chest expansion, and the power
delivered to the load (200kΩ). For this purpose were
performed a series of experiments: a healthy person
with 1.64m of height and 60kg of weight were asked
to perform six normal breathings and six deep
breathings. A typical resulting signal in an SS5LB
output is given in Figure 5. In this graphic the first
six signals are related to normal breathings followed
by the next six signals related to deep breathings. As
it was expected, the normal breathings give lower
SS5LB output signals (peak to peak) than the deep
breathings.
Figure 5: SS5LB output signal, in V(t).
An oscilloscope was used to measure the AC
voltage delivered to the load. Resulting graphics of
obtained signals for normal and deep breathings are
presented in Figure 6 and Figure 7, respectively.
From the oscilloscope data were also obtained the
RMS voltages, allowing calculates the values for an
active power available at the (resistive) consumer.
This power is given by equation 1, resulting in
BIODEVICES 2012 - International Conference on Biomedical Electronics and Devices
390
19μW and 50μW for normal and deep breathing,
respectively.
=
(1)
Figure 6: Oscilloscope output signal for normal
breathings.
Figure 7: Oscilloscope output signal for deep breathings.
Previously, it was found a relation between the
chest expansion in normal and deep breathings,
resulting in an expansion between 2 cm and 3.18 cm
while breathing normal, and an expansion between
3.54cm and 4.05cm while breathing deeply. With
this relation, it is possible to affirm that for a specific
person, an expansion of the chest with 4cm can
provide an average power of 50μW to any electronic
sensor that presents ideal input impedance, around
200kΩ.
An extremely efficient converter from Linear
Technology was used to convert the AC signals
generated by the generator tape due to the chest
expansions. The converter was configured to outputs
a value of 2.6V, to a capacitor of 47μF. The
experimental results are shown in Figure 8 and
Figure 9. In both figures, the yellow signal
represents the rectified voltage from the
piezoelectric BET, and the blue signal show the
output value of the capacitor.
Figure 8: Output value for charging during normal
breathing.
Figure 9: Output value for charging during deep breathing.
As it can easy observe, the normal breathing
during around 25 seconds will allow charging the
capacitor until 2.5V, while deep breathing will take
less time, around 20 seconds. The obtained results
for the charging time have a clear correlation with
less voltage, and consequently less power, generated
during the normal breathing than during the deep
one.
5 CONCLUSIONS
The experimental study performed in this work
shows that the mechanical movements of the chest
during the breathing can be used as an energy source
harvested from the human respiratory effort.
Obtained results also showed that deep breathing is
able to generate almost 3 times more power than
normal breathing.
The proposed prototype of piezoelectric Breath
Energy Transducer using an efficient converter was
able to generate enough power to charge a capacitor
of 47μF to a fixed value of 2.6V due to its
ENERGY HARVESTED FROM RESPIRATORY EFFORT
391
mechanical deformation caused by respiratory effort
movements. This capacitor of 47μF charged until
2.6V could be sufficient as to act as an electric
source to any system that presents very low power
consumption.
In the future, the output power value of BET can
be improved by better adapting of electronic circuits.
Another important improvement will be obtained by
the optimizing present mechanical construction in
order to enable maximum compression in the
piezoelectric tape at minimum breathing effort.
REFERENCES
Angrist, S. W., "Direct energy conversion", Allyn and
Bacon, Inc. Boston, 1971.
Starner, T., Paradiso, J., 2004. "Human generated power
for mobile electronics", C. (ed), Low-Power
Electronics, CRC Press, Chapter 45.
Starner, T., “Human Powered Wearable Computing”, IBM
Systems Journal, Vol. 35, No. 3 & 4, pp. 618-629,
(1996).
Kymissis, J., Kendall, C., Paradiso, J., Gershenfeld, N.,
1998. “Parasitic power harvesting in shoes”, in Proc.
2nd Int. Symp. Wearable Computing, pp. 132–139.
BIODEVICES 2012 - International Conference on Biomedical Electronics and Devices
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