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A high performance automatic wingsail auxiliary propulsion system for commercial ships
Journal of Wind Engineering and Industrial Aerodynamics, 20 (1985) 83---96 Elsevier Science Publishers B.V., Amsterdam -- Printed in The Netherlands
A HIGH PERFORMANCE AUTOMATIC WINGSAIL AUXILIARY PROPULSION SYSTEM FOR COMMERCIAL SHIPS by JOHN G. WALKER (WALKER WINGSAIL SYSTEMS LIMITED)
ABSTRACT Wingsail
auxiliary
0304-3908/85/$03.30
ship propulsion
systems.
© 1985 Elsevier Science Publishers B.V.
83
84 WINGSAIL HISTORY
It m u s t
have
occurred
to t r y f i t t i n g already
been
a remarkable
So f a r as w e German
know,
Anton
the
Flettner,
wings to p r o ~ l
He o b t a i n e d
to m a n y
experimenters
the new fangled
aeroplane
plan
first who
the backing
in 1712 to propel engineer
in the e a r l y
the "Buckau",
in the e a r l y
to
twenties
at H a m b u r g ,
w h e n F l e t t n e r b e c a m e o b s e s s e d w i t h his famous of persuasion, got her
rotors,
course.
The project
reappeared War
and the "Barbara"
as a
then fizzled
leading
figure
and designs
Flettner
were well
metal
advanced
By an a m a z i n g
their a l l e g i a n c e . were a l s o
not surfacing
helicopter
the
fitted again
progra~e
feat
"Buckau" in due
until
he
during World
II.
We b e l i e v e , effect work,
of c o u r s e ,
rotor suffers
The next working
but w i n d w a r d
experimenter in N o r w a y
excellent
little
that
a major
from the very
of a f u n d a m e n t a l l y
in plenty,
poor
to m a k e
a
in t h e y e a r s
known
to us.
occupying
forces as "a potential
ratio.
significant immediately
She
of
was,
judgment
w a s made.
disadvantage,
tends to be
boat "Flaunder"(Fig.
vessel
2
error
serious
lift/drag
efficiency
trimming
Fig.
out,
was
i).
rotor concept.
in the G e r m a n
system
self-tricing
(Fig.
and the "Baden Baden"
century
there had
w i t h a wind turbine.
a workable
suggested
he caused the Krupp b o a r d to transfer
of this
After all
a vessel
propose
a 150 tonne b a r q u e n t i n e
of K r u p p s
years
w i n g s t o ships.
Thus o f f w i n d
force
contribution the
was
Fin
Second
2) w a s t h e f i r s t f u l l y
w e a p o n of war"
is a v a i l a b l e
lacking.
before
most
The Magnus
for s h i p p r o p u l s i o n
sadly,
destroyed
Utne,
World
who was
War.
His
worked out self by
the
German
85 Our own work in the field started in the late sixties, with P l a n e s a i l a 10m long wingsail aerofoil
p r o p e l l e d cruiser.
(Fig. 3),
She shared a simple symmetrical type of
section with "Flaunder" but had four main
sail
panels
instead of one,
to provide extra thrust, and she worked e x t r e m e l y well. In p a r a l l e l
with these ventures
in the field of self
were many attempts to fit wings to boats and to control by c o n v e n t i o n a l is b e c a u s e
of
sheets, the
far
push rods, higher
motors etc.,
demands
efficient high aspect ratio wing.
made
A c l o t h sail
ratio wingsail) is much "easier on the sheets." in Fig.
their angle to the wind
of which had failed. the
trimming
This
system
(or a low efficiency,
by
an
low aspect
This is g r a p h i c a l l y i l l u s t r a t e d
4, which shows curves of crosswind force against angle of incidence for
a typical wide
all
upon
trimming w i n g s a i l s there
efficient wingsail and a low efficiency cloth
tolerance
shown
c o n t r o l l e d by slow, inexorably
by
the
low
efficiency
even manual means.
device
(or rigid) device. means
that
it
can
The be
The search for high efficiency leads one
t o w a r d s s y s t e m s n e e d i n g v e r y r a p i d a n g l e t r i m m i n g rates, and t h u s
l o g i c a l l y to the self trimming wingsail. Fig. 3
8B 3.0
"~.0
4.o
Fig.
c~ AN~L~-
4
OF- A - [ T A C ~
SYSTEM DEFINITION
Modern
motor
ships
r u n n i n g costs,
have
bunker
and the p r e s e n t
of the b u n k e r cost r e d u c t i o n s To e n a b l e
a given
system
should p e r f o r m well
2.
High course efficiency. course c i r c l e
at a n o m i n a l
Safety,
in structural,
4.
Low or n e g l i g i b l e
thrust
o p e r a t i o n and failsafe
directly
period.
while
from
the wind;
figures b e l o w
terms.
This
a maximum
of
is
the
result
of
an
a w i d e range of course angles,
a m o u n t s of f u e l , r e l i a b l e for
system;
towards
c r e w demands.
strongly over
attainable.
it
in the v e s s e l
Thus 100% w o u l d o n l y be a v a i l a b l e
of g i v i n g
for a w i n g s a i l
aim
field,
This we d e f i n e as the p e r c e n t a g e of the 360 d e g r e e
system effectiveness.
pay-back
in t h e
o v e r w h i c h forward thrust can be a p p l i e d
60% suggest rather poor overall
Short
cost by such systems.
contribution
80% w o u l d be a v e r y good figure
thrusting
of total
arises b e c a u s e
levels in a given w i n d per unit size.
system capable
3.
5.
40-60%
assistance
low c a p i t a l
a worthwhile
i0 knot forward speed.
turbine
a m o u n t to some
against the f o l l o w i n g criteria:
High m a x i m u m t h r u s t
a wind
costs w h i c h
o f f e r e d at quite
to m a k e
I.
total
fuel
thrust t o w a r d s w i n g s a i l
and cheap to maintain,
3 years,
and
1.5 to
with
2.5 y e a r s
efficient saving
system,
considerable
l o w f i r s t cost. seems
likely
to
We be
87 THEORY AND PRACTICE
All
the aerodynamic d e v i c e s
proposed to extract solar energy from the wind for
ship p r o p u l s i o n work on e x a c t l y the same principle, and using the r e s u l t a n t reaction force in some way. opposed
reactions,
and so the o u t p u t
transmission system. the vessel,
Auto-rotation
so do all
is a t o r q u e
systems
of d e f l e c t i n g
the air flow
Turbines have s y ~ n e t r i c a l l y calling
for
some
f o r m of
(autogyros) react direct force on to
Magnus effect rotors,
circulation
control
columns,
wings
and cloth sails. The
best
plotting
way
to
visualise
crosswind
force
this
deflection
coefficient
against
is p e r h a p s downwind
the
drag
envelope force
curve,
coefficient,
giving a characteristic symmetrical butterfly shape (Fig. 5).
L/D =
/
(
1oPPo~crE
TkCv..
CI
FO ~ C £
Fig. 5 The three main parameters measured by this graph are: m a x i m u m crosswind force coefficient
All
(A)
optimum crosswind force/drag ratio
(B)
maximum downwind force coefficient
(fully stalled)
vessels
apart from specialised
a b l e to p e r f o r m
(C and C')
o n e - t r a c k o n l y r e c o r d b r e a k e r s n e e d to be
just as w e l l on the p o r t t a c k as on s t a r b o a r d .
s y m m e t r i c a l l y i n v e r t a b l e configurations,
This requires
which can fall into one of two possible
types: Symmetry across the wind line.
This group includes all square rigged ships, and
the Nippon Kokan system for example. Symmetry
along
the wind
line.
This group includes
all
fore and aft r i g g e d
yachts, and our own self trimming wingsail systems. The c h o i c e is i m p o r t a n t , e s p e c i a l l y
for h i g h l y e f f i c i e n t c o m p u t e r c o n t r o l l e d
systems suitable for fitment to modern minimally manned commercial vessels.
88 In Fig. 6 a c r o s s w i n d wingsail device.
force/angle
of a t t a c k c u r v e is d r a w n for a h y p o t h e t i c a l
It can easily be seen that if X is a "maximum permitted" anq[~
c h o s e n to p r e v e n t u n w a n t e d s t a l l i n g ,
( u n d e s i r a b l e b e c a u s e of s h a r p l y r e d u c e d
c r o s s w i n d force, i n c r e a s e d d r a g and the l a r g e " h y s t e r e s i s establish
a s m o o t h flow)
- then a t r i m m i n g
angular excursions from the set level, a less e f f i c i e n t the set level
will
system,
loop" n e e d e d to re-
A, p e r m i t t i n g
only
small
produce a higher mean thrust B than
t r i m m i n g system, C, p e r m i t t i n g w i d e r a n g u l a r e x c u r s i o n s
and giving a mean thrust level
device.
D, from exactly
/ ) M E A N T H R U S T OF C O N T R O L SYSTEM
B CROSSWIND FORCE
from
the same wingsail
~
' A'
D
CONTROL
Fig. 6 ANGLE
The efficiency of a trimming to rotate the wingsail
SYSTEM
'B'
0Y ATTACK
system is a function of the energy
against inertia and air
loads.
levels required
The "crosswind symmetry"
style of wingsail
system suffers in this respect because the pivot axis must be
at
in the
the
50%
point
chord
width,
while
the
c a m b e r e d s u r f a c e u s u a l ly acts at a p p r o x i m a t e l y leading edge
total
output
force
from
a
33% of the c h o r d b a c k from the
(or "luff").
Thus, t h e r e w i l l ship p r o p u l s i o n
always
be a m o m e n t of some 0.17 x c h o r d x force, a m o u n t i n g in
sized systems to many tonnes.metres of torque,
to be reacted by
the trimming system in addition to the effects of inertia, when the system tries to turn the wingsail
so as to avoid the highly undesirable stal 1 (Fig. 7).
FORCE
F
SUSTAINING
Fig. 7
MOMENT
REQUIRED
89
AIR DIRECTOR
Fig.
8
"Wind-line placed
symmetry"
by the d e s i g n e r s
system.
Thus,
automatic
governing
The aerofoil no less vital
when configured downwind
external
torques
easily
hold
Its
centre
thick
rounded internal
minimal
thrusting.
it c l o s e
zone should. resistance,
to p o i n t
a simple
'X' o n
and a longer
chord
cambered
(to port or,
image,
mode, useful
manoeuvring.
(Fig.
in mirror
8),
gives
for power-off
a
tests
of
spent
on this
tested
low downwind
drag when configured are
specifically avoiding
free,
with
reliable curve
safe,
control 6),
for
the n e e d for
extremely
(Fig.
at
drag
adapted
zone behaves
This a l l o w s combined
exactly
power-off low
system
airmay
giving
real
section,
with
predictions.
a short
chord
flap both c o u p l e d
modes
flat
very
design,
and
and we have
tunnel
of pressure
output
of three main elements,
T h e r e are t w o p r i m a r y
envelope,
the
very close to theoretical
consists
elements
structural
Thus
trimming
capable
independently
3.0, with
and its centre
air
on the
designs
of wind
has b e e n
than
section
hinges.
The
series
section
of more
of pressure
with
when
an air director
demands
trimmed
axis can be
can be produced.
separate
JW05-3
thrust
and stiff
w o r l d effectiveness
The section
torque
tail
for upwind work, and very high downwind
a light
as a wingsail
load
operation
and t w e l v e
masts or bracing wires;
weather-cocking
air
reliable
and the pivot
to be u s e d is of c o u r s e m o s t i m p o r t a n t ,
crosswind
running.
to a l l o w
fast,
Our present
of
this disadvantage,
and fail-safe
section
subject.
avoid
to m i n i m i s e
efficient,
than nine years
coefficients
load
systems
of o p e r a t i o n
leading
to it by simple
- flat
and robust
(or s y m m e t r i c a l )
and
to starboard).
low-drag,
alongside
low
situations
maximum and
thrust
performance
low speed close quarters
90
I
---4 /
l
Fig.
9
Maximum
cross-wind
mode,
while
(Fig.
9).
In
the
cambered
carefully
crosswind to s o m e
2.0; JW05-3 force
Fig.
force
flap
and
slotted
air
before
3.0.
director
of i n c i d e n c e
of
stall,
up to 35 to 40 degrees of
one third
of t h a t
move
flap configuration
of Flaunder
coefficients
20 d e g r e e s
turns
is a p p r o x i m a t e l y
is less t h a n t h a t of an e q u i v a l e n t
in a n g l e
wingsails
coefficient
i0
the
single
increases
p l a i n symmetrical
rotate
drag
mode
profiled
considerable
with
thrust
downwind
before
and Planesail 1.0;
highly
giving before
to p o s i t i o n s (Fig.
stall. stall
giving
This
a
allows
For e x a m p l e ,
cambered
with
i0).
the
at 12 to 15 degrees, unslotted
coefficients stall,
in the c a m b e r e d m a s t or d e r r i c k
rather
a maximum
shapes
less t h a n crosswind
91 SO far as m a x i m u m
downwind
very
can achieve
few devices
specially
designed
on s i n c e about
and
much more
parachutes
our early
0.5,
d r a g is c o n c e r n e d ,
and spinnakers.
symmetrical
we
now
than
days,
achieve
for s a i l i n g
over
f r o m t h e wind,
of a b o u t
1.2,
even
Our section design work has m o v e d
with downwind
just
away
a coefficient
1.3,
drag
quite
coefficients close
to
of o n l y
the
maximum
theoretical ly obtainable.
All
our primary wind tunnel
one metre JW05-3
span and 0.3m chord,
section
displays
the g r a p h s
for 10 m / s
interested
in t r i p l a n e
model,
work has been performed with m o d e l s
with which
fitted with end p l a t e s
extremely a n d 75 m / s
tolerant
and tested at 25 m/s. Number
characteristics,
a r e v i r t u a l ly i d e n t i c a l .
configurations,
such v a r i a b l e s
Reynolds
we also
as spacing
and
of a p p r o x i m a t e l y
have
Since
a triplane
stagger
have
we
are
wind
The and very
tunnel
been e x h a u s t i v e l y
analysed.
While more where
our e a r l y recent the
work
wind tunnel has
been
enthusiastic
test was carried
done
support
at
Cambridge
and
In
1976
prototype
we
initiated
2 form
2.7, as against
ii
over
(capable
of
Aerospace
University,
Engineering
Professor
the
Department,
Austyn
Mair
has
Filton.
- THE FLYER PROGRAMME
a programme
and demonstration
in its D a s h
Fig.
TESTING
University
encouragement
been a very great h e l p to us, and at British
FULL SIZE PROTOTYPE
out at Southampton
craft
aimed called
of a m a x i m u m
3.0 for the present
at
the
Flyer.
construction She
crosswind Dash
3).
utilizes force
of
a full
the JW05
coefficient
size
section of s o m e
92 Flyer
(Fig.
II)
free r o t a t i o n tail
vane
Filton are
a
the water,
controlled
Flyer
switched
to
yet
thrust
The
we
Flyer our
have
Fully
has shown
product
by
designed power
and the w h o l e
by
pack,
system
has
satisfaction,
thrust very
drag.
In
stationary
standing
silent
now
from zero to force
when
when
and
valves,
availability
low
lie quite
chaseboat
giving
control
5,
the
so desired,
the
computer
is
seen
sailing
and m o s t
she runs a w a y than
be be reliable, identical
of
the
of our Flyer
of
the
silent
f r o m the w i n d q u i e t l y not
only
on
and this
strong and c o n t r o l l a b l e , in M o d u l e
and gives
2 will
provide a
for ship propulsion.
JW05-3
and sought
section
criteria
trimming,
using
trace
a comparatively
may go a l o n g s i d e circle"
a tail
vane,
is t h a t
large
quays and other is
propulsive
configuration.
A natural
well
vessels,
within
thrusting
Here a central
the
area
the
vane
into
on
its
this
main sail panel
boom
view.
it is n a t u r a l l y We
according
for v e r y
to
careful
of the decision to go
in p l a n
beam.
place.
of ships,
2, c a l l e d
corollary
circle
product needs very
in the market
to the p r o p u l s i o n
testing work.
for s e l f
out
but a v i a b l e
after
set out in S e c t i o n
tends
possible
25 d e g r e e s
and e x h i l a r a t i n g
Planesail,
technology
t e s t s a n d t h e o r y are a l l v e r y w e l l ,
"trimming
within
abundant
2 SYSTEM DESIGN
evaluation
triplane
will
performance
if it is to be valuable
application
maximum
specially
The h y d r a u l i c
with
70hp
stalled,
itself
definition
this
union
are
to the h u l l
a DC e l e c t r o h y d r a u l i c
of great
already
far greater
the s y s t e m
vessel
actuation
but on a l l o t h e r s as w e l l .
THE MODULE
to
vane
the s a i l s e t
Franklin,
progressive
"closehauled",
showing
most acceptable
Wind tunnel
including Spencer
give
us e v e r y hope that the v i r t u a l l y
much more,
rotary
direction
leaving
but
when
p o i n t of s a i l i n g ,
TOWARDS
four-way
as p l a n n e d .
experienced,
off the wind.
The sailset
and
on a ratio
"Ahead".
wind
effectively,
Flap
connecting
been a source
exactly
and
boom.
mounted
by a low a s p e c t
and sensitivity.
crosswind
away
continue,
apparent
has
wingsail
It is t r i m m e d
pathways
hydraulics,
by microprocessor,
wind
lower
friction
reliability
thrust
accelerating
a 7.2m x 2.5m s i n g l e
Ltd and p a r t l y
in e i t h e r
highest
Tests
low
by U C C
controllable
maximum
a single
The other
partly
with
four hydraulic
through Ltd.
long,
ring type bearing.
on
means,
worked with great
On
10m
mounted
hydraulic passing
is
slewing
desirable
therefore,
circle,
to
decided
is flanked
or b o o m s
So t h a t
the that
get
the
upon
the
by two
93 lighter ones, all three being c o n t r o l l e d by a single tail vane assembly. is of course some 5%-8% m u l t i p l a n e
loss in using such a layout.
There
The triplane
a l s o p r o v i d e s quite high e f f e c t i v e aspect ratios for good course efficiency. Module
2 has therefore three main panels, almost identical
rib h i n g e d e t a i l s The r e s u l t i n g
to M o d u l e
sailset
I, but e a c h p a n e l
in c h o r d w i d t h and
is 13.5m h i g h i n s t e a d of 7.2m.
(Fig. 12) has a n o m i n a l t h r u s t a r e a of 101 sq. m., and is
r a t e d at 2.5 t o n n e s of s t a t i c t h r u s t in a 25kt (13 m/s) b e a m wind.
The m a x i m u m
force a v a i l a b l e is 6 tonnes. The s a i l s e t s
are of m a i n l y
aerospace m a t e r i a l s panels
have
the c e n t r a l loads.
reinforced
plastics
such as p o l y m e t h a c r i l i m i d e
identical
external
design,
foams
section profiles,
calling
and epoxide
upon modern resins.
to reduce tooling
All
costs,
but
p a n e l h a s a v e r y r o b u s t s t e e l m a i n s p a r c a r r y i n g a l l the b e n d i n g
At the b o t t o m ,
this
is f l a n g e m o u n t e d
to a p r o p r i e t a r y
low friction
slewing ring main bearing.
I
1
Fig. 12 Both vane and flap have closed accepts
information
loop servo control
from transducers
g i v i n g wind
systems. speed,
The computer itself
apparent wind angle
to
the ships c e n t r e l i n e and apparent wind a n g l e to the sailset centreline. In operation,
the computer system configures and angles
optimum thrust available. the wingsails, for.
The
main
and whether close hauled, engine
will
be
reaching or running settings are c a l l e d
automatically
throttled
s t r e n g t h rises, or the c o u r s e a n g l e or w i n d d i r e c t i o n then
the
main
engine
p r o g r e s s i v e l y more fuel.
or
the sailset to give the
This process includes deciding on which tack to angle
engines
will
reduce
power
back.
If the
wind
become more favourable, further,
thus
saving
94 If
the
chosen
computer w i l l
A
full
diagnostic
approximately are
course
bridge,
the
+/-
If
the
the
checking
weather-cocking
s a f e l y until
NAVAL A R C H I T E C T U R A L
the f a u l t
our
It w i l l
be
sailsets
are a b o v e
noticed
a
fault
for
and m e c h a n i c s
which
at
procedures
there
shewing a red
go to i t s
the drag.
is
no
light on the
symmetrical
settings,
CONSIDERATIONS
that the b r i d g e has as full
most cases panel
to w i n d w a r d ,
can be a t t e n d e d to.
It is i m p o r t a n t
of the s a i l s e t s
dead
thrust and m i n i m a l
hydraulics
cut its power,
automatically
therefore
mount
zone
electronics,
discovers
the s y s t e m w i l l will
degree
and a range of p h a s e d c l o s e - d o w n
computer
sailset
20
g i v i n g no c r o s s w i n d
one second i n t e r v a l s ,
available,
and
in
programme,
available.
redundancy
lies
feather the sailsets,
that
on t u b u l a r
a f i e l d of v i e w as possible,
steel
columns,
so that
the upper edges of the b r i d g e w i n d o w s
only
heights will
very
moderate
approximate
height
sailsets
the
(Fig.
are
and we
lower
edges
13).
specified
- in
to the b e a m of the ship.
\
. . . . .
Fig.
F
±__
13
There are further benefits
small maxima,
heel
resulting
angles,
from these m o d e s t
averaging
2 to 3 d e g r e e s ,
e v e n in the worst conditions.
sailset specifications:
with only
5 to 8 d e g r e e
95 low column
-
loads,
of the s a m e o r d e r
a v e r a g e deck crane installation, plates
of rhythmic
to 50%, w i t h reduction.
later
constant
first
vessel
level
to speed
bridge
monitor
speed/economy
most
course
pitch
control
energy
course
installations
will
emerge
propulsion
ship
propeller
over
and
perhaps
speed
tend
the m i n i m u m
level
Eventually,
with
main p r o p u l s i o n
for
data
scheduled
a
the
range
of
permit
Cargo handling
enough
blend
until
crane.
in
the
levels,
wingsail
of
controllable
installations
being
specified.
both engines
would
run at say 90%
being
progressively
raising
again
the output
progressively
ie 20% to 25% of t o t a l
installed
direction
with
both are at say 40% MCR.
completely,
very
rpm
with
wingsail
well
with
this
against
load
for
pitch
ranges
are not predicted
operation
area
problems
"Eastgate",
and
In
throttled
The next stage of the remaining
throttling
back to
installed
rating.
a strong
wind,
- the w i n g s a i l s
each
of operation,
different
all
used,
rating.
115 d e g r e e s ,
to add a p p r e c i a b l y
as
Fully already
to i n s t a l l e d
costs,
stopped.
importance
owned
pattern
of a p p r o x i m a t e l y
with main engines
is of c o u r s e of v i t a l
to vessels.
handling
for
in due
be shut down.
to o p t i m i s e designs,
vessels,
adapted
further
output
for e x a m p l e ,
improve,
a high
could
exist at Stone Vickers,
cargo
distance/time
onto existing
move
engine
of 40% to 50% MCR,
c.p p r o p e l l e r s
handling
the
systems can a l s o be used,
specifically
to
engine at the same time to 80% M C R before
wingsails
only
the vessel
for the same
recommendations
in l o w w i n d c o n d i t i o n s ,
be to cut out one engine
and w i l l
and profit.
can a l l o w
memorising
roll
l o s s or d a m a g e
is of course
later,
be retrofits
multiple
as wind conditions
present,
above
information
range of power
back,
feathering
aerodynamic
cargo
crew effectiveness
conditions,
designs
will
a wide
would
at
being cut by 30
using our products.
specifications
operation
for s e r v i c e
Modern
active
Later generations
planning
will
such a design with twin engines MCR
full
in light winds
based weather
amplitudes
resistance,
system described
possible.
wind
showing
early
engine
flexible
as the
options.
there
auxiliary
Main
speed
Satellite
affording
can reduce
lower speed running
time.
in beam sea,
and increase morale,
up in f a v o u r a b l e
arrival
While
versions
of sophistication
so as to permit
rolling
This effect
and seasickness,
The
for e x a m p l e
o n l y for simple deck d o u b l i n g
etc.
reduction
-
of m a g n i t u d e
calling
in c o n s i d e r i n g
by R o w b o t h a m
Tankships
must
be kept
simply
the fitment Ltd,
clear
presents of
the
of no
hose
96 LOW
level
horizontal
cranes m o u n t e d on the wingsail
to s o l v e
most reefer,
vessels
alongside
confident
container
high
walls
that the innovative
s o l v e most of the snags
Car
carriers
adapted
and R o - r o
to benefit
are also
at
low tide
skills
support c o l u m n s
cargo problems, may
present
of t h e c a r g o
seem l i k e l y
although
smaller
difficulties
handling
- we a r e
specialists
will
l i k e l y to arise.
vessels,
provided
from w i n g s a i l
favoured,
prove e s p e c i a l l y
and general
the reduced
valuable
that
auxiliary
stability
propulsion,
noise and vibration
is adequate, while
seem w e l l
passenger
levels
seeming
vessels
likely
to
in the c r u i s e market.
SUMMARY
We are of
confident
this
new
considerable wingsail
that
no m a j o r
industry's quantities
installations
technical
progress of bunker
becoming
fuel
an
or o p e r a t i n g
towards each
saving year.
increasingly
problems the
lie in the path
shipping
We t h e r e f o r e normal
sight
on
industry
look forward to the
oceans
of
the world.
BIOGRAPHY
John W a l k e r since
1965,
developing computer
is 47, and was o r i g i n a l l y he
has
aerofoil
control
been
t r a i n e d as an a i r c r a f t
concentrating
sections,
self
virtually trimming
engineer.
exclusively
systems
and
to their p r e s e n t high level of s o p h i s t i c a t i o n .
However,
on wingsails,
their
associated
A HIGH PERFORMANCE AUTOMATIC WINGSAIL AUXILIARY PROPULSION SYSTEM FOR COMMERCIAL SHIPS by JOHN G. WALKER (WALKER WINGSAIL SYSTEMS LIMITED)
ABSTRACT Wingsail
auxiliary
0304-3908/85/$03.30
ship propulsion
systems.
© 1985 Elsevier Science Publishers B.V.
83
84 WINGSAIL HISTORY
It m u s t
have
occurred
to t r y f i t t i n g already
been
a remarkable
So f a r as w e German
know,
Anton
the
Flettner,
wings to p r o ~ l
He o b t a i n e d
to m a n y
experimenters
the new fangled
aeroplane
plan
first who
the backing
in 1712 to propel engineer
in the e a r l y
the "Buckau",
in the e a r l y
to
twenties
at H a m b u r g ,
w h e n F l e t t n e r b e c a m e o b s e s s e d w i t h his famous of persuasion, got her
rotors,
course.
The project
reappeared War
and the "Barbara"
as a
then fizzled
leading
figure
and designs
Flettner
were well
metal
advanced
By an a m a z i n g
their a l l e g i a n c e . were a l s o
not surfacing
helicopter
the
fitted again
progra~e
feat
"Buckau" in due
until
he
during World
II.
We b e l i e v e , effect work,
of c o u r s e ,
rotor suffers
The next working
but w i n d w a r d
experimenter in N o r w a y
excellent
little
that
a major
from the very
of a f u n d a m e n t a l l y
in plenty,
poor
to m a k e
a
in t h e y e a r s
known
to us.
occupying
forces as "a potential
ratio.
significant immediately
She
of
was,
judgment
w a s made.
disadvantage,
tends to be
boat "Flaunder"(Fig.
vessel
2
error
serious
lift/drag
efficiency
trimming
Fig.
out,
was
i).
rotor concept.
in the G e r m a n
system
self-tricing
(Fig.
and the "Baden Baden"
century
there had
w i t h a wind turbine.
a workable
suggested
he caused the Krupp b o a r d to transfer
of this
After all
a vessel
propose
a 150 tonne b a r q u e n t i n e
of K r u p p s
years
w i n g s t o ships.
Thus o f f w i n d
force
contribution the
was
Fin
Second
2) w a s t h e f i r s t f u l l y
w e a p o n of war"
is a v a i l a b l e
lacking.
before
most
The Magnus
for s h i p p r o p u l s i o n
sadly,
destroyed
Utne,
World
who was
War.
His
worked out self by
the
German
85 Our own work in the field started in the late sixties, with P l a n e s a i l a 10m long wingsail aerofoil
p r o p e l l e d cruiser.
(Fig. 3),
She shared a simple symmetrical type of
section with "Flaunder" but had four main
sail
panels
instead of one,
to provide extra thrust, and she worked e x t r e m e l y well. In p a r a l l e l
with these ventures
in the field of self
were many attempts to fit wings to boats and to control by c o n v e n t i o n a l is b e c a u s e
of
sheets, the
far
push rods, higher
motors etc.,
demands
efficient high aspect ratio wing.
made
A c l o t h sail
ratio wingsail) is much "easier on the sheets." in Fig.
their angle to the wind
of which had failed. the
trimming
This
system
(or a low efficiency,
by
an
low aspect
This is g r a p h i c a l l y i l l u s t r a t e d
4, which shows curves of crosswind force against angle of incidence for
a typical wide
all
upon
trimming w i n g s a i l s there
efficient wingsail and a low efficiency cloth
tolerance
shown
c o n t r o l l e d by slow, inexorably
by
the
low
efficiency
even manual means.
device
(or rigid) device. means
that
it
can
The be
The search for high efficiency leads one
t o w a r d s s y s t e m s n e e d i n g v e r y r a p i d a n g l e t r i m m i n g rates, and t h u s
l o g i c a l l y to the self trimming wingsail. Fig. 3
8B 3.0
"~.0
4.o
Fig.
c~ AN~L~-
4
OF- A - [ T A C ~
SYSTEM DEFINITION
Modern
motor
ships
r u n n i n g costs,
have
bunker
and the p r e s e n t
of the b u n k e r cost r e d u c t i o n s To e n a b l e
a given
system
should p e r f o r m well
2.
High course efficiency. course c i r c l e
at a n o m i n a l
Safety,
in structural,
4.
Low or n e g l i g i b l e
thrust
o p e r a t i o n and failsafe
directly
period.
while
from
the wind;
figures b e l o w
terms.
This
a maximum
of
is
the
result
of
an
a w i d e range of course angles,
a m o u n t s of f u e l , r e l i a b l e for
system;
towards
c r e w demands.
strongly over
attainable.
it
in the v e s s e l
Thus 100% w o u l d o n l y be a v a i l a b l e
of g i v i n g
for a w i n g s a i l
aim
field,
This we d e f i n e as the p e r c e n t a g e of the 360 d e g r e e
system effectiveness.
pay-back
in t h e
o v e r w h i c h forward thrust can be a p p l i e d
60% suggest rather poor overall
Short
cost by such systems.
contribution
80% w o u l d be a v e r y good figure
thrusting
of total
arises b e c a u s e
levels in a given w i n d per unit size.
system capable
3.
5.
40-60%
assistance
low c a p i t a l
a worthwhile
i0 knot forward speed.
turbine
a m o u n t to some
against the f o l l o w i n g criteria:
High m a x i m u m t h r u s t
a wind
costs w h i c h
o f f e r e d at quite
to m a k e
I.
total
fuel
thrust t o w a r d s w i n g s a i l
and cheap to maintain,
3 years,
and
1.5 to
with
2.5 y e a r s
efficient saving
system,
considerable
l o w f i r s t cost. seems
likely
to
We be
87 THEORY AND PRACTICE
All
the aerodynamic d e v i c e s
proposed to extract solar energy from the wind for
ship p r o p u l s i o n work on e x a c t l y the same principle, and using the r e s u l t a n t reaction force in some way. opposed
reactions,
and so the o u t p u t
transmission system. the vessel,
Auto-rotation
so do all
is a t o r q u e
systems
of d e f l e c t i n g
the air flow
Turbines have s y ~ n e t r i c a l l y calling
for
some
f o r m of
(autogyros) react direct force on to
Magnus effect rotors,
circulation
control
columns,
wings
and cloth sails. The
best
plotting
way
to
visualise
crosswind
force
this
deflection
coefficient
against
is p e r h a p s downwind
the
drag
envelope force
curve,
coefficient,
giving a characteristic symmetrical butterfly shape (Fig. 5).
L/D =
/
(
1oPPo~crE
TkCv..
CI
FO ~ C £
Fig. 5 The three main parameters measured by this graph are: m a x i m u m crosswind force coefficient
All
(A)
optimum crosswind force/drag ratio
(B)
maximum downwind force coefficient
(fully stalled)
vessels
apart from specialised
a b l e to p e r f o r m
(C and C')
o n e - t r a c k o n l y r e c o r d b r e a k e r s n e e d to be
just as w e l l on the p o r t t a c k as on s t a r b o a r d .
s y m m e t r i c a l l y i n v e r t a b l e configurations,
This requires
which can fall into one of two possible
types: Symmetry across the wind line.
This group includes all square rigged ships, and
the Nippon Kokan system for example. Symmetry
along
the wind
line.
This group includes
all
fore and aft r i g g e d
yachts, and our own self trimming wingsail systems. The c h o i c e is i m p o r t a n t , e s p e c i a l l y
for h i g h l y e f f i c i e n t c o m p u t e r c o n t r o l l e d
systems suitable for fitment to modern minimally manned commercial vessels.
88 In Fig. 6 a c r o s s w i n d wingsail device.
force/angle
of a t t a c k c u r v e is d r a w n for a h y p o t h e t i c a l
It can easily be seen that if X is a "maximum permitted" anq[~
c h o s e n to p r e v e n t u n w a n t e d s t a l l i n g ,
( u n d e s i r a b l e b e c a u s e of s h a r p l y r e d u c e d
c r o s s w i n d force, i n c r e a s e d d r a g and the l a r g e " h y s t e r e s i s establish
a s m o o t h flow)
- then a t r i m m i n g
angular excursions from the set level, a less e f f i c i e n t the set level
will
system,
loop" n e e d e d to re-
A, p e r m i t t i n g
only
small
produce a higher mean thrust B than
t r i m m i n g system, C, p e r m i t t i n g w i d e r a n g u l a r e x c u r s i o n s
and giving a mean thrust level
device.
D, from exactly
/ ) M E A N T H R U S T OF C O N T R O L SYSTEM
B CROSSWIND FORCE
from
the same wingsail
~
' A'
D
CONTROL
Fig. 6 ANGLE
The efficiency of a trimming to rotate the wingsail
SYSTEM
'B'
0Y ATTACK
system is a function of the energy
against inertia and air
loads.
levels required
The "crosswind symmetry"
style of wingsail
system suffers in this respect because the pivot axis must be
at
in the
the
50%
point
chord
width,
while
the
c a m b e r e d s u r f a c e u s u a l ly acts at a p p r o x i m a t e l y leading edge
total
output
force
from
a
33% of the c h o r d b a c k from the
(or "luff").
Thus, t h e r e w i l l ship p r o p u l s i o n
always
be a m o m e n t of some 0.17 x c h o r d x force, a m o u n t i n g in
sized systems to many tonnes.metres of torque,
to be reacted by
the trimming system in addition to the effects of inertia, when the system tries to turn the wingsail
so as to avoid the highly undesirable stal 1 (Fig. 7).
FORCE
F
SUSTAINING
Fig. 7
MOMENT
REQUIRED
89
AIR DIRECTOR
Fig.
8
"Wind-line placed
symmetry"
by the d e s i g n e r s
system.
Thus,
automatic
governing
The aerofoil no less vital
when configured downwind
external
torques
easily
hold
Its
centre
thick
rounded internal
minimal
thrusting.
it c l o s e
zone should. resistance,
to p o i n t
a simple
'X' o n
and a longer
chord
cambered
(to port or,
image,
mode, useful
manoeuvring.
(Fig.
in mirror
8),
gives
for power-off
a
tests
of
spent
on this
tested
low downwind
drag when configured are
specifically avoiding
free,
with
reliable curve
safe,
control 6),
for
the n e e d for
extremely
(Fig.
at
drag
adapted
zone behaves
This a l l o w s combined
exactly
power-off low
system
airmay
giving
real
section,
with
predictions.
a short
chord
flap both c o u p l e d
modes
flat
very
design,
and
and we have
tunnel
of pressure
output
of three main elements,
T h e r e are t w o p r i m a r y
envelope,
the
very close to theoretical
consists
elements
structural
Thus
trimming
capable
independently
3.0, with
and its centre
air
on the
designs
of wind
has b e e n
than
section
hinges.
The
series
section
of more
of pressure
with
when
an air director
demands
trimmed
axis can be
can be produced.
separate
JW05-3
thrust
and stiff
w o r l d effectiveness
The section
torque
tail
for upwind work, and very high downwind
a light
as a wingsail
load
operation
and t w e l v e
masts or bracing wires;
weather-cocking
air
reliable
and the pivot
to be u s e d is of c o u r s e m o s t i m p o r t a n t ,
crosswind
running.
to a l l o w
fast,
Our present
of
this disadvantage,
and fail-safe
section
subject.
avoid
to m i n i m i s e
efficient,
than nine years
coefficients
load
systems
of o p e r a t i o n
leading
to it by simple
- flat
and robust
(or s y m m e t r i c a l )
and
to starboard).
low-drag,
alongside
low
situations
maximum and
thrust
performance
low speed close quarters
90
I
---4 /
l
Fig.
9
Maximum
cross-wind
mode,
while
(Fig.
9).
In
the
cambered
carefully
crosswind to s o m e
2.0; JW05-3 force
Fig.
force
flap
and
slotted
air
before
3.0.
director
of i n c i d e n c e
of
stall,
up to 35 to 40 degrees of
one third
of t h a t
move
flap configuration
of Flaunder
coefficients
20 d e g r e e s
turns
is a p p r o x i m a t e l y
is less t h a n t h a t of an e q u i v a l e n t
in a n g l e
wingsails
coefficient
i0
the
single
increases
p l a i n symmetrical
rotate
drag
mode
profiled
considerable
with
thrust
downwind
before
and Planesail 1.0;
highly
giving before
to p o s i t i o n s (Fig.
stall. stall
giving
This
a
allows
For e x a m p l e ,
cambered
with
i0).
the
at 12 to 15 degrees, unslotted
coefficients stall,
in the c a m b e r e d m a s t or d e r r i c k
rather
a maximum
shapes
less t h a n crosswind
91 SO far as m a x i m u m
downwind
very
can achieve
few devices
specially
designed
on s i n c e about
and
much more
parachutes
our early
0.5,
d r a g is c o n c e r n e d ,
and spinnakers.
symmetrical
we
now
than
days,
achieve
for s a i l i n g
over
f r o m t h e wind,
of a b o u t
1.2,
even
Our section design work has m o v e d
with downwind
just
away
a coefficient
1.3,
drag
quite
coefficients close
to
of o n l y
the
maximum
theoretical ly obtainable.
All
our primary wind tunnel
one metre JW05-3
span and 0.3m chord,
section
displays
the g r a p h s
for 10 m / s
interested
in t r i p l a n e
model,
work has been performed with m o d e l s
with which
fitted with end p l a t e s
extremely a n d 75 m / s
tolerant
and tested at 25 m/s. Number
characteristics,
a r e v i r t u a l ly i d e n t i c a l .
configurations,
such v a r i a b l e s
Reynolds
we also
as spacing
and
of a p p r o x i m a t e l y
have
Since
a triplane
stagger
have
we
are
wind
The and very
tunnel
been e x h a u s t i v e l y
analysed.
While more where
our e a r l y recent the
work
wind tunnel has
been
enthusiastic
test was carried
done
support
at
Cambridge
and
In
1976
prototype
we
initiated
2 form
2.7, as against
ii
over
(capable
of
Aerospace
University,
Engineering
Professor
the
Department,
Austyn
Mair
has
Filton.
- THE FLYER PROGRAMME
a programme
and demonstration
in its D a s h
Fig.
TESTING
University
encouragement
been a very great h e l p to us, and at British
FULL SIZE PROTOTYPE
out at Southampton
craft
aimed called
of a m a x i m u m
3.0 for the present
at
the
Flyer.
construction She
crosswind Dash
3).
utilizes force
of
a full
the JW05
coefficient
size
section of s o m e
92 Flyer
(Fig.
II)
free r o t a t i o n tail
vane
Filton are
a
the water,
controlled
Flyer
switched
to
yet
thrust
The
we
Flyer our
have
Fully
has shown
product
by
designed power
and the w h o l e
by
pack,
system
has
satisfaction,
thrust very
drag.
In
stationary
standing
silent
now
from zero to force
when
when
and
valves,
availability
low
lie quite
chaseboat
giving
control
5,
the
so desired,
the
computer
is
seen
sailing
and m o s t
she runs a w a y than
be be reliable, identical
of
the
of our Flyer
of
the
silent
f r o m the w i n d q u i e t l y not
only
on
and this
strong and c o n t r o l l a b l e , in M o d u l e
and gives
2 will
provide a
for ship propulsion.
JW05-3
and sought
section
criteria
trimming,
using
trace
a comparatively
may go a l o n g s i d e circle"
a tail
vane,
is t h a t
large
quays and other is
propulsive
configuration.
A natural
well
vessels,
within
thrusting
Here a central
the
area
the
vane
into
on
its
this
main sail panel
boom
view.
it is n a t u r a l l y We
according
for v e r y
to
careful
of the decision to go
in p l a n
beam.
place.
of ships,
2, c a l l e d
corollary
circle
product needs very
in the market
to the p r o p u l s i o n
testing work.
for s e l f
out
but a v i a b l e
after
set out in S e c t i o n
tends
possible
25 d e g r e e s
and e x h i l a r a t i n g
Planesail,
technology
t e s t s a n d t h e o r y are a l l v e r y w e l l ,
"trimming
within
abundant
2 SYSTEM DESIGN
evaluation
triplane
will
performance
if it is to be valuable
application
maximum
specially
The h y d r a u l i c
with
70hp
stalled,
itself
definition
this
union
are
to the h u l l
a DC e l e c t r o h y d r a u l i c
of great
already
far greater
the s y s t e m
vessel
actuation
but on a l l o t h e r s as w e l l .
THE MODULE
to
vane
the s a i l s e t
Franklin,
progressive
"closehauled",
showing
most acceptable
Wind tunnel
including Spencer
give
us e v e r y hope that the v i r t u a l l y
much more,
rotary
direction
leaving
but
when
p o i n t of s a i l i n g ,
TOWARDS
four-way
as p l a n n e d .
experienced,
off the wind.
The sailset
and
on a ratio
"Ahead".
wind
effectively,
Flap
connecting
been a source
exactly
and
boom.
mounted
by a low a s p e c t
and sensitivity.
crosswind
away
continue,
apparent
has
wingsail
It is t r i m m e d
pathways
hydraulics,
by microprocessor,
wind
lower
friction
reliability
thrust
accelerating
a 7.2m x 2.5m s i n g l e
Ltd and p a r t l y
in e i t h e r
highest
Tests
low
by U C C
controllable
maximum
a single
The other
partly
with
four hydraulic
through Ltd.
long,
ring type bearing.
on
means,
worked with great
On
10m
mounted
hydraulic passing
is
slewing
desirable
therefore,
circle,
to
decided
is flanked
or b o o m s
So t h a t
the that
get
the
upon
the
by two
93 lighter ones, all three being c o n t r o l l e d by a single tail vane assembly. is of course some 5%-8% m u l t i p l a n e
loss in using such a layout.
There
The triplane
a l s o p r o v i d e s quite high e f f e c t i v e aspect ratios for good course efficiency. Module
2 has therefore three main panels, almost identical
rib h i n g e d e t a i l s The r e s u l t i n g
to M o d u l e
sailset
I, but e a c h p a n e l
in c h o r d w i d t h and
is 13.5m h i g h i n s t e a d of 7.2m.
(Fig. 12) has a n o m i n a l t h r u s t a r e a of 101 sq. m., and is
r a t e d at 2.5 t o n n e s of s t a t i c t h r u s t in a 25kt (13 m/s) b e a m wind.
The m a x i m u m
force a v a i l a b l e is 6 tonnes. The s a i l s e t s
are of m a i n l y
aerospace m a t e r i a l s panels
have
the c e n t r a l loads.
reinforced
plastics
such as p o l y m e t h a c r i l i m i d e
identical
external
design,
foams
section profiles,
calling
and epoxide
upon modern resins.
to reduce tooling
All
costs,
but
p a n e l h a s a v e r y r o b u s t s t e e l m a i n s p a r c a r r y i n g a l l the b e n d i n g
At the b o t t o m ,
this
is f l a n g e m o u n t e d
to a p r o p r i e t a r y
low friction
slewing ring main bearing.
I
1
Fig. 12 Both vane and flap have closed accepts
information
loop servo control
from transducers
g i v i n g wind
systems. speed,
The computer itself
apparent wind angle
to
the ships c e n t r e l i n e and apparent wind a n g l e to the sailset centreline. In operation,
the computer system configures and angles
optimum thrust available. the wingsails, for.
The
main
and whether close hauled, engine
will
be
reaching or running settings are c a l l e d
automatically
throttled
s t r e n g t h rises, or the c o u r s e a n g l e or w i n d d i r e c t i o n then
the
main
engine
p r o g r e s s i v e l y more fuel.
or
the sailset to give the
This process includes deciding on which tack to angle
engines
will
reduce
power
back.
If the
wind
become more favourable, further,
thus
saving
94 If
the
chosen
computer w i l l
A
full
diagnostic
approximately are
course
bridge,
the
+/-
If
the
the
checking
weather-cocking
s a f e l y until
NAVAL A R C H I T E C T U R A L
the f a u l t
our
It w i l l
be
sailsets
are a b o v e
noticed
a
fault
for
and m e c h a n i c s
which
at
procedures
there
shewing a red
go to i t s
the drag.
is
no
light on the
symmetrical
settings,
CONSIDERATIONS
that the b r i d g e has as full
most cases panel
to w i n d w a r d ,
can be a t t e n d e d to.
It is i m p o r t a n t
of the s a i l s e t s
dead
thrust and m i n i m a l
hydraulics
cut its power,
automatically
therefore
mount
zone
electronics,
discovers
the s y s t e m w i l l will
degree
and a range of p h a s e d c l o s e - d o w n
computer
sailset
20
g i v i n g no c r o s s w i n d
one second i n t e r v a l s ,
available,
and
in
programme,
available.
redundancy
lies
feather the sailsets,
that
on t u b u l a r
a f i e l d of v i e w as possible,
steel
columns,
so that
the upper edges of the b r i d g e w i n d o w s
only
heights will
very
moderate
approximate
height
sailsets
the
(Fig.
are
and we
lower
edges
13).
specified
- in
to the b e a m of the ship.
\
. . . . .
Fig.
F
±__
13
There are further benefits
small maxima,
heel
resulting
angles,
from these m o d e s t
averaging
2 to 3 d e g r e e s ,
e v e n in the worst conditions.
sailset specifications:
with only
5 to 8 d e g r e e
95 low column
-
loads,
of the s a m e o r d e r
a v e r a g e deck crane installation, plates
of rhythmic
to 50%, w i t h reduction.
later
constant
first
vessel
level
to speed
bridge
monitor
speed/economy
most
course
pitch
control
energy
course
installations
will
emerge
propulsion
ship
propeller
over
and
perhaps
speed
tend
the m i n i m u m
level
Eventually,
with
main p r o p u l s i o n
for
data
scheduled
a
the
range
of
permit
Cargo handling
enough
blend
until
crane.
in
the
levels,
wingsail
of
controllable
installations
being
specified.
both engines
would
run at say 90%
being
progressively
raising
again
the output
progressively
ie 20% to 25% of t o t a l
installed
direction
with
both are at say 40% MCR.
completely,
very
rpm
with
wingsail
well
with
this
against
load
for
pitch
ranges
are not predicted
operation
area
problems
"Eastgate",
and
In
throttled
The next stage of the remaining
throttling
back to
installed
rating.
a strong
wind,
- the w i n g s a i l s
each
of operation,
different
all
used,
rating.
115 d e g r e e s ,
to add a p p r e c i a b l y
as
Fully already
to i n s t a l l e d
costs,
stopped.
importance
owned
pattern
of a p p r o x i m a t e l y
with main engines
is of c o u r s e of v i t a l
to vessels.
handling
for
in due
be shut down.
to o p t i m i s e designs,
vessels,
adapted
further
output
for e x a m p l e ,
improve,
a high
could
exist at Stone Vickers,
cargo
distance/time
onto existing
move
engine
of 40% to 50% MCR,
c.p p r o p e l l e r s
handling
the
systems can a l s o be used,
specifically
to
engine at the same time to 80% M C R before
wingsails
only
the vessel
for the same
recommendations
in l o w w i n d c o n d i t i o n s ,
be to cut out one engine
and w i l l
and profit.
can a l l o w
memorising
roll
l o s s or d a m a g e
is of course
later,
be retrofits
multiple
as wind conditions
present,
above
information
range of power
back,
feathering
aerodynamic
cargo
crew effectiveness
conditions,
designs
will
a wide
would
at
being cut by 30
using our products.
specifications
operation
for s e r v i c e
Modern
active
Later generations
planning
will
such a design with twin engines MCR
full
in light winds
based weather
amplitudes
resistance,
system described
possible.
wind
showing
early
engine
flexible
as the
options.
there
auxiliary
Main
speed
Satellite
affording
can reduce
lower speed running
time.
in beam sea,
and increase morale,
up in f a v o u r a b l e
arrival
While
versions
of sophistication
so as to permit
rolling
This effect
and seasickness,
The
for e x a m p l e
o n l y for simple deck d o u b l i n g
etc.
reduction
-
of m a g n i t u d e
calling
in c o n s i d e r i n g
by R o w b o t h a m
Tankships
must
be kept
simply
the fitment Ltd,
clear
presents of
the
of no
hose
96 LOW
level
horizontal
cranes m o u n t e d on the wingsail
to s o l v e
most reefer,
vessels
alongside
confident
container
high
walls
that the innovative
s o l v e most of the snags
Car
carriers
adapted
and R o - r o
to benefit
are also
at
low tide
skills
support c o l u m n s
cargo problems, may
present
of t h e c a r g o
seem l i k e l y
although
smaller
difficulties
handling
- we a r e
specialists
will
l i k e l y to arise.
vessels,
provided
from w i n g s a i l
favoured,
prove e s p e c i a l l y
and general
the reduced
valuable
that
auxiliary
stability
propulsion,
noise and vibration
is adequate, while
seem w e l l
passenger
levels
seeming
vessels
likely
to
in the c r u i s e market.
SUMMARY
We are of
confident
this
new
considerable wingsail
that
no m a j o r
industry's quantities
installations
technical
progress of bunker
becoming
fuel
an
or o p e r a t i n g
towards each
saving year.
increasingly
problems the
lie in the path
shipping
We t h e r e f o r e normal
sight
on
industry
look forward to the
oceans
of
the world.
BIOGRAPHY
John W a l k e r since
1965,
developing computer
is 47, and was o r i g i n a l l y he
has
aerofoil
control
been
t r a i n e d as an a i r c r a f t
concentrating
sections,
self
virtually trimming
engineer.
exclusively
systems
and
to their p r e s e n t high level of s o p h i s t i c a t i o n .
However,
on wingsails,
their
associated