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SOCIETY FOR
UNDERWATER TECHNOLOGY
Vol 19 No3
Editor: John Howes
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Editorial
Zoltan Vinegar
Research
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CONTENTS
22
COVER STORY: Deep Sea
Energy
SubCtech Battery
Storage Skid lifted
into ocean by support
vessel after successful
re-charging campaign
NEWS from the
OceanBusiness show
inSouthampton……
…..and Global Offshore
Wind
UNDERWATER IMAGING
Luxus IP Camera,
SmartSight, Deep vision
SOLAR POWERED USVs
Blue Trail, Openocean
Robotics
Seasats,Seatraac,
Echoblue
TRENCHERS
Amphibious HiTraq jetter,
100th Plough, Jet -it, NKT
T3600, Pretrenching
26
30
40
As global demand for deep-sea
energy, surveillance, and
infrastructure expands, the
subsea technology market is
undergoing a transformation.
Subsea power systems must
evolve to support more
autonomous platforms, operate
at greater depths, and reduce
emissions—while remaining
compact, efficient, and fail-safe.
SubCtech, founded in 2010 by
applied physicist Stefan Marx, has
positioned itself as a global
leader in advanced underwater
energy solutions. Based in Kiel,
Germany, SubCtech specialises in
subsea power ands batteries
custom engineering, and rigorous
prototype validation for a wide
range of subsea applications.
With a growing team and
expanding global reach, the
company delivers smart, field-
tested systems that reduce
CAPEX, OPEX, and CO₂
emissions—a win for industry,
security, and sustainability.
AUVS, OFFSHORE ASSETS &
OCEAN MONITORING
SubCtech’s Ocean Power product
line includes lithium-ion battery
systems, energy storage
solutions, and telemetry tools
built for:
● Offshore Oil & Gas CCS
● Environmental monitoring
● Autonomous and remotely
operated vehicles (AUVs, ROVs,
USVs)
At the core of this portfolio is the
INNOVATIVE AND SUSTAINABLE TECHNOLOGIES FOR THE
RAPIDLY-GROWING UNDERWATER MARKETS
DEEP SEA ENERGY
Battery Storage Skid lifted into ocean by support vessel for
first deployment
NEWS
PowerPacks line—robust, long-
lifespan battery systems (up to 25
years) that power everything from
portable sensors to large-scale
underwater platforms.
Engineered for operation in harsh
subsea environments, the
PowerPacks come in a variety of
pressure-tolerant housings
including:
● Titanium: for ultra-deep
missions up to 6000m
● Super-Duplex Stainless Steel:
rugged and corrosion-resistant,
also to 6000m
● Marine-grade Aluminum:
optimized for shallower
operations up to 1000m
BUILT FOR POWER, PROVEN IN
THE FIELD
SubCtech’s battery systems
undergo extensive qualification
testing—including resistance to
shock, vibration, thermal
variation, and electromagnetic
interference. All systems are built
to meet or exceed:
● UN T38.3 (transport safety)
● API17F / API17Q (subsea
equipment reliability)
● MIL-STD, DNV 2.7-3 (portable
offshore units)
The Li-Ion-based PowerPacks
offer automatic protection
against overvoltage,
undervoltage, overcurrent,
overheating, overcharging, and
short circuits and smart algorithm
for complex ESS system.
An intelligent Battery
Management System (SmartBMS)
constantly monitors and
optimizes performance from
individual cells to full module
arrays.
These systems also support AI-
based predictive analytics and
remote diagnostics—enhancing
reliability while minimising
downtime.
PowerPacks can deliver higher
peak currents, operate in sub-
zero temperatures, and support
long-term deployments with
minimal maintenance.
SUBSEA ESS: POWERING THE
ENERGY TRANSITION
A major milestone for SubCtech
is the development of a modular,
scalable Subsea Energy Storage
System (ESS)—the first of its kind
to be certified under API17F and
reach TRL 6 (Technology
Readiness Level 6), validated in
real-world offshore deployment.
The ESS includes:
● Two 1 MWh Battery Storage
Skids (BSS)
● Integrated Power Skid (AC/DC
converter)
FAULT FINDING • CONSTRUCTION • DECOMMISSIONING
Subsea Test Tools
www.c-kore.com
Tel: +44 (0)1904 215161 • Email: sales@C-Kore.com
Insulation Resistance
Electrical TDR
Optical TDR
Sensor Monitor
C-Kore’s patented test tools automate the entire
testing process, achieving significant cost savings. It’s
safe for use on all subsea infrastructure, giving you
better data much faster without extra personnel.
Now with
Optical TDR
● Auto-configuration via
SmartBMS and BCM (Battery
Control Module based on NetDI
technology)
● Redundant architecture for
continuous operation
● Modular expansion to 6 MWh
capacity
Built for a 25-year lifespan, the
ESS currently supports 2000m
deployments, with options for
3000m and 6000m depths. The
system has already been
successfully implemented in the
oil & gas sector, with an
immediate reorder confirming its
value and dependability.
FROM AUVS TO
INFRASTRUCTURE: FLEXIBLE
APPLICATIONS
SubCtech’s vehicle batteries and
subsea systems support a wide
array of defense and industrial
use cases:
● XXL-AUVs for surveillance,
mine detection, and deep-sea
intelligence (up to 12 modules at
100kWh each, totaling >1 MWh
at up to 1000V, in serial or parallel
configurations)
● AUVs with 416 mm, 310 mm or
260 mm battery modules
diameter for underwater
inspection or monitoring
● Docking-enabled AUVs and
ROVs, autonomously charging at
seabed stations without surface
recovery.
The ESS also provides buffering
for renewable energy sources like
wave, wind, and solar power, and
powers subsea compression,
injection, and monitoring
equipment—key to the offshore
energy transition.
ENGINEERING FOR EFFICIENCY
AND SUSTAINABILITY
By minimising the need for
vessel-based operations,
SubCtech’s systems dramatically
reduce both operational costs
and emissions. The ESS can
replace long umbilical
connections, reduce cable
infrastructure, especially long
tiebacks or CCS and extend
autonomous deployment
durations—all while maintaining
high safety and reliability
standards.
The redundancy concept ensures
uninterrupted supply to critical
subsea loads, and smart
telemetry systems enable
wireless underwater
communication via Acoustic
Telemetry Modems (ATM), with
ranges up to 6000m.
GLOBAL GROWTH, LOCAL
EXPERTISE
With 80 employees and tripling
production expansion in 2025,
SubCtech continues to scale
responsibly. Their UN-certified
battery systems are airfreight-
compatible and shipped globally,
supported by a professional
international sales network.
1 MWh Battery Storage Skid deployment
Battery Storage Skid
NEWS
Empowering
The professional portable underwater vehicle.
Seaeye Falcon
The Seaeye Falcon is the most versatile underwater electric
robotic system in its class. Compact, powerful, and depth-rated
to 300m or 1000m, it excels in demanding missions making it
the trusted choice for critical underwater tasks worldwide.
Learn more at: saabseaeye.com
OCEAN BUSINE
function ensures high contrast
across different seafloor types.
Both models include integrated
pitch, roll, heading and pressure
sensors for precise navigation
and depth measurement, helping
users to collect accurate, high-
resolution data in the most
demanding underwater
environments.
Typical applications for the
GeoScan family include Search
and Recovery (SAR), hydrographic
surveying, object detection and
identification, inspection and
engineering support, and marine
geology and archaeology.
It comes with a with a standard
50m tow cable.
GeoAcoustics also
has expanded of its
custom cable
moulding and
assembly services for
subsea equipment
manufacturers, marine
systems integrators
by acquiring a
specialist cable
moulding company
located near its
Yarmouth HQ.
Overmoulding
GeoAcoustics showed its new
sidescan sonar at Ocean
Business. Weighing only 25kg,
the GeoScan is able to be
carried by a single person. The
range currently features two
models, both offering
simultaneous broadband dual
frequency operation and
advanced sonar processing
features.
The GeoScan 2361 operates at
300 kHz and 600 kHz to
maximise range performance,
while the GeoScan 2491 runs at
400 kHz and 900 kHz to deliver
even higher image resolution.
Both include a fast 60 kHz
update rate, CW and Chirp
pulse options, no near-field
blurring, and a maximum
operating depth of 300m.
GeoScan features high-definition
capabilities that combines ultra-
short pulses and pulse
compression to enhance image
resolution and range definition.
A dynamic variable aperture
focusing system enables higher
resolution at shorter ranges and
improved image quality at
longer ranges, while an
automated image equalisation
GEOSCAN
This strategic move unlocks
increased capacity and
specialist expertise, enabling
the delivery of complex, high-
reliability cable mouldings
and terminations for a wide
range of marine and subsea
applications.
Cable moulding is a critical
process in the production and
use of underwater
equipment, involving the
sealing and encapsulation of
cable terminations to ensure
electrical integrity, water
ingress protection, and
mechanical durability under
harsh ocean conditions.
NEWS
SS
Gyrocompassing IMU
MRU
Norwegian Subsea’s Motion Reference Units
(MRUs) are now available integrated with
WASSP’s multibeam sonar systems, offering
enhanced motion data accuracy and
performance for offshore applications.
Designed for simple setup and operation,
Norwegian Subsea MRUs offer comparable
heave accuracy to RTK-enabled systems without
requiring RTK infrastructure.
This is said to be a game-changer for offshore
survey and deep-sea fishing, as precision depth
correction for multibeam data is possible when
external corrections are not available. Further,
the MRUs are ready calibrated and
maintenance-free, reducing downtime and
providing long-term reliability for users.
Well-known for striking a balance between cost
and performance, WASSP’s multibeam systems,
which target the sustainable fishing and marine
survey markets, now achieve higher accuracy
and performance through the integration of
Norwegian Subsea MRUs.
The package is especially beneficial for
customers operating offshore, as the MRUs
compensate for vessel motion with exceptional
precision even in challenging sea states.
WASSP
SBG Systems has unveilled the world's First
MEMS-based Gyrocompassing IMU.
SBG Systems, a leader in high-performance
Inertial Measurement Units (IMU) and Inertial
Navigation Systems (INS), has introduced the
world’s first MEMS-based North seeking IMU,
capable of operating without GNSS aiding—a
breakthrough in MEMS technology.
This leap forward paves the way for future
products, including AHRS and INS solutions, to
further expand the possibilities of MEMS-based
navigation. This innovation marks a major
milestone in inertial navigation by bringing the
benefits of MEMS sensors to the world of high-
performance navigation and orientation.
This MEMS-based IMU provides unparalleled
precision, achieving a heading accuracy better
than 1° secant latitude without GNSS aiding,
and an INS heading accuracy better than 0.01°
when fused with GNSS using SBG Systems’
state-of-the-art navigation and orientation
algorithms.
Furthermore, this is a true MEMS-based
gyrocompass with no moving parts, that doesn’t
rely on carouseling, ensuring durability and
reliability in all environments.
MEMS IMU
10
Sonardyne has launched the groundbreaking
SPRINT-Nav U, one of the world's smallest hybrid
acoustic-inertial navigators designed specifically
for compact marine robotic platforms.
This technology delivers the proven performance
of Sonardyne's SPRINT-Nav family in a package
measuring just 135 mm tall by 114mm in diameter
and weighing only 600 grams in water.
SPRINT-Nav U represents a significant
advancement for operators of small ROVs, AUVs,
towfish and USVs, who can now access survey-
grade navigation capabilities previously available
only to larger platforms.
The system combines four critical instruments—
AHRS, DVL, INS, and pressure sensor—into a
single unit with one connector and one cable,
dramatically simplifying integration while
optimising size, weight, and power consumption.
"SPRINT-Nav U transforms what's possible for
small robotic platforms. Operators can now
conduct complex inspections
and surveys around offshore
structures, ports, and harbours
with exceptional accuracy and
reliability, without the need for
large-scale vessel
deployments," said Aidan
Thorn, Business Development
Manager – Marine
Robotics, Sonardyne.
Key features and benefits
●
Ultra-compact design:
Measuring 135 mm x114 mm
and weighing only 0.6 kg in
water (1.98 kg in air), SPRINT-
Nav U fits into spaces
traditionally occupied by just a
DVL
SPRINT-Nav
●
True north seeking: Maintains accurate
heading even in ferrous environments where MEMS-
based navigation systems struggle
●
Survey-grade performance: Delivers 0.1%
error for distance travelled during typical surveys,
with heading accuracy of 0.15°
●
Extended altitude range: 500 kHz DVL
maintains bottom lock at up to 100 m altitude
●
Rapid deployment: Aligns in just 5 minutes
with DVL bottom lock
●
Easy operation: Familiar web user interface
shared with SPRINT-Nav Mini, with outputs
compatible with third-party software
GAME-CHANGING CAPABILITIES
SPRINT-Nav U is particularly valuable for offshore
wind operations, where its compact FOG-based IMU
provides continuous, high-accuracy position,
orientation, and velocity data even when operating
in and around steel structures.
This capability enables operators to
conduct thorough inspections of
wind turbine foundations, cables, and
other subsea infrastructure without
the interference issues common to
magnetic-based systems.
"The ability to maintain accurate
navigation in and around ferrous
structures is a game-changer for
operations such as offshore wind
farm monitoring and maintenance.
SPRINT-Nav U ensures operators can
collect consistent, high-quality data
near steel components where other
systems would fail." John Houlder,
Senior Product Manager, Sonardyne.
SPRINT-NAV U
NEWS
SONARDYNE
11
HYPERION 32
eBOSS
EDGETECH
EDGETECH
BURIED OBJECT
BURIED OBJECT
SONAR SYSTEM
SONAR SYSTEM
• Unmatched Clarity
See through the seabed with precision
• Compact & Efficient
High performance with reduced
size & weight
• Seamless Integration
Pairs with EdgeTech 2205 for
full-spectrum obstacle detection
Advanced 3D Imaging
Beneath the Seabed
Discover the power of
broadband, sediment-
penetrating Synthetic
Aperture Sonar (SAS) for
high-resolution imaging
of buried objects.
eBOSS
Redefining subsea imaging for faster,
more effective site clearance
Seabed
What eBOSS sees
UK-based environmental
monitoring instrument
manufacturer, Teledyne Valeport
Water has released the
Hyperion32, the latest addition to
its Hyperion range of high-
performance optical instruments.
Designed specifically for inland
water and shallow marine
environments, the Hyperion32 is
depth-rated to 50m offering a
cost-effective alternative for users
who don’t require deep-sea
capability.
Its streamlined 32 mm diameter
housing also offers a lighter, more
compact form factor, making it
ideal for a broad range of water
quality monitoring applications
where space, ease of deployment
are key considerations.
The Hyperion range is an industry
leading suite of optical sensors,
packaged in Teledyne Valeport’s
signature Titanium housings,
offering precise measurement of
an ever-increasing number of
parameters. With the Hyperion32,
Teledyne Valeport Water delivers
the same trusted optical
performance found in the original
Hyperion, now optimised for
shallow marine, inland and
industrial water operations.
The Hyperion32 is a versatile
sensor ideal for a wide range of
users, including: environmental
monitoring, academic research,
agriculture, municipal water
management, industrial
compliance, conservation,
aquaculture, and civil
engineering—anywhere precise
shallow water data collection is
essential.
“This new sensor offers the same
trusted optics as our deep-water
Hyperion, in a smaller, lighter, and
user-friendly form. It’s a practical
solution for professionals who
require precision and reliability—
without investing in deep-sea
capabilities they don’t need,” said
Nick Smedley, Business Manager
at Teledyne Valeport Water.
TELEDYNE VALEPORT
Hyperion 32
12
Kraken Robotics has received new orders totalling
more than $3 million for Kraken Synthetic
Aperture Sonar (SAS).
The Kraken SAS systems will be integrated on
small and medium-class uncrewed underwater
vehicles (UUVs) for clients in Asia Pacific, Europe,
and North America.
"Kraken SAS enables clients to significantly
increase the capabilities of their uncrewed
platforms, providing a larger swath with consistent
high resolution, enabling missions to be
completed faster and more accurately."Greg Reid,
President and CEO of Kraken Robotics.
One of the orders is for the University of Southern
Mississippi's Roger F. Wicker Center for Ocean
Enterprise, which will be outfitting a variety of
autonomous underwater vehicles (AUVs) and
autonomous surface vessels (ASVs) with Kraken
SAS to support research, development, testing,
and evaluation activities Kraken SAS integrates
the capability to perform imaging and
bathymetric mapping simultaneously, offering
user selectable 3 cm x 3 cm or 2 cm x 2 cm
processing and increased ranges up to 200 meters
per side.
Its flexible, modular design allows integration
across all small, medium, and large diameter
UUVs rated to 300 1000 or 6000m depths.
Kraken SAS Image
Ocean services provider DeepOcean has
acquired Shelf Subsea, an independent provider
of subsea services with a strong position in the
eastern hemisphere.
“DeepOcean and Shelf Subsea offer similar
services, but have distinct geographical
strongholds that complement each other. When
combined, we will provide customers worldwide
with access to a comprehensive pool of expertise
and capabilities. says Øyvind Mikaelsen, CEO of
DeepOcean.
The combined group will have approximately
1,800 employees and generate more than USD 1
billion in revenue.
Eelume has acquired the Trondheim-developed
underwater hyperspectral imaging technology
Ecotone, bringing together two Norwegian
technologies to unlock new possibilities for
ocean observation and environmental insight to
discover more.
Eelume, known for its autonomous, bio-inspired
and highly manoeuvrable underwater vehicles is
strengthening its capabilities by integrating
Ecotone’s advanced hyperspectral imaging
systems.
The acquisition paves the way for long-term,
intelligent monitoring of the marine environment
— essential for industries and ecosystems alike.
From research to real-world impact
Ecotone was founded in 2010 as a spin-off from
the Norwegian University of Science and
Technology (NTNU). Over more than a decade,
the company has developed underwater sensors
capable of mapping and characterising marine
habitats with exceptional precision.
DEEPOCEAN: SHELF SUBSEA
EELUME:ECOTONE
KRAKEN ORDER
NEWS
13
1-6 MWh Energy
Storage Systems
Intervention
Batteries
Wave Energy & Wind
Battery Storage
Subsea UPS &
Converter
AUV / Drone
Docking Station
Vehicle Batteries
API17F
Ocean Power & Monitoring
Transform into the cost-efficient and sustainable future
14
Sonardyne has been selected
through a competitive bidding
process to deliver baseline
environmental monitoring
services for the UK’s first
offshore carbon capture and
storage (CCS) site.
The company has been
contracted by the Northern
Endurance Partnership (NEP),
the developer of the onshore
and offshore infrastructure
needed to transport carbon
dioxide (CO2) from carbon
capture projects across Teesside
and the Humber – collectively
known as the East Coast Cluster
- to secure storage under the
North Sea. The infrastructure is
crucial to achieving net zero in
the UK’s most carbon intensive
industrial regions.
Sonardyne will provide
environmental monitoring, in
SEABED MONITORING LANDERS AND
ASSOCIATED SERVICES FOR NEP PROJECT
1000TH TESTING TOOL
the form of seabed landers, at key
locations above and around the
subsurface Endurance site – the
saline aquifer located 145km off
the coast of Teesside where
captured CO2 will be stored.
Monitoring of the site will begin in
the summer of 2026 to provide
baseline data for a duration of
two years before the
transportation and storage of
captured CO2 commences. The
seabed landers will be equipped
with Sonardyne’s Edge data
processing application, power
management and acoustic
through-water communications to
enable long-term, remote battery-
operated deployment.
Each lander will also contain a
suite of hardware including
Sonardyne’s Origin 600 ADCP,
Wavefront’s passive sonar array
and multiple third-party sensors.
Together, this technology can
detect small changes in water
chemistry across a wide area,
while the data can be harvested,
without retrieving the lander,
using wireless subsea acoustic
communication techniques.
Monitoring is a key activity for
offshore CCS developments
to verify safe containment
of CO2 within the
reservoir, provide
reassurance to
stakeholders and foster
public confidence in this
greenhouse gas
abatement process.
Sonardyne will
provide seabed
landers at key
locations around
the subsurface
Endurance site.
C-Kore Systems is celebrating
an exciting milestone with the
deployment of their 1000th
subsea testing tool, to Australia.
This significant achievement
was marked by the mobilisation
of the C-Kore tools to an
Australian offshore energy
project for one of their key
customers, Fugro.
Australia is one of C-Kore's
largest markets, where their
tools are helping oil and gas
operators save money by
simplifying their subsea testing
operations.
C-Kore's subsea testing tools
have quickly become a game
changer in the offshore oil and
gas industry, earning
widespread recognition with
both operators and contractors
for their quick and accurate
results. The ease of use of the
battery powered autonomous
units means specialised
offshore personnel are not
required to accompany the
units, equating to big cost
savings on offshore testing
campaign.
NEWS
SONARDYNE
C-KORE
C-Kore receiving the King’s Award
15
Sentinel
The global oceanographic
community is invited to gather in
Woods Hole this autumn for the
SLOCUM GLIDER USER'S
CONFERENCE, taking place
October 7-9, 2025. This three-
day event will bring together
Slocum glider users, marine
scientists, engineers, and
dignitaries for a collaborative
exchange of knowledge,
innovation and mission
collaboration.
The conference will culminate in
the official launch of the Sentinel
Mission on October 10, featuring
REDWING, the first autonomous
underwater glider that will
embark on the first ever AUV
mission to autonomously
circumnavigate the globe.
"This conference is more than a
technical gathering—it's a
celebration of innovation and a
launchpad for a mission that will
redefine what's possible in ocean
exploration," said Shea Quinn,
Slocum Glider Product Line
Manager.
CONFERENCE HIGHLIGHTS
●Expert Panels & Technical
Sessions on topics such as long-
endurance missions, passive
acoustic monitoring, storm
gliders, and under-ice operations.
●Advanced Training with sensor
vendors and glider specialists.
●Live Presentation and Poster
Sessions from the global glider
community.
●Networking Opportunities with
NOAA and WHOl leadership,
state officials, and academic
researchers.
The Sentinel Mission: A Global
First
The Sentinel Mission, a
collaboration between Teledyne
Webb Research and Rutgers
University to complete the first-
ever global circumnavigation with
an autonomous underwater
vehicle, is supported by NOAA,
the UN Ocean Decade, and the
Marine Technology Society. The
mission will launch from Woods
Hole on October 10, 2025, with
the deployment of REDWING, a
specially outfitted Slocum
Sentinel Glider.
The mission aims to:
●Demonstrate cutting-edge
oceanographic technology
●Promote STEM education and
student-led research
●Support global ocean
monitoring and climate science
Rutgers undergraduate students
are actively involved in planning
the glider's route, accounting for
ocean currents, recharge stops,
and geopolitical considerations.
The mission will also feature a live
online flight viewer, branded
outreach campaigns, and
educational content to engage
the public worldwide.
TELEDYNE MARINE TO HOST SLOCUM
GLIDER USER’S CONFERENCE
16
The new Teledyne Valeport pH
sensor developed in
collaboration with ANB Sensors,
introduces a cutting-edge, self-
calibrating solution for robust,
reliable pH measurements in
ocean monitoring. This
innovative sensor redefines how
pH is measured over extended
periods of time, offering a
powerful alternative to
traditional glass electrode
technology.
Traditionally, pH measurements
have used glass electrode
technology. While highly
accurate, this method requires
frequent instrument calibration
to prevent reference electrode
drift, resulting in lengthy sensor
downtime. Glass electrodes are
also more fragile and require
storage in very specific
conditions.
Unlike conventional pH sensors,
the new Teledyne Valeport pH
leverages Teledyne Valeport’s
respected engineering
expertise and ANB’s patented
calibration-free technology to
Teledyne Valeport
pH sensor
SELF-CALIBRATING PH SENSOR
create a leading pH sensor.
This advanced sensor is self-
calibrating, preventing
instrument downtime, reducing
calibration-related costs, and
significantly extending
deployment periods. The sensor
is also highly durable and easy to
store, making it a resilient and
superior alternative to traditional
pH sensors.
Engineered for versatility, the
sensor is rated to depths of up
to 1250m and delivers
exceptional accuracy of ±0.1 pH.
Its rugged titanium housing
ensures reliability in harsh marine
environments, making it suitable
for a wide range of applications,
including: fixed site monitoring,
buoys and frames, ROVs, AUVs
and ASVs.
What sets the Teledyne Valeport
pH sensor apart is its
combination of simple
operation, robustness, and ease
of handling and storage. It is
particularly well-suited for long-
term deployment scenarios due
to several unique features:
●
Robust solid-state
technology - for durability in
extreme marine conditions
●
Reference drift
compensation - to maintain
accuracy over time
●
Calibration-free
operation - in situ self-calibration
eliminates the need for frequent
recalibrations
●
Bio foul solution - a low
concentration of biocide is
produced at the sensor head to
keep the transducer clean and
ensure reliable data collection
●
More responsive
temperature compensation -
improving measurement accuracy
in varying ocean conditions
Designed with practicality in
mind, the Teledyne Valeport pH
sensor features Valeport’s
signature titanium housing and
measures 204mm in length with a
diameter of 47mm. It operates on
9-28V DC power with a
consumption of <32 mA @12 V
DC and weighs less than 1 kg in
air.
NEWS
TELEDYNE VALEPORT
17
SPRINT-Nav
The ultimate solution for
underwater navigation
Imagine a navigation system that delivers unparalleled precision, effortless integration
and reliable performance for every operation. The SPRINT-Nav family offers a
class-leading, all-in-one subsea navigation solution for all marine robotics and
autonomous vehicles.
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18
Teledyne Marine recently
unveiled its Compact
Navigator, a ground-breaking,
ultra-compact and advanced
autonomous integrated
navigation solution that
redefines performance in a
small form-factor.
“Extreme optimisation on size,
weight, power, performance,
and functionality makes the
new Compact Navigator
revolutionary,” said Rolf
Christensen, Head of Product
Management at Teledyne
Marine.
"It’s ultra-compact design,
high-accuracy, premium
titanium construction, and
ability to operate in
challenging acoustic
environments make it the new
‘go-to’ choice for operators
requiring reliable, high-
performance navigation in both
subsea and surface
applications.
It is Ideal for small vehicles, it
enables inspection and survey
applications not previously
achievable."
Available in two depth-rated
versions—4000m and 300m—
the Compact Navigator has
been developed using unique
Teledyne Marine technology by
navigation experts and in
consultation with key ROV and
AUV companies.
KEY ADVANTAGES
• World's Smallest High-
Accuracy Navigator – Measures
COMPACT NAVIGATOR
only Ø114mm x 135mm, fitting
within the volume of most
standalone DVLs, while still
outperforming much larger
navigation systems
• Ultra-Low Power Consumption
– Uses less than 7W, a
breakthrough in energy
efficiency. Allowing missions to
last longer and extending the
time before a vehicle needs to
surface.
• Seamless Integration – A single
lightweight unit with minimal
cabling simplifies installation,
reduces costs, and frees up
valuable space on compact
vehicles.
The Compact Navigator’s fully
autonomous operation
eliminates the need for external
aiding or operator intervention,
ensuring ease of use. It also
features comprehensive
connectivity, with power,
Ethernet, dual triggers, and serial
connections accessible via a
single connector.
The advanced phased array DVL
technology enhances
performance while maintaining
its compact size, allowing the
instrument to sit flush with an
AUV or ship hull.
Designed for versatility, the
Compact Navigator supports a
wide range of applications, from
ROVs and AUVs to shallow water
surface navigation, GNSS-denied
environments, and dynamic
positioning for surface vehicles.
It combines true North-seeking
gyrocompass-grade
performance with a rich WebUI
for integration, operation, and
troubleshooting. With a factory-
calibrated design and battery
backup option, it ensures high
reliability in demanding
environments.
Unlike traditional surface
navigation systems, the Compact
Navigator operates
independently of GNSS, making
it resistant to jamming or signal
loss. This breakthrough is
particularly crucial for shallow
water navigation, where
traditional GNSS-dependent
systems can fall short.
As autonomous surface vehicles
become more prevalent, a
robust and independent
navigation solution like the
Compact Navigator becomes
increasingly vital.
NEWS
TELEDYNE MARINE
19
STINGRAY
Dynamic Load Monitoring has
launched a new Acoustic
Positioning Grapnel called
Stingray.
It is positioned at the rear of a
train of multiple grapnels and
towed behind the vessel when a
pre-lay grapnel run (PLGR) is
being undertaken. It is located
the furthest away from the ship’s
stern.
It uses acoustics to send a signal
to a vessel towing the train to
communicate where it is on the
seabed.
Stingray is 1343mm long and
308mm high with the beacon
closed; with it open, it is 473mm
high. The main body is 500mm
wide and, depending on what
type of stabiliser is fitted, it is
900mm or 1500mm wide.
While there is only one body size,
there will be options in that
customers will be able to fit
different sized stabilisers to suit
deployment chutes. There will also
be the ability to fit different
manufacturers’ ultra-short baseline
(USBL) beacons to meet the
client’s preferences and what
receiver is already fitted onto the
vessel.
The acoustic grapnel is
manufactured from high-strength
structural steel and covered with a
special marine paint.
Martin Halford, managing director
at DLM, said: “The overall shape
of it is based on the front skid of
our wheeled detrenching
grapnel.
“As a grapnel train is being
towed it is often just assumed
that the train falls in line with the
direction and movement of the
vessel and follows the same path.
However, this is not necessarily
the case due to the length of the
tow line and also the length of
the train; the whole assembly can
wander and in some cases the
grapnel train could be outside of
the planned route.”
ACOUSTIC CORER:
REVOLUTIONARY 3D
SUB-SEABED INSIGHT
Kraken Robotics | Transforming Subsea Intelligence
www.krakenrobotics.com
Providing 3D visualization and live rendered
data, Kraken’s Acoustic Corer identifies
geohazards, stratigraphy, and boulders as
small as 0.2 m, ensuring efficient, risk-free
offshore foundation design and installation.
DLM
20
and the external water pressure,
preventing damage to the box
due to pressure differentials.
• MacArtney has also launched
its new SubConn Micro Circular
9-contact connector. With
enhanced features designed to
minimise signal interference,
this connector ensures optimal
data accuracy and efficient
underwater operations.
“The standard 8-contact
connector is very good for high
bandwidth data, even up to
gigabit Ethernet,“
said Jørgensen.
“Over recent years, however, we
have recognised that the
instruments currently being
developed, provide increasingly
more data and for some, even
one gigabit is not enough
anymore.
“8-contact connectors are
typically used for signal
transmission, and some users
have requested an additional
contact for enhanced security.
The ninth contact in the new
connector is intended for a
screen, providing an extra layer
of data protection and ensuring
higher bandwidth.
“We have been running tests
and found that it is possible to
get 10 gigabit of data and now,
we are establishing what kind of
cable length this will work with,
targeting harness cables for
high bandwidth sensors such as
4K cameras.”
MONITORING TRIPOD
MacArtney has designed a tripod
assembly accommodating the
growing focus on innovative and
efficient solutions for subsea
infrastructure surveillance,
spanning defence,
communication, energy
production, scientific research,
and environmental monitoring.
“We intend to use these tripods
as a base on which to attach a
variety of sensors,” said Lars
Jørgensen, Head of Product
Management. “This would
typically include a number of
hydrophones in order to listen
out for underwater vehicles,
divers that shouldn’t be there or
possibly anchors dragging along
the seabed.
“It is suitable for
attaching
hydrophones from
any manufacturer.
MacArtney
tripod
assembly
We are currently working with a
new model from a Dutch
company: Optics11. These are
purely fibre optic, and as such,
there are no electronics. A
benefit of this is that signals can
travel great distances.
“Aside from the exhibited tripod,
we also construct other
geometrical frames to meet
specific sensor requirements. We
envisage the tripod and frames as
a suitable mount for subsea
cameras, sonars, oceanography
and seismic sensors or ADCP
systems.
“An important part of the
arrangement is employing our
connectivity and data acquisition
expertise. On this particular
tripod, we have also incorporated
a junction box as well as one of
our latest multiplexers.
The MacArtney oil-filled junction
box is a robust, reliable junction
box designed for underwater
applications. It is specially
engineered to withstand
harsh marine
environments and
ensure reliable
electrical connections.
The oil-filled
environment inside the
junction box
helps equalise
the pressure
between the
internal
components
NEWS
MACARTNEY
21
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22
At the recent Renewable UK
Global Offshore Wind
conference and exhibition Terry
Griffiths, Director at Aurora
Offshore Engineering (and more
importantly, a founding member
of the SUT Perth Branch), talked
on the topic of "Thar be
Dragons", sharing lessons
learned from solving really
difficult design and integrity
problems for over 4000km and
22GW of subsea cable projects
across the globe.
In many ways, the rise of the wind
industry has built on the
inherited methods developed
over many decades by the
offshore oil and gas industry and
has been motivated as much by
environmental concerns about
the need to transition to
sustainable and renewable
sources of energy, as it is based
on energy security concerns. The
offshore industry has also been
transitioning as work
opportunities in the renewables
sector grow.
While the specifics and
economics between these
industries are different, it did not
take established offshore
companies long to exploit this
market. This has an added bonus
that there are to be considerably
more turbines than conventional
offshore oil installations. There
are very broad similarities.
Instead of production platform
jackets read offshore substation
jackets. Instead of oil pipelines,
read subsea cables. And this,
contends Terry, is a trap the
industry is sleepwalking into.
THAR BE DRAGONS
“We need to stop thinking about
subsea power cables as just small
oil and gas pipelines,” he said.
“A fundamental difference is that
because of the small diameter,
typically subsea cables have
Keulegan-Carpenter (KC)
numbers (a quantity describing
the relative importance of the
drag) that are in the range of 200
to 500. The typical oil and gas
pipelines, however, have a KC
number that's in the range of 30
to 50.
“Subsea cables also typically
have much smaller Reynolds
numbers, so the hydrodynamic
models that we've inherited from
the oil and gas industry are not
correct for subsea cables, and
using these engineering formulae
can result in fundamental errors
in the physics that is very relevant
to the design.”
“The reason the way pipeline
engineering has evolved because
of the hydrocarbon fluids they
Pipeline with rock bag
NEWS
23
contain. Leakage has the potential
to cause catastrophic events and
environmental devastation. It was
necessary, especially in the early
days of the industry, to over-
engineer. The underlying
reliability targets inherited and
adopted in the offshore wind
sector have largely derived from
trying to prevent catastrophic
events in pipelines.
“What we need to be looking to
do is move towards bespoke
design guidelines actually geared
towards the fundamental risks and
opportunities of subsea cables."
CABLES
Cables are very important. While
they cost roughly 9% of the
project CAPEX, they represent 80–
90% of insurance claims. Despite
being a relatively modest
proportion of the project cost,
therefore, cables are a
fundamentally unacceptably large
proportion of the reason for the
failure of wind farms to deliver.
“We are proposing that the
industry moves away from a
one-size-fits-all target of
reliability and actually
progresses towards setting
bespoke cable reliability targets
that are actually fit for purpose
in carrying the amount of power
that needs to be transmitted
through each cable.
“We suspect that will drive
fundamentally different cable
layouts as well,” said Griffiths.
“We have been able to identify
that across the offshore wind
sector, cables at the bottom of
the ocean are subject to very
different metocean criteria
because they have very different
response characteristics.
“What we've been able to do on
a number of projects is actually
re-evaluate the metocean
hindcast and redevelop fit for
purpose metocean design
criteria to suit the response
characteristics of the cables.“
CONSERVATIVE DESIGN
Since the early years of the
offshore industry, engineers have
adopted conservative
assumptions in the input
parameters.
“When it comes to subsea cables,
however, we repeatedly find there
is no universally conservative bias
that can be adopted. We can look
at the Goldilocks principle.”
In the eponymous fairy tale,
before Goldilocks went into the
house of the bears, she didn't
know which bowl of porridge or
which chair or which bed was the
right one for her. She had to try all
three.
“Similarly, the way in which we go
about designing subsea cables
needs to also stop making the
erroneous assumption that we can
both second guess and correct for
bias in each of the input
parameters. We need to model
these on a case-by-case basis until
we have reliable information.
“We recently carried out some
investigations on subsea cables
being installed for the Hollandse
Kust offshore wind farm in the
central North Sea to actually look
at what happens to real cables in
the real ocean conditions.
“That cable laying on the surface
was originally predicted to be
unstable, however using the
STABLEpipe design methodology
it was predicted that in reality the
cables would rapidly embed into
the seabed due to scour and
erosion.
24
Within the space of a couple of
hours after the cable was laid,
ROV images showed sand being
ejected out from under that
cable. The result was that the
cable rapidly became self-
embedded into the seabed and
thus became profoundly stable.
At adjacent locations on those
cables, where they crossed
existing assets (pipelines, cables)
buried in the seabed, they were
required to install hollow sleeves
on the outside of the cable to
guarantee separation with the
existing assets.
“Those hollow sleeves were
actually free to roll around the
cable which effectively meant
that the CSS, (crossing
separation system) was free to
roll backwards and forwards. This
made it profoundly and
fundamentally unstable.
Using our knowledge of cable
scour meant the crossings could
be installed with confidence,
knowing they would self embed.
“By analysing videos taken on
site, it is possible to observe the
rate at which sand is being
ejected out. This meant the
scouring was occurring
underneath that cable as
predicted.
“Again, within the space of 6–
12hrs, that system self-
embedded into the seabed and
became fundamentally stable
and did not move laterally.”
“When the installation
contractor returned to undertake
permanent stabilisation works of
the crossings, they found that the
cables and CSS had Indeed self-
embedded Into the seabed and
remained stable.
Elsewhere in Scotland, the group
have been looking at the power
cables that connect the UK's first
tidal stream energy project to the
grid - the MayGen tidal stream
project owned by SAE
Renewables.
“It is clearly possible to see the
extent to which these bare cables
- with no added external
protection applied to them, have
naturally found nooks and
crannies in the seabed into which
they have become wedged and
thus become self-stable.
“The seabed is characterised by
hard rocks and thus, the cables
could not buried. Instead, they
have been placed on the bare
rock surface. The rock was not flat
and on a smaller scale, had cracks
and boulders distributed across
the surface.
“Conventional wisdom would
suggest that the cables would be
free to slide across the surface
but upon investigation, the cables
embedded themselves between
the boulders and undulations and
ultimately self-stablised on the
seabed.
“It is critical to understand and to
learn by looking carefully at what
is happening in the ocean,
understanding the relevant
physics and then tailoring the
engineering solutions to suit.
“When applying the relevant
physics to the design, we
wind up being able to show
some rather extraordinary
outcomes that these cables
are actually self-stable.
“This is not what you would
expect if you just inherited
the oil and gas design
methods, and based on the
different sets of ROV footage
we've actually got proof when
we've taken the design
methods that were inspired
by watching the Maygen
cables and we've been able
to apply them to now two
offshore wind farms off the
Atlantic coast of Europe that
have been developed on
entirely rocky seabeds.
“It was a career highlight to
stand on the cliffs at Le
Croisic near St Nazaire and
look out towards France's first
offshore windfarm a few
weeks after it was
commissioned.
This project demonstrates
what we are advocating - that
the offshore renewables
industry actually needs new
design guidance that is
actually fit for purpose for
subsea cables.
They need to be based on a
new mindset a new paradigm
for how we go about setting
the target risk and the target
reliability for subsea cables so
that we one lower the cost
but two improve the
performance of cables.
NEWS
25
26
LUXUS IP CAMERA
This feature enhances versatility,
simplifies integration into various
systems, and improves usability in
diverse underwater applications. A
12-24 VDC supply powers the
camera and consumes only 3.5
W, making it energy-efficient
for prolonged use.
The increasingly streamlined
design of underwater
technology solutions
demands advancements in
instrumentation, equipment,
and systems development. A
primary focus during the
development of the new camera
was creating a compact housing
without compromising
performance, which MacArtney's
skilled engineering team achieved
with innovative design techniques.
Compared to previous models in
the LUXUS range, the new
Compact IP camera stands out with
its smaller size and IP feature,
offering enhanced integration
capabilities and improved
performance. The camera features
a ½ 8in Progressive Scan SONY
STARVIS CMOS sensor, providing a
resolution of 1920x1080 at 25fps
(2mp).
The LUXUS Compact IP camera
offers a horizontal angle of view
of 95.0° in air and 72.0° in water,
with a focus length of >0.5m
(F2.0). It supports multiple
control options, including
ONVIF (S), and features fully
automatic or manual gain and
exposure settings.
The camera's minimum
illumination is 0.05 Lux,
ensuring high-quality imaging
even in low-light conditions.
The housing is sandblasted
titanium for enhanced durability
and corrosion resistance,
consistent with the other
cameras in the LUXUS Compact
range.
Positive user feedback
"Feedback from early users has
been overwhelmingly positive.
Users have praised the camera
for its ease of installation,
compact size, and precise
image quality," said Ron
Voerman, Managing Director
with MacArtney Benelux.
SMALL FOOTPRINT, HIGH
PERFORMANCE
“The standard depth rating of
4000 metres and the low power
consumption are highly
appreciated features, and the
Subconn Micro connector
ensures compatibility with
existing systems.”
The long-term goals for the
LUXUS range include launching
a small LED and IP camera with
a higher data rate, superior
image quality, and a TrustLink
connector as standard.
MacArtney has launched
the LUXUS Compact IP camera,
our latest innovation in
underwater imaging technology.
Small, robust, and easy to
integrate, it is designed to meet
the diverse needs of
professionals across various
industries.
The new LUXUS camera
introduces IP capabilities,
enabling direct network
connection for remote viewing
and management.
LUXUS Compact IP
camera
IMAGING
27
SMARTSIGHT MV100
DeepSea has introduced the SmartSight MV100, the
first in its new line of cameras built specifically for
machine vision applications.
The camera system marks the company’s entry into
advanced computer vision technologies while
preserving the rugged durability that defines its
subsea products.
Optimal for systems integrating machine learning
and artificial intelligence, the SmartSight MV100
enables object recognition, navigation, and
inspection, enhancing autonomous subsea
operations with greater precision and efficiency.
Designed to meet the stringent demands of deep-
sea exploration and industrial underwater
applications, DeepSea says that its camera sets a
new standard for subsea imaging.
A Gigabit Ethernet interface ensures seamless
integration with existing platforms, while its low
power consumption extends operational
capabilities in autonomous vehicles. Its compact
form factor allows for easy manoeuvring and
portability.
The camera's lightweight design—0.44 kg in water
with a flat port and 0.37 kg with a dome port—
enhances adaptability for various deployment
scenarios. Encased in a robust titanium housing, the
SmartSight MV100 withstands extreme underwater
conditions, performing reliably at depths up to 6 km
with either the flat or dome port.
The MV100 offers sensor options
from high-sensitivity 0.4 MP to
better-than-HD 3.2 MP, all featuring
Sony Pregius global shutter
technology in both colour and
monochrome. A selection of focal
lengths from 2.3 mm to 6 mm
provides flexibility for different
imaging needs.
Compliance with GigE Vision standards, along with
support for discrete power and Power over Ethernet
SmartSight MV100
(PoE), ensures compatibility with industry
requirements. Digital input and output
channels facilitate triggering and event
synchronisation, making it highly functional
in complex underwater environments.
Compatibility with LED SeaLite SeaStrobe
lights further optimises illumination in
deepsea conditions. A dedicated sync
input and fast response times allow the
SeaStrobe to be used in machine vision
applications to freeze movement and
reduce power consumption compared to
continuous output LED lights.
Highly configurable, the SmartSight MV100
can be customised with various lens,
sensor, housing, and connector options for
seamless integration with existing systems.
The choice of optical port further allows
the MV100 to be tailored to specific
imaging requirements. The flat port offers
a reduced field of view underwater but
maintains the same optimal focus in air and
water. The dome port preserves field of
view across both mediums but achieves
optimal focus when underwater.
The dome port also allows the MV100 to
be configured to perform at depths up to
11 km.
28
Voyis has launched Deep Vision
Optics, an advanced optical
system designed to enhance
image clarity and sharpness in
subsea environments.
UNDERWATER IMAGING
LIMITATIONS
Underwater cameras face a
significant challenge in
maintaining focus across their
entire field of view and working
range due to the water medium.
Traditional dome viewports affect
image formation and focus,
leading to poor corner focus that
limit the usability of the camera’s
field of view. They also reduce the
depth-of-filed of the camera,
meaning both close-up and far
away targets cannot both have
optimal sharpness. The result is
image blur, reduced feature
tracking accuracy, and
inconsistencies in
photogrammetry-based mapping
applications.
THE DEEP VISION OPTICS
To address these fundamental
imaging issues, Voyis has
developed the Deep Vision
Optics, integrating an advanced
corrective optical design with
three key objectives:
VOYIS DEEP VISION
IMAGING
29
ELIMINATING IMAGE BLUR IN THE CORNERS
By optically correcting for the effects of the dome
viewport and water medium, the system ensures
nearly equal sharpness across the entire field of
view, allowing for full-sensor utilisation.
Enhancing Overall Image Sharpness: The new
optical system removes distortions caused by the
water medium, improving clarity not just in the
corners, but at the center as well.
Expanding the Depth of Field: With customized
optical engineering, the Deep Vision Lens enables
clear imaging of both nearby and distant objects,
crucial for precision inspections and wide-area
surveys.
BENEFITS FOR UNDERWATER OPERATIONS
Deep Vision Optics delivers industry-leading image
quality, maximising field-of-view utilisation to
enhance situational awareness for ROVs and
improve visual surveys with AUVs.
Optimised image sharpness boosts feature and
target detection, supporting machine learning
applications with reliable automated analysis.
Enhanced corner sharpness improves stability in
photogrammetry and VSLAM processes, while
higher depth of field ensures accurate
photogrammetry, reducing manual intervention
and accelerating data processing for faster, more
reliable survey results.
SETTING A NEW STANDARD IN UNDERWATER
IMAGING
Deep Vision Optics represents a significant leap
forward in underwater imaging technology,
empowering operators with the tools needed to
conduct more precise, efficient, and automated
subsea inspections. Voyis remains committed to
advancing the field of underwater vision, ensuring
that every detail beneath the surface is captured
with unparalleled clarity.
The system endeavours to produce underwater
imagery where the effects of the water medium
are entirely removed in real time.
The Observer 4K camera
enables integration into tight
platforms, and the Nova LED
panel can be adapted to
meet vehicle needs.
30
All Uncrewed Surface Vessels
(USVs) require a power source
and as such, any lack of
available fuel can limit their
range. Some are solely battery
powered and ideal for port
and harbour surveillance.
Others seek to exploit the
power of wind or waves.
A popular design solution is to
use solar power to charge a
battery directly. The battery
can power the vehicle at night
time and be recharged by the
sun during the following day.
Solar power means that
operational costs and
maintenance are typically low
when compared with diesel or
hybrid systems. The simplified
designs also have fewer
moving parts that reduces
mechanical failure risks.
Solar-powered vessels are also
environmentally friendly with
zero carbon emissions during
operation and minimal noise
pollution. This reduces
disturbance to marine life,
making these vehicles suitable
for conservation projects and
eco-sensitive regions.
Solar USVs also have a lower
thermal footprint, making
them less detectable in certain
defence scenarios.
The downside of the vehicles
stems from the dependence
on solar availability. There is a
reduced efficiency in high-
latitude regions or during
extended cloudy conditions.
This means that they need to
be coupled to larger high-
capacity batteries adding
weight and cost. The larger and
heavier the battery, the less
weight constraints and deck
space available for payload and
the power budget may restrict
the types of sensors and
communication equipment that
can be carried.
Solar panels are vulnerable to
corrosion, biofouling and
impact damage from debris.
Ocean conditions like high
waves and saltwater exposure
can degrade performance over
time.
Nevertheless, solar -powered
vessels have a number of
potential applications including
environmental monitoring and
oceanographic surveys such as
mapping ocean currents,
collecting weather data and
monitoring marine ecosystems.
These vessels could be used for
long-term studies of ocean
acidification, climate change
impacts and marine
biodiversity.They are also
suitable for maritime
surveillance and defence
coastal patrol, anti-
submarine warfare and mine
detection.
Many USVs such as wind and
wave-driven systems have
solar panels to provide
auxiliary power but there are
a number of vessels that use
solar power and the primary
fuel source.
SOLAR
POWER
Blue Trail Engineering launched
its prototype oceangoing ASV
from Avila Beach, California in
February earlier this year. It
successfully reached its
destination in Hawaii,
but moved on
towards Southeast
Asia.
The vessel has a
length of 2.6 m and
weighs 28 kg . Hull is
constructed of a wet
fibreglass layup co-
cured with expanding
polyurethane foam,
with G-10
reinforcements in key
locations. Solar panel
base is constructed
of 1/2" foam core
BLUE TRAIL
Blue Trail USV above….
SOLAR-POWERED USVS
31
ENGINEERING
laminated with carbon fibre.
Solar panel is a Sunbeam 126
which generates around 100
watts of power.
It has a carbon fibre rudder while
the is Keel fabricated from an
aluminium spine overmolded
with urethane. There is 4.5 kg of
lead in keel bulb.
The vessel is driven by a Blue
Trail Engineering MTR-2000
Motor connected to a APC Sport
8x8 propeller and controlled by a
Castle Creations Phoenix Edge 50
controller.
For Power storage, there are a
pair of Blue Robotics 14.8 V, 18
Ah (total of 532 watt-hours)
The vehicle can communicate via
a Rockblock 9603 satellite
modem.
The navigation system employs a
Arduino ESP32 auto pilot running
code developed by blue Trail
engineering. Other electronics
include a Pololu MinIMU-9 v6 for
attitude and heading, Adafruit
Mini GPS PA1010D for
positioning,
EagleTree RPM
Sensor for
motor RPM
…. And under the water
Propeller and
weighted keel
Electronics
and battery
enclosure in
the hull
Propeller and keel damaged
by a marine predator
32
SeaTrac has collaborated with
JASCO Applied Sciences to
deploy an advanced Passive
Acoustic Monitoring (PAM)
system aboard its SP-48 USV.
Equipped with acoustic
technology, a collapsible
directional array and heave-
compensating winch, the system
successfully detected several
endangered North Atlantic Right
Whales during trials conducted
off the coasts of Massachusetts
and Rhode Island.
The SP-48 is a persistent
Uncrewed Surface Vehicle (USV)
used to efficiently, safely and cost
effectively perform real-time data
collection and communications in
all marine environments.
It has a length of 4.8m(15.7ft
and a width of 139cm (4.6 ft). It
weighs 275kg (606 lb) and can
carry a payload of 70kg (154lb) ,
which can be fed power up to
500W. The solar cells feed into a
6.75KWh battery. This gives the
vessel a 5 kts top speed.
PAM
Traditional PAM systems rely on
towed arrays, which require
continuous vehicle movement and
limit deployment duration.
This new innovative approach
replaces the towed array with a
dipping, collapsible array that
supports “sprint and drift”
operations, enabling the USV to
collect data while stationary. This
method significantly reduces
energy consumption, allowing for
extended deployments and
broader coverage.
Between December 14, 2024, and
April 7, 2025, four field trials were
conducted in various sea states
and locations. These tests
confirmed the system’s ability to
operate reliably and autonomously
in challenging conditions while
consistently delivering high-quality
acoustic data.
SeaTrac custom-designed its solar-
powered SP-48 USV with a deep
keel to enhance stability and to
provide precise support for
JASCO’s specialised equipment.
Its 48V battery powered
JASCO’s heave-compensating
winch which was controlled by
an onboard single-board
computer (SBC) to deploy and
retrieve the collapsible acoustic
array.
JASCO’s array features a unique
collapsible design with four
adjustable arms and a fabric
damper to minimise motion
interference. When lowered, the
array unfolds into a compact
spatial configuration that
captures high-quality acoustic
data, which is streamed in real-
time to the SBC.
At the system’s core is
JASCO’s OceanObserver. Data
is processed by JASCO’s
StreamRepeater and PAMlab-
INT software packages.
Processed marine mammal
detections, ambient sound
reports, and operational
summaries are sent to JASCO’s
shore-based software for
continuous monitoring and
reporting via Iridium Certus and
Starlink satellite
communication.
The real-time reporting
capability of this USV-based
system offers a significant
advantage over traditional
gliders which require surface
events to transmit data.
The continuous connectivity of
SeaTrac’s SP-48 allows users to
remotely download data,
reconfigure detectors, and
troubleshoot the system via a
Secure Shell (SSH) 24/7.
SEATRAC
SOLAR-POWERED USVS
SeaTrac USV
33
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34
SOLAR-POWERED USVS
Open Ocean Robotics was recently
chosen to lead the $3.8 million Air Sea
Ocean Monitoring System (ASOMS).
The project brings together a group of
Canadian ocean tech companies to
improve observation and
understanding the ocean.
ASOMS will combine uncrewed boats
and aerial vehicles with smart sensors
and clean energy systems. The goal is
to create a long-lasting, low-impact way
to monitor the ocean, useful for
everything from overseeing marine
protected areas and offshore energy
sites, to improving coastal safety and
awareness.
This project is part of Canada’s Ocean
Supercluster’s Ambition 2035 plan to
grow the ocean economy.
DATAXPLORER
OpenOcean’s DataXplorer USV is
designed for persistent marine
monitoring. It can deliver real-time,
high-resolution data across diverse
ocean environments, from coastal
waters to the open sea.
Based on a composite fibreglass hull, it
has a length of 3.7m, a 0.9m beam and
the overall height is 1.8m or 1.3m above
the waterline.
One perennial problem with any
autonomous vehicle is that if it capsizes,
OPENOCEAN ROBOT
35
it can be very difficult to right itself.
Many vehicles solve this problem by
having a deep keel often lying a metre
or two below bottom of the hull, well
below the hull’s centre of buoyancy.
The DataXplorer, however, uses a
patented self-righting system. While it
does have a keel, it is much smaller
than many other vessels , providing it
with a draft of only 0.5m making the
vessel very useful in shallow waters.
The solar panels generate 348W of
energy and these feed 3.5kWh lithium
ion batteries (expandable up to 17.5
kWh). In total, the weight is 143 kg or
204 kg with max battery capacity.
Propulsion is provided by a 1.1KW
electric motor to give a cruising speed
of 2kts and a maximum speed of 6kts.
In total, it has a range of 100nm at
cruising speed without additional solar
input (500 nm with max optional
batteries).
A key feature of the vessel is its large
payload of up to 50 kgs or 43lit.
“The DataXplorer is equipped with AI-
powered detection systems that use
custom algorithms to identify non-AIS
vessels and track objects on the ocean
surface, said Julie Angus, CEP and Co-
Founder.
TICS
36
PROTECT
Another DataXplorer model, the Protect, adds
additional sensors and for such things as
increased maritime domain awareness, asset
security and illegal fishing enforcement. With
multiple thermal cameras and covert
colouring, it allows day and night time
operations in sensitive areas.
Add-on Sensors include a thermal camera
(LWIR) and towed passive acoustic array and
processing.
ENVIRO
Lastly, the DataXplorer Enviro has additional
oceanographic and environmental sensors
that can be customised for seafloor mapping,
metocean data collection and marine
mammal monitoring. It can also include a a
profiling winch, underwater cameras, or towed
sensors, it addresses a range of environmental
needs.
Add-on devices include sensors for
temperature, salinity, dissolved oxygen,
chlorophyll A, pCO2, FDOM and turbidity. It
can accommodate a towed passive acoustic
array, multibeam sonar and ADCP.
“Al-powered signal processing
also classifies underwater sounds
in real-time.Called ‘Enhanced
Horizon and Underwater
Listener’, these technologies
provide advanced real-time
insights, while the XplorerView
secure cloud platform enables
real-time data access and mission
control—making it one of the
most sophisticated tools for
ocean intelligence and
monitoring.”
BASE CASE
The base case DataXplorer is
configured to measures weather
conditions, ocean currents, water
depth and water temperature. It
an also scan the horizon with its
360-degree camera and AIS
transponder.
Its core sensors cal also measure
wind speed and direction, air
temp and pressure, and it has a
single beam sonar.
DataXplorer
SOLAR-POWERED USVS
37
Seasats has released Lightfish Security, a
turnkey autonomous surface vehicle (ASV)
designed to support persistent intelligence,
surveillance and reconnaissance (ISR) missions
in littoral, harbour, and open-ocean
environments.
The platform addresses critical operational
needs in maritime domain awareness (MDA),
port and coastal security, and remote
infrastructure monitoring — whether tracking
illegal fishing activity, trafficking operations, or
other emerging threats.
The Lightfish is 11.4ft (3.5m) in length by 1m
(3.4ft) wide and can be launched and recovered
in less ten minutes with man-portable
components. It weighs 367lb (166 kg)n and
therefore, no shipboard crane or davit is
required. It has a composite hull with
retractable keel for storage.
The vessel has a range of over 6000 nautical
miles, cruising at a speed of 2kts (max 4.5 kts). It
is operational up to Sea State 6 and fully self
righting. Power is generated by a Torqueedo
1103 electric drive.
The Lightship receives power from a 415W solar
collector and this is fed to a 4.0 kWh lithium-ion
battery. There is also a built-in supplemental
methanol fuel cell which provides 100 W of
boost power on demand.
For communications, it has a Starlink, Iridium
Cetus and cellular system with optional MANET
radio. For navigation and sensing, it has 5x
onboard HD cameras, GNSS/GPS, IMU,
compass, 2D LiDAR, AIS send/receive, tricolour
navigation light. There is also a collision
avoidance automated AlS sense and avoid plus
LiDAR object detection.
The sensor package can include Marine
radar, HD and thermal cameras, AIS broadcast/
receive, LiDAR
“ The Lightfish Security is engineered for multi-
month endurance and rapid field deployment,”
said Seasats CEO Declan Kerwin. Leveraging a
low-profile, the vessel can operate for many
months continuously, tracking vessels many
miles away without being seen itself.
SEASATS
38
ECHO BLUE
SOLAR-POWERED USVS
EchoBlue is a floating, non-intrusive
and eco-responsible marine drone
designed for acoustic and visual
monitoring of dolphins, particularly
in fishing areas where interactions
between cetaceans and human
activities can pose risks. It is a
hybrid object, at the crossroads of
design, science, and marine
conservation, which meets a
concrete need – to make visible
and measurable an often-ignored
reality– that of interactions between
cetaceans and industrial fishing.
A BIO-INSPIRED DESIGN
APPROACH
The drone's shape is part of a
biomorphic approach. Its fluid lines,
compact dimensions and dorsal fin
directly evoke the silhouette of a
dolphin, facilitating its integration
into the marine environment while
optimising its hydrodynamics.
Its surface is covered with a layer of
soft silicone that replicates the
texture of dolphin skin using
biomimicry. This discreet and
environmentally friendly coating
reduces visual and acoustic
disturbances in the marine
ecosystem.
A DISCREET AND AUTONOMOUS
DEVICE:
The drone flies along the water's
surface following a pre-
programmed route. At certain key
points, it stops to record sounds
emitted by the hydrophone down
to a depth of 15m. A surface
camera and an underwater camera
complete the visual data collection.
The system operates using solar
panels, emitting no noise or direct
interaction with wildlife.
The EchoBlue
developer
Célia
Granjeaud
39
A UNIQUE AND SCALABLE
INNOVATION:
To date, no other autonomous floating
device integrates a hydrophone that
descends to a depth of 15m into such a
compact bio-inspired structure. It is a
unique solution that is mobile,
environmentally friendly, and
accessible. It allows for close proximity
to cetaceans without disturbing them,
while generating valuable data for
research and biodiversity preservation.
This project embodies a strong desire:
to reconcile design, technology, and
ethics, to promote better coexistence
between humans and the marine
environment.
Currently, EchoBlue is a first functional
prototype, used in manual mode. It
already collects acoustic and visual
data on the surface and underwater
thanks to its onboard sensors.
In the near future, the goal is to make it
fully autonomous: programmed
navigation, stops at listening points,
automatic sensor deployment, real-
time data transmission, etc, while
maintaining a minimal ecological
footprint.
Dimensions:
99 cm long
Onboard systems: Hydrophone (15m long),
surface camera
underwater camera
Power supply:
Solar panels integrated
into the surface. These recharge the internal
batteries, extending the vehicle's autonomy
during multi-day sea missions.
Project History: EchoBlue was designed as
part of a design graduation project, with the
aim of combining technological innovation,
conservation, and sustainable design. The
design process was carried out in
collaboration with marine experts and field
users. The project adopts a participatory
approach, soliciting feedback from biologists,
fishermen, engineers and citizens to improve
its functionality and relevance.
EchoBlue is currently supported by two
sponsors: ROV Expert, a company specialising
in underwater exploration and robotics, which
donated electronic components, and One
Ocean, an initiative committed to ocean
conservation, which is supporting the project
by offering me the opportunity to conduct
tests in the open sea with cetaceans.
Applications and potential:
EchoBlue can be used by many stakeholders:
Scientists:
Non-intrusive
observation of marine
wildlife
Authorities/NGOs: Passive monitoring of
sensitive areas
Educational:
Awareness-raising and
environmental education
“In the long term, the device could contribute
to acoustic mapping, noise pollution analysis,
and the active protection of marine
biodiversity, said developer Célia Granjeaud.
“EchoBlue is not just a technical object: it is a
living, evolving platform, deeply rooted in a
responsible and committed design
approach.”
40
This solar-powered autonomous
USV was designed entirely from
the ground up with autonomy,
efficiency, and versatility in mind.
Measuring just under 2 meters
SOLAR S
(199 cm) in length, it complies
with Transport Canada’s under-2m
regulation for uncrewed vessels—
compared to the more common
2.4-meter threshold in many other
countries.
Its self-righting hull can be
configured as either a trimaran or
monohull, depending on mission
requirements.
The trimaran setup supports a
41
ENTINEL
200-watt solar array, ideal for
running power-intensive sensors
and payloads. The monohull
version offers a more compact
profile and accommodates a 100-
watt solar array.
Despite its compact footprint, the
vessel is exceptionally efficient. It
consumes less than 5 watts to
cruise steadily at 2 knots (≈4
km/h), and reaches a top speed
of 4 knots on just 120 watts. At its
core is a custom immersible
motor with ultra-low KV for
direct-drive efficiency,
corrosion-resistant ceramic
bearings, and a vacuum-potted
stator and rotor to ensure long-
42
43
term durability in saltwater
environments.
For communications, the boat
comes equipped with LTE and
Iridium Short Burst Data (SBD)
as standard, with an optional
upgrade path to Starlink. A
future update will enable
direct-to-cell Starlink
operation, providing seamless
nearshore and offshore
connectivity via a single
modem.
The platform is designed for
accessibility and
customisation—whether for
researchers, educators, or
government users. It runs
open-source ArduPilot
software, supported by a
Raspberry Pi Compute
Module 4 (CM4) companion
computer.
All platform software will be
made open-source, allowing
full integration of third-party
sensors, mission logic, and
automation workflows.
Initial sea trials are underway,
with the first production run
launching shortly. This solar
USV is purpose-built for clear-
sky environments, ideal for
long-duration missions where
solar availability is high. It
complements our wind-
powered sailing USVs, which
excel in cloudy or winter
conditions
Trimaran version with solar
panels included
44
Royal IHC has recently delivered a
new version of Its successful "Hi-
Traq" subsea trenching vehicle
range, the "Amphibious Hi-Traq
Jetter" to Caldwell Marine
International (CMI). This newbuild
subsea vehicle is the first of its
type and will be owned and
operated by the specialist US
cable installation contractor,
becoming a key tool in its
extensive arsenal of equipment.
The scope of this contract award
included the Jetting vehicle with
eductor system, combined power
and control cabin complete with
latest SCADA system, power/
control umbilical and a special
purpose umbilical reeling system.
AMPHIBIOUS HI-
“The evolution of the design of
the Hi-Traq Jetter can be traced
right back to the i-Trencher,
currently owned and operated by
Helix,” said Robert Haylock,
Business Development Manager,
Subsea Technologies. “Delivered
in 2009, i-Trencher is still
operating successfully today and
has an unrivalled track record of
installing subsea power cables
worldwide.
“Post delivery of the i-Trencher,
Royal IHC invested millions of
pounds into R&D to discover if
subsea tracked trenching vehicles
of the time could be
fundamentally improved upon.
That process identified two key
problems: firstly traction related
Issues caused by the
exclusive use of the
classic ridged two-
track system.
Secondly was the potential loss of
vehicle control whilst cresting large
undulations In sea
beds such as sand
waves.
“It is logical to
assume that when
encountering a
completely flat,
relatively firm sea
bed, a two- track
vehicle generates
excellent traction,
but how often in
the real world Is
that the case?
More likely, sea
bed conditions
can be more problematic, with soft
soils, steep slopes or challenging
undulations.
In those circumstances a
traditional two
tracked system
Amphibious
Hi-Traq Jetter
Two tracks per side
makes the vehicle
more manoeuvrable
than a single track
TRENCHERS
45
-TRAQ JETTER
Hi Traq 1600
will experience challenges
maintaining traction. For example
in an undulating sea bed scenario,
where a track spans two sand
wave peaks, track contact Is lost
between these peaks leading to a
significant reduction In available
traction.
This loss of traction can lead to
slow progress for the vehicle and
at worst lead to a requirement for
vIntervention and recovery. Where
the vehicle Is peaking the crest of
a large sand wave, a two tracked
system can experience a total
momentary loss of control as it
pivots from the upward to the
downward faces. This loss of
control poses a serious threat to
the Integrity of the cable and to
the vehicle Itself".
“Many cable burial operations
take place in notoriously harsh
shallow water environments that
have high wind and wave
energies that lead to undulating
sea beds.
Traditional two track
technologies may struggle with
such demanding conditions,
leading to a risk of project
delays, Inadequate burial
performance and ultimately,
increased costs for the
contractor".
Demonstrator vehicle Tackling
these potential risks is where the
idea of a four-track vehicle with a
self-levelling capability
originated. Such a platform
would maximise traction and
enable a constant trench depth
to be maintained independent o
the seabed topography over
which the vehicle is manoeuvring.
“The constant ground contact
delivered by the four-track
system offers the best possible
traction performance, resulting in
consistent and higher speed
trenching rates through arduous
topography and soil conditions.
In combination, the patented
self- levelling system maintains a
vertical, flat-bottomed trench,
significantly reducing the risk of
point loading the product.”
Royal IHC developed a
demonstration vehicle to
successfully test and prove the
benefits of a four-track system.
46
Hi-Traq Jetter during trials
This demonstrator vehicle can still be viewed
today at their facility at the Port Of Blyth in the
North East of England.
The next phase in the development was to
produce In- house a full-scale, workable vehicle.
That vehicle was to become the Hi-Traq 1600,
which is now owned and operated worldwide by
Aratellus under the name “Leviathan” (see
separate story).
Although focused on power cable burial the Hi-
Traq 1600 is also capable of trenching a wide
range of products including umbilicals, flexibles
and ridged pipelines for the offshore Oil & Gas
market.
The High-Track 1600 featured multiple
capabilities such as jetting and cutting.
Generally, the cutting process benefits from a
significant amount of vehicle weight and as
such, the trencher was designed to weigh-In at
around 70t.
Jetting however, does not require as much
vehicle weight so when Royal IHC saw a market
requirement for an advanced, jetting-specific
tracked vehicle, their specialist Subsea
Technologies team undertook the development
of a new, smaller, lighter vehicle, which
ultimately became the Hi-Traq Jetter.
“The Hi-Traq Jetter is no less capable as a
jetting vehicle than its larger ‘predecessor,” said
Haylock,“ and still uses the patented field
proven self- levelling four-track concept, but it is
considerably lighter at around 20–25t.
47
Demonstrator vehicle
48
”This resonated with New-Jersey-
based Caldwell Marine International
(CMI), a company focused, amongst
many activities, on the shallow water
aspects of windfarm cable
installation.”
CMI had considerable experience
using surface-supplied jet sleds, but
were keen to embrace the
advantages offered by a tracked
subsea vehicle, especially one that
was crane launchable and "surface-
supplied" with Its jetting pumps
installed topsides on the support
vessel – an arrangement they were
very familiar with. A keynote is its
modularity
“A key USP of the Hi-Traq Jetter
range is that there are two main
variants: the surface-supplied
amphibious Hi-Traq Jetter and the
deep-water Hi-Traq Jetter,” said
Haylock.
“Whilst being completely
independent vehicles, they are
almost identical, sharing a vast
amount of design features and
components. Whereas the
Amphibious Jetter can operate from
the beach down to around 80m, the
deep-water version includes all of
the subsea pumps, HPUs, etc, to
operate in deeper waters.
“It effectively takes over where the
amphibious vehicle leaves off and
can operate down to around 2000m
water depth.
“Between the forward and aft
levelling system of each vehicle is a
core central chassis. This chassis is
simply pinned Into place, meaning
that should a customer require both
TRENCHERS
Amphibious Hi-Traq Jetter
49
the shallow-water and deep-water
capabilities, they have the option of
simply buying one vehicle but two
central chassis.
“Doing so comes with significant
advantages, both In terms of cost
and operations. Going from shallow
to deep water project phases, an
operator will simply unpin the
central chassis, remove the shallow-
water section, and pin Into place
the deep-water chassis.
“Of course, some additional
equipment such as a power cabin
and umbilical would be required for
the deep water Hi- Traq Jetter, but
ultimately, a very significant
proportion of the vehicle can be
used for both applications which is
one of the major advantages of the
Hi-Traq Jetter vehicle”
Serious consideration has also been
given to storage and
transportation.
“By disengaging the simple pin
connections, it Is designed to be
broken down into standard sized
shipping containers, making it
easier and less costly to store and
to mobilise to site, wherever that
may be around the globe.The
Industry feedback we are receiving
is extremely positive.”
The USA looks like a growing
market for the jetter. US East Coast
wind farm developments are driving
demand for innovative subsea
trenching solutions.
The industry there is evolving
rapidly, and operators are looking
for tools which are cutting-edge,
cost effective, reliable and practical.
50
Simultaneous lay and trench with a typical power
cable plough has been the typical cable lay
approach for most buried telecommunications
cable and now subsea power cables, mainly export
cables. This , however, could be a less practical
option when compared to pre-trenching. So says
Lee Screaton of S&A Associates.
“Simultaneous lay and trench is the process of
cable lay whereby the cable is laid into a subsea
cable plough that immediately buries the cable
into the seabed as it is towed behind the cable lay
vessel,” he said
“The problem with this method is that power
cables have a far larger diameter than telecoms
cables with a minimum bend radius (MBR) of
between 4m and 5m. Furthermore, power cables
are arguably more fragile than telecoms cables
due to the combination of large diameter, high
density and construction elements such as the
‘paper’ insulation layer.”
There are numerous advantages of simultaneous
lay and trench.
●
The cable is immediately trenched so
unlikely to be damaged as it waits for trenching
●
The whole lay and trench operation occurs
from one vessel
These advantages were, and still are, great for
tele-communications cables but they don’t
translate as well to the power cable installation
operation.
When viewed from the power cable installation
perspective, however the disadvantages are:
●
Power cable ploughs are larger than
telecommunications ploughs due to the far larger
MBR and usually need 150Te of bollard pull (for
2m+ trenching) making for a more powerful cable
lay vessel or dual vessel laying with an offshore tug
in tandem with the cable lay vessel
●
The standard approach of loading cable
into the plough on the vessel and launching with
the cable through the plough is less desirable as the
launching process can damage the cable outer
serving layer
●
It can be difficult to perform some
ploughing operations, such as changing heading, as
the overboard tension of a power cable should be
lower than telecoms cable due to concerns over the
fragility of the cable.
This can lead to issues such as not being able to lay
power cable directly into the bellmouth of the
plough
●
The back deck of a power cable lay vessel
can be congested and multi-role when compared to
a telecoms lay vessel so it isn’t easy to find space for
the power cable plough. This can lead to additional
systems such as movable mezzanine decks, etc.
Various approaches have been developed to offset
the plough related problems such as subsea loading
using grabs or ‘top loading’ techniques which avoid
the launching issues but they are not common and
have their own problems.
Is the answer to shift the emphasis to pre-trenching
instead?
In the context of this article, the term “pre-
trenching” is intended to imply the use of a plough
that creates a V shaped trench in the seabed that the
cable lay vessel lays the power cable into as a
separate process.
Practically, what this means is a pre-trenching plough
is deployed from a plough support vessel, not the
cable lay vessel, to cut the trench in the seabed.
After the trench is cut, the cable lay vessel lays
LAY AND TRENCH V PRE TRE
TRENCHERS
Fig1: Typical Simultaneous
Lay and Burial Operation
51
NCHING
power cable into the pre-cut trench.
Once the power cable has been laid into the trench,
the same plough is reconfigured for backfill and is
deployed again from the plough support vessel to
backfill the trench thereby covering the power cable.
This same plough could also be used for route
clearing ahead of the pre-trenching however that
depends on whether there are boulders or other
obstructions on the cable lay route.
S&A have produced a generic Standard Operating
Procedure (SOP) storyboard drawing that outlines
how pre-trenching can be approached.
The advantages of this pre-trenching approach are
●
The trenching, which is notoriously slow, can
be completed by an operationally cheaper vessel
than the lay vessel. Typically, a plough support vessel
is an offshore tug with only the ships crew and
plough team
●
The trenching can be performed off the
critical path of the project, for example when the
cable lay vessel is loading cable or deployed
elsewhere
●
The lay vessel can be a significantly less
expensive vessel in that it could be a basic lay barge
with anchors for propulsion or basic dynamic
positioning (DP)
●
The lay vessel aft deck can be optimised for
cable lay instead of requiring space for the plough,
tow cable, umbilical/ umbilical winch, LARS, etc.
●
If the trench is required to be deep or
problems are encountered during the pre-trenching
operation, the plough support vessel can perform
multiple passes until the trench is as required. The
same applies to complex cable routes that feature
direction changes that can be problematic when
installing large power cable running through a
standard power cable plough
●
The issue of MBR and damage to the cable
is effectively eliminated as the cable does not pass
through the plough
There is an obvious disadvantage to pre-trenching
in that the trench may infill while it waits for the lay
vessel or the cable, once laid into the trench, is
effectively unprotected until the backfill operation
completes. But with appropriate organisation of the
vessel availability it is believed that these periods
can be mitigated against.
It is also worth noting the increase in reports of
damaged power cable that is believed to have
occurred during installation.
“With the activity in the Far East and USA there is a
push for reducing costs and implementing "lessons
learned" from the European installation
experience,” said Screaton. “There is a lot of
newbuild activity but is bigger, more powerful, more
expensive, etc. the way to go?
“Perhaps pre-trenching could prove to be the more
cost effective, cable friendly and practical approach
for future export power cable installation?”
Figure 4: Backfilling
the trench
Figure 3: Laying
into the trench
Figure 2: Creating
the trench
52
LEVIATHAN
TRENCHERS
Aratellus’ Innovative 4-track
Trencher ‘Leviathan’ has
returned to the UK after a
number of years in Taiwan and
Northwest Africa on various
projects.
“Leviathan has been deployed
away from our Blyth base for
several years, engaged in a
series of consecutive projects.
The 4-Track arrangement came
into its own in Taiwan on an
inter-array trenching campaign
where the site had many large
sand waves along the cable
routes. Leviathan has the ability
to traverse sand waves and self-
level on side slopes as well as
manage crests with its
independent suspension,
without the shearing and
tipping effect 2-Track systems
typically encounter.
As a result of Leviathan’s
capabilities, the client was able
to eliminate the need for a pre-
sweeping campaign, achieving
significant cost savings whilst
maintaining cable integrity. “
Said Jamie Linton, Project
Director for Aratellus.
“It’s great to be able to
demonstrate the effectiveness
of the 4-track design and the
positive impact it can have in
these challenging conditions”
said Linton.
Leviathan is a 1600 horsepower
Trencher with the capability to
both jet trench and perform
chain cutting in a wide range of
conditions.
Leviathan
53
Underwater technology and services
company SMD is celebrating a significant
milestone with the sale of its 100th plough.
The Plough M has been purchased by
Global Marine, a market leader in subsea
cable installation and maintenance, to
support its worldwide operations.
The sale is the latest in a series of
collaborations between the two
companies. Over the last 30 years, SMD
and Global Marine have partnered on 27
projects, and countless more equipment
upgrades and refurbishments, delivering
innovative technology that continues to
shape the future of offshore engineering.
Plough M has successfully completed sea
trials and has now been deployed on its
first commercial mission.
“Plough M represents the latest evolution
of our plough technology, blending
decades of experience with future-focused
solutions. It has been designed for
maximum plough stability with minimum
cable handling, delivering a true 2m burial
depth for ultimate cable protection.
Thanks to a low-friction share design, this
vehicle also consumes minimal fuel to
ensure efficient and economical
operations, said Adam Batsford, Key
Account Manager at SMD
The plough is designed to work in soft
mud with the minimum capacity of 5kPa.
It has a length of 9.1 m, a width of 5.1 m
and stands 4.4 m high. It has a depth
rating of up to 2000m.
With a chassis of high strength steel, it
weighs 22 tons in air or 19 tons
submerged white. It can be used to trench
cables with a maximum diameter of 160
mm and a maximum cable bend radius of
1.5 m. The maximum repeated distance is
380 mm.
Plough M
Its trenching system employs a pair of passive
narrow parallel sided shares with repeater burial
flaps to temporarily widen trench. It has two of
265kW water jets as required.
The plough has installed hydraulic power of 15KW
and a comprehensive instrumentation package,
including cameras, on panel and tilt units, lamps
and sonar.
It is installed from a 30 ton A-frame handling
system which lowers the plough on a single wire.
The winch is rated at 64 tons to render and 35 tons
to lift. There is an optional front jet tool for specific
soul conditions, and aggressive share tip for
operations in underground.
100TH PLOUGH
54
JET-IT
TRENCHERS
Van Oord has added a third trencher
to its fleet with the Jet-It. This new
1300kW jet trencher has completed a
successful test campaign in the North
Sea and is now working on its first
project.
With its 1300kW installed power, Jet-lt
can efficiently bury inter-array and
export cables in sandy and light clay
substrates down to a depth of 3m.
This vehicle builds on the expertise
gained from the company's two other
units, the Dig-It and Deep Dig-It. While
these have mechanical cutting and
jetting technology, the Jet-lt uses only
jetting technology.
Drawing on the expertise gained over
the years and continuous
improvements, Jet-lt has a really high
jetting efficiency, requires less power,
less fuel and less maintenance.
The trencher is 12.8m long and has a
width of 6.7m. It stands 3.5m high and
weighs 28.5tonnes in air. Its operating
depth is 2 to 200m. It travels across the
seabed on a pair of caterpillar tracks
driven by 30kW hydraulic motors and it
is equipped with two thrusters for
orientation.
The Jet-lt is equipped with two sets of
jetting swords for cable burial at 2m
and at 3m. The two jetting swords and
the aft cable sensor can be deployed
independently. The width between the
swords is remotely adjustable from 450
to 950mm.
Those two independent jetting swords
inject into the seabed water supplied
from the two high pressure, three
JET-IT
55
stage, 18-in water pumps. Each pump
is driven by a 550kW e-motor and can
supply between 550 m3 at 15.5 bar and
1050 m3 at 13 bar depending on the
nozzle configuration.
As the first in the industry to use this
technique, Van Oord has equipped its
jetting tools with a unique combination
of sensors that can precisely monitor
the depth of the cable, control the load
applied on the product andconfirm the
depth of burial directly during the
burial process.
This enhanced cable monitoring
system enables a greater control and
higher burial speeds.
Survey equipment includes seven
cameras, eight lights and three imaging
sonars, as well as obstacle avoidance
and a protiling sonar. It also has four
bea
cons and a cable tracker.
The Jet-lt spread includes the Launch
And Recovery System (LARS)
composed of an A-frame and an
umbilical winch, its control cabin, the
power cabin with the frequency drives,
a dedicated data cabin with the survey
equipment and IT environment.
The whole spread is permanently
installed and connected on a
dedicated 18 x18m plattorm. This
strong integration of all the
components allows mobilisation on any
vessel in a single lift, making the
preparation more efficient, reducing
the mobilisation time and cost. The 30t
LARS enables launch and recovery up
to sea state 5.
56
Earlier this year, NKT completed the
ceremonial keel laying for its cable-laying
vessel NKT Eleonora that can lay heavier and
longer-length power cables. This was
designed to meet the high demand for high-
voltage power cables needed for renewable
energy.
As a natural progression, NKT is now also
investing in enhanced cable protection
technology with the construction of the
world’s most powerful subsea trencher,
delivering 3,600 horsepower to bury cables to
depths of up to 5.5m below the seabed.
This investment further strengthens NKT’s
complete cable solutions for installing power
cables at deeper depths with minimal
risk.
“Protecting power cables is more important
than ever due to the increased risk of
sabotage and high activity at sea,” said
Darren Fennell, Executive Vice President and
Head of HV Solutions at NKT.
“This trencher will be best in class, ensuring
reliable deep-burial protection of power
cables in even the most challenging soil
conditions.
The company has contracted OSBIT to design
and construct the trencher, as well as the
Launch & Recovery System.
Power:
3,600HP
Capability:
Burial depths of up to 5.5 m
below the seabed
Functionality: Equipped with both a jetting
and cutting function, allowing
it to operate in a wide range
of soil conditions
Timeline:
The trencher is expected to
be commercially operational
by 2027
NKT T3600
WORLDS MOST POWERFUL SUBSEA TRENCHER
TRENCHERS
57
58
Smart
Subsea
Solutions
• intelligent vehicles
• reliable communication
• accurate positioning
• modern sensor networks
• diver navigation systems
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