The Crawler and iCrawlerThe mobile deep sea (real-time) monitoring platforms

Environmental conditions in the marine environment can vary

greatly, both spatially and temporally.

By using mobile research platforms with internet connectivity, suchvariability can be investigatedand monitored in real-time.

In this brochure we present an overview of a new product in this market, the Deep Sea Crawler.

Developed for deep sea research, this modular vehicle can be

tailored by our skilled technicians to best meet your research or

monitoring requirements.

The iCrawler, a fully autonomous version for environmental

monitoring will be available by 2015

Table of Contents

The Deep Sea Crawler Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . 2-3

Deployment Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-5

Standard Components . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-7

Development of the Crawler . . . . . . . . . . . . . . . . . . . . . . . 8-9

Upgrades and Services . . . . . . . . . . . . . . . . . 10-11

The iCrawler . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12-13

For more information contact:Laurenz Thomsen

Professor of GeosciencesJacobs University

D-28759 Bremen, GermanyEmail: l.thomsen@jacobs-university.de

Telephone: +49 421 200-3254

(All images within this brocure copyright NEPTUNE Canada or Jacobs University Bremen)

A reliable presence on the ocean floor for months at a time.

Deep Sea Crawler

Acquire data, perform experiments, survey installations, all at a fraction of the cost of traditional methods… without leaving your office.

The Crawler is a fully customizable tool for deep-sea data collection. An IOV (Internet operated vehicle), the Crawler is compatible with a large range of equipment, and can be adapted to your particular needs. An overview of the technical specifications of the Crawler as a science platform are published in the journal `Methods in Oceanography`- downloadable here: http://tinyurl.com/kwnxpum

Science data collected by the Crawler was used in a recent science publication on carbon transport published in `Geophysical Research Letters` - downloadable here: http://tinyurl.com/n0068dm

The Crawler provides long-term data

Uninterrupted deployments of several months give you a permanent record of the sea-floor, be it oceanographic data, environmental monitoring, or a status check of your deep-sea installations.

The Crawler collects hard-to-access data

The surface conditions might prevent traditional deployment of equipment, but the Crawler will keep collecting data under the roughest weather.

The Crawler gives you full control

Users can drive the Crawler to a new location, perform experiments or visual observations, all in real time, from anywhere in the world.

Capabilities

Deep-sea Current ProfilingSeep Detection Oceanographic ResearchLong Term Environmental MonitoringLong Term Industrial Monitoring

Advantages

Operates at depths up to 6000 metersPerforms missions up to one year in duration

Controllable from anywhere in the world via Internet access

Enables continuous monitoring and analysisAccommodates multiple sensors simultaneously

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Dimensions and Weight

Dimensions: L 1290 x H 890 x W 1060 mmWeight in air: 355 kgWeight in saltwater: 40 kgPayload: 120 kg

Frame and Buoyancy Elements

The frame construction of the Crawler is made of titanium corner profiles grade 5. Together with its plastic parts (POM) for the camera frame and the other connecting parts this makes the Crawler completely corrosion resistant and allows long term operations in seawater.

The buoyancy elements consist of syntactical foam (glass microbubbles enclosed in epoxy resin).

Electronic Components

Two functional units are the main electronic components of the Crawler: the Track Controller and the Port Manager. Both are mounted in separate titanium pressure casings.

The pressure housings are secured against inner overpressure.

Track Units

The Crawler moves on two tracks driven by transport wheels running on titanium axles. Depending on the seabed of the operation area different track profiles can be supplied.

The two driving units include a motor and an angular gear. Motor and gear are enclosed in a hydrostatically compensated housing.

3

Typical Deep Sea Crawler deployment:

70 m buoyant cable connecting vehicle with internet and power supply hub

Operations:

The control interface allows very precise positioning of the vehicle, cameras and

sensors in areas of great seabed complexity

4

In deployment basket below ROV

As an important research tool on the NEPTUNE Canada cabled ocean observatory system, the Deep Sea Crawler is used to investigate a cold-seep site at 800 m depth.

The stable tracked design

allows positioning even on high gradient areas

of seafloor,as pictured here.

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Sta

ndar

d c

ompon

ents Track unit:

Tracks (Plastic)Transport wheels (Plastic)Axles (Titanium)BLDC motor (600W) Angular gearSubconn ConnectorsPressure compensated housing (Plastic)

Optional equipment:

Umbilical-Copper (up to 70m)Umbilical-Optic fiber (up to 1000m)Laser sizerBenthic chamberMechanical arm for sediment profiling

Standard sensor package:

CTD

Optional:

ADCPMethaneFluorometerOptical backscatterCO2O2pHSonarHydrophone

Track controller: Micro Computer (OS: Linux)Motor control (CAN bus)Network switch (100Mbit)Subconn ConnectorsPressure housing (Titanium) 6000 mClamps (Plastic)

Crawler chassis:

Camera mount2 chain drive units (Kevlar) Main frame (Titanium)Float 6000 m(Syntactic Foam)

Port manager:

Network switch (100Mbit)Protocol converter (RS232-TCP/IP)

Subconn ConnectorsPressure housing (Titanium) 6000 mClamps (Plastic)

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Additional sensors:

The Crawler is a universal device carrier for a wide variety of sensors. The protocol converter of the Cra-wler allows the adaptation of (usually) serial sensor interfaces to the TCP/IP network (Ethernet).

This not only allows the integration of all sensors into the network but also their manipulation.

Front camera: Pan-tilt camera (Panasonic BB-HCM580CE Pan / Tilt IP CAM, programmable as a photo camera)Subconn ConnectorsPressure housing (Polished pressure resistant glass sphere) 6000 m

Mounting ring (plastic)

Optional:

Rear HD camera 3D scanning camera

Compass:

Electronic CompassEthernet Interface ConverterSubconn ConnectorsPressure housing (POM) 6000m

Mounting bracket

Front lights:

Power LED (33W)Subconn ConnectorsPressure housing (Titanium, Plexi) 6000 mMounting bracket (plastic)

Optional:Back lights

Fully customizablesystem

With your purchase we offer you 20 man-hours to

freely customize the Crawler to your own demands.

Our team of engineers and our fully equipped workshop

will be at your disposal to turn the Crawler into the

platform that will best meet your needs.

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Dev

elop

men

t of

the

Cra

wle

rWhy develop Deep Sea Crawlers?

To fully understand the dynamics of a parti-cular marine environment time series data are essential.

The ongoing deployment of Lander based systems, and the repeated visits to survey stations by research vessels has produced extensive data sets from the shallows to the deep sea at particular sites. The develop-ment of satellite data transfer techniques allow such ship and Lander collected data to be available worldwide via the Internet in near real-time, though these systems are often power hungry, or for cruise data, only possible when a ship is on station.

Live data collection

For some applications, live data collection is essential or desired, even from deep sea environments. An example is the collection of seismic data for the prediction of Tsunami events. The JAMSTEC cabled system off the Japanese mainland and the NEPTUNE Canada network covering the Juan de Fuca plate off the Pacific Canadian coast are two examples of such networks capable of measuring seismic waves in real time from a number of stations on the seafloor, in some cases from stations in waters of >3km depth. Further examples would be the extant and in de-velopment deep sea Neutrino telescopes within the Mediterranean Sea. These cabled systems have been designed to supply large amounts of power and return gigabytes of data per second to a land based processing station, then to the World Wide Web, in near to real-time.

The Crawler in a deployment basket, slung below the 6000 m rated ROV `ROPOS`.

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The development of an integrated European Multidisciplinary Seafloor Observatory (EMSO) is also foreseen as is the further development of the MARS network from Monterey, USA and others in Taiwan (MACHO) and China.

The NEPTUNE Canada network was installed with more than 100 oceanographic instru-ments (including flow meters, turbidity meters, fluorometers, cameras and oxygen sensors) deployed at various nodes. The neutrino teles-copes, in addition to providing basic oceano-graphic data from a few sensor packages, have produced a swathe of bioluminescence data from the CCD chips used primarily to capture neutrino trajectory data. Both these networks have been used to produce published scientific papers with many more in preparation or peer review.

Although the real-time data delivery from the-se cabled systems allows scientists to monitor the oceanographic conditions at a target site whenever they wish to, they can only moni-tor the conditions at one or a small number of discrete locations.

In some ecosystems, such as hydrothermal areas, gas hydrate seep regions or at deep sea coral sites, oceanographic, hydrodynamic, sub-strate and faunal assemblages can vary great-ly, both temporally and spatially. To investigate such regions a mobile sensor platform would be greatly beneficial. For scientific studies, such a mobile platform, the ROVER, is in ope-ration on the Monterey Accelerated Research System (MARS) network, investigating carbon transport and soft bottom communities.

Commercial applications

Such platforms have been used commercial-ly by the oil and gas industry for inspections around drilling rigs, and for inspection of cab-les and pipelines for a number of years. These are commonly operated from a drill site or ship rather than via the Internet. To enable scien-tists and engineers worldwide to investigate and monitor dynamic ecosystems and benthic environments in real-time with such sensor platforms, Jacobs University Bremen has been designing Internet connected vehicles (IOV) for almost a decade.

In 2009 the university completed development of a Benthic Deep Sea Crawler (hereafter re-ferred to as the Crawler) capable of carrying in excess of 120 kg in sensor payload. The Craw-ler has been used extensively on the NEPTUNE Canada network.

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UpgradesYou can upgrade your Crawler’s sensor package at any time, and with minimal effort.

You can take advantage of the free 20 man-hours supplied with the purchase, or ask for our service rates.

Upgra

des

and S

ervi

ce

Mosaic showing a cold-seep vent site, produced from 70 images taken with the rear Panasonic camera, Sept 2012

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ServiceOur collaborating operations engineers and technical representatives are well trained and highly professional. We provide top-notch individuals for these positions.

We also offer an on demand service to login to your Deep Sea Crawler during deployments to advise your team directly on any operational or technical questions.

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12

The next generation: the iCrawler

There is no international consensus on how the activities of the offshore oil and gas industry should be monitored. However environmental awareness and technological advances has spurred development of new monitoring solutions for the petroleum industry. For more than 10 years now, our team of scientists and engineers have run projects with petroleum industries to develop new concepts and regulations (1,2). Cabled observatories with teleoperated sensors and robots will be increasingly deployed for the offshore industry. The cabled Statoil Lofoten observatory is a prominent example for that, but these operations are also time consuming.

Therefore we have joined forces with the German Research Center for Artificial Intelligence to create the iCrawler. The iCrawler can either be connected to a cabled observatory to carry out pre-determined autonomous operations with realtime data supply, or work in a fully autonomous mode, after deployment by ship or helicopter into surface waters. The iCrawler will sink to the seafloor and begin the monitoring process.

The first iCrawler will be operational by early 2015. The robot will follow pre-determined missions on the seafloor, create baseline maps with vi-deo-mosaics from the environment and geo-reference all incoming sensor data to create one GIS map. Each final mission-plan can also be transferred to the iCrawler via Internet-connection from an operational team on land, thus allowing maximum flexibility for the user.

Our team of experts can provide the first environmental maps and data analyses during cabled online operations or shortly after the retrieval of the iCrawler by ROV. The depth rating for the iCrawler is down to 2000/6000 m but we also offer teleoperated 100 m depth versions, which can be launched by small boats and allow real-time missions via a surface float with cellphone connection.

1) Purser A, Thomsen L (2012) Monitoring strategies for drill cutting discharge in the vicinity of cold-water coral ecosystems, Marine Pollution Bulletin 64, 2309–2316

2) Godø O R, Klungsøyr J, Meier S, Tenningen E, Purser A, Thomsen L (2014) Real time observation system for monitoring environmental impact on marine ecosystems from oil drilling operations. Marine Pollution Bulletin, Volume 84, 236-250

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Example of future monitoring operations: A baseline study will be provided with one robot 1 – 0.5 years before drilling operations, followed by detailed monitoring during the 3-6 weeks drilling process and 1 mission after the end of drilling. During exploration, 1 – 3 robots can monitor the environment and can be regularly maintained via ROVs.

A modular design allows easy

adaptation of the Deep Sea Crawler for

a range of tasks in a range of marine

ecosystems.

Please contact our professional team to

discuss how the Deep Sea Crawler may

provide a solution for your research or

monitoring requirements.

Crawler Mobile field tested platforms for realtime seafloor and water column research as well as a multipurpose tool for environmental monitoring.

This robot development was supported by Oceans Network Canada and NEPTUNE Canada, the EU ESONET program, Titanium Solutions Bremen, Statoil and the Heimholz ROBEX project