Mooring Modifications for the Reduction of Losses to Vandalism H. Paul Freitag Chris Meinig Andrew J. Shepherd Pacific Marine Environmental Laboratory.

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Presentation transcript:

Mooring Modifications for the Reduction of Losses to Vandalism H. Paul Freitag Chris Meinig Andrew J. Shepherd Pacific Marine Environmental Laboratory Seattle, Washington, USA Linda D. Stratton JISAO/University of Washington Seattle, Washington USA Technical and Scientific Workshop 23rd Session Data Buoy Cooperation Panel October 15-19, 2007 Jeju, Korea

Mooring Vandalism Outline Types of vandalism with examples. Regional distribution of vandalism Impacts on data return Modification of surface mooring hardware Modification of surface mooring design Modification of moored array Indian Ocean plans for 2008 Development of longer term solutions

Types of Vandalism Incidental fishing interaction Intentional interaction (slingshotting) Theft Malicious damage

Incidental Fishing Interaction Minor fouling of temperature sensor by longline. No impact on data. Can be hazardous to personnel.

Incidental Fishing Interaction Fouling of Doppler Current Meter with longline and float Potential impact on data quality. Damage to connector and electrical cable.

Incidental Fishing Interaction Longline completely engulfs instrument. Cuts to wire jacket can cause failure of data telemetry.

Incidental Fishing Interaction Large amounts of longline can increase drag on mooring

Incidental Fishing Interaction Fishing line can contain unexpected bi-catch.

Intentional Fishing Interaction Purse seiners slowly pull buoys several miles, setting their nets around the buoy and the fish attracted to the “FAD”. They then release the buoy and close the net. This “sling shot” method increases their catch, but can damage moorings to the point that they are separated from their anchors. Image credit: Gulf of Maine Research Institute

Intentional Fishing Interaction. Mooring drifted for 2 months before being recovered. Had hawser attached. June-July º 165ºE

Intentional Fishing Interaction. Damage to buoy and sensors can occur when large ships tie up to moorings

Theft of equipment. “Tower stripped of sensors, except tube and barometer, lots of fishing gear on bridle, plus float. Fishing gear fouled at 10m, 20m, 50m, 100m.” 0º 90ºE Mooring Recovery Log “Hi There, I believe you are wanting back an electronic tube that I have which I found drifting about 18 month ago. I am willing to give it back but need compensation – how much are you prepared to pay?” from Palmerston Atoll

Malicious Damage. All or a portion of the buoy tower may be removed, either by unbolting or cutting.

Malicious Damage Buoys have been used for target practice.

TAO Vandalism Moorings and instruments confirmed lost or damaged (through August 2007). All surface sensors: 16% lost, 5% damaged. All sensors: 10% lost. Number Deployed Number Lost Number Damaged Percent Lost Percent Damaged Moorings % 5% Wind % 5% Air Temperature % 2% Short Wave Radiation % 8% Rain % 9% Barometric Pressure % 0% Long Wave Radiation % 8% Water Temperature >5423>436 ~8%

PIRATA Vandalism Moorings and instruments confirmed lost or damaged (through August 2007). Number Deployed Number Lost Number Damaged Percent Lost Percent Damaged Moorings80465%8% Wind %8% Air Temperature808310%4% Short Wave Radiation %8% Rain %13% Barometric Pressure3000% Long Wave Radiation3000% Water Temperature>880>66~8% All surface sensors: 12% lost, 8% damaged. All sensors: 9% lost.

Indian Ocean Vandalism Moorings and instruments confirmed lost or damaged (through August 2007). Number Deployed Number Lost Number Damaged Percent Lost Percent Damaged Moorings114036%0% Wind136146%8% AT136046%0% SWR125142%8% Rain125142%8% BP31033%0% LWR21050%0% Temp modules~132~46 ~35% All surface sensors: 44% lost, 5% damaged. All sensors: 37% lost.

Major TAO Vandalism Moorings which were entirely lost, or all surface or subsurface sensors were lost. Majority of major vandalism was mainly in eastern portion of the Pacific Basin.

TAO Data Return Wind sensor is one of the most often vandalized. Pattern of data loss is consistent with pattern of vandalism. Data return for all standard sensors was 91%.

Indian Ocean Mooring Design Modifications Make sensors and equipment more difficult to remove Remove vulnerable sensors Make buoys harder to board Remove buoy attachment points Deploy more subsurface moorings

Vandal Resistant Hardware Hardware used to attached sensors and the buoy tower will require special tools.

Vandal Resistant Buoys Surface sensors and tower removed. Buoy covered with cone to inhibit boarding or attachment to buoy. SST, SSS, subsurface T and S, and velocity measurements remain and telemetered via Argos. If prototype moorings are not vandalized, new vandal resistant surface sensors could be reintroduced.

Vandal Resistant Buoys New recovery and deployment methods are required and are under development

Indian Ocean Plans Surface moorings will either have vandal resistant hardware or “conehead” design. Prototype deployments began in September New ATLAS sites to be deployed in Bay of Bengal. Expanded array along 80.5 ºE will include additional off-equatorial ATLAS surface moorings and additional subsurface ADCP moorings.

2008 Indian Ocean Plans Expanded ADCP array along 80.5 ºE will include some moorings enhanced for upper ocean T and S measurements. Two surface moorings will have vandal resistant design.

Future Mooring Design Goals Telemeter more data Reduce size/cost of mooring hardware Reduce size/cost of sensors Reduce vulnerability of sensors Reduce cost of shipping and deployment

PICO (Platform and Instrumentation for Continuous ocean Obs) Profiler Terminator Lifting eye Shipping & deployment pallet Pre-packaged and palletized “Factory-built” concept Small vessel Low Expertise Cost effective R&D Engineering

“Prawler” (Profiler + Crawler) PURPOSE: Test a simple ascender concept for climbing the mooring line: Develop an efficient magnetic ‘actuator’ Develop and test software adaptive sampling routines. Quantify ascent and decent under measured surface displacements. FIELD TRIALS: Terminal fall velocity set at.3 m/sec Successful tests in 60m local waters with manual wave input. Achieved ~85% efficiency in climbing with 1m 6sec wave input. Magnetic ratcheting pawl Inductive coms Ultra low-power CPU Sensor space R&D Engineering

“Prawler” Testing 10m tank testing Buoy and Prawler deployment R&D Engineering

Summary Damage to moorings by fishermen, either inadvertent or intentional, results in significant loss of both data and equipment. Percentage losses are especially high in the Indian Ocean. PMEL is redesigning its surface moorings in an attempt to reduced loss of instrumentation and data, and relying more heavily on subsurface moorings. The first deployments of vandal resistant moorings in September Some modifications will result in less surface data, and less data in real time. If these modifications reduce the damage and losses of moorings, then (lower cost?) vandal resistant sensors may be added to the moorings. Longer term mooring solutions which adopt unique technology are being developed. Modifications which prove successful may be extended to other basins.