The Claw — Vessel Integration & General Arrangement

Draft High Research 5,126 words Created Mar 5, 2026

The Claw -- Vessel Integration & General Arrangement

How every subsystem physically connects on an Aframax tanker conversion to form a functioning plasma processing vessel. This is the systems-level view that ties together the subsystem research into a unified ship design.

This document does NOT repeat subsystem details. It references:

Internal Layout (node 54) for deck zones and space allocation
Retrofit Engineering (node 55) for strip-out scope and structural mods
Operations Plan (node 56) for power budgets and daily procedures
PRRS Deep Dive (node 46) for reactor specifications
Feedstock Science (node 65) for material flow and storage sizing
Collection Systems (node 6) for collection hardware specs
Syngas (node 22) for gas cleanup train specs

What this document adds: the connections between systems, the conversion sequence, electrical architecture, thermal integration, control systems, interface specifications, and combined weight/stability analysis.

1. Process Flow: Plastic In, Power + Slag Out

The complete material path from ocean to output, showing every handoff between subsystems.

1.1 Primary Process Flow (Bow-to-Stern, Left-to-Right)

OCEAN                                                              OUTPUTS
  |                                                                   |
  v                                                                   v
[Boom/Drone] --> [Receiving] --> [Pre-Process] --> [PRRS] --> [Syngas Train] --> [Engine] --> ELECTRICITY
  Collection      Deck           Line              Reactor     Gas Cleanup       Genset      (powers ship)
  (stern/side)    (stern)        (mid-aft)         (midship)   (midship)         (midship)
                                                      |            |                |
                                                      v            v                v
                                                   [Slag]     [Scrubber        [Exhaust
                                                    Hold       Waste]           Stack]
                                                   (below      (hazmat          (above
                                                    deck)       tank)            processing)

1.2 Detailed Handoff Chain (12 Steps)

Step	From	To	Interface	Physical Connection
1	Ocean	Boom system	Water surface	200-600m V-boom, 1-3m draft, towed or deployed from stern
2	Boom	Receiving deck	Boom recovery	Stern ramp or side conveyor. Hydraulic winch pulls boom codend to deck. Debris + seawater deposited in receiving hopper
3	Receiving hopper	Freshwater rinse	Gravity feed	Hopper drains seawater through grated floor. Overhead spray bar rinses salt. Runoff to process water system
4	Rinse station	Shredder	Conveyor belt	600mm wide belt conveyor, 2-5m run, variable speed. Manual sorting station inline for oversized items (large nets pre-cut by crew)
5	Shredder	Dewatering	Conveyor/chute	Shredded output (50-100mm fragments) drops into dewatering centrifuge or screw press. Moisture reduced from 50-70% to 15-25%
6	Dewatering	Feed hopper	Screw conveyor	Enclosed screw conveyor, 3-5m run, delivers de-watered shredded feedstock to reactor feed hopper. 24-48 hour buffer capacity in hopper (decouples collection from processing)
7	Feed hopper	PRRS reactor	Sealed feed system	Ram feeder or screw injector pushes feedstock into reactor chamber. Air-locked to prevent syngas backflow. Continuous feed at 0.2-0.4 tonnes/hour
8	PRRS reactor	Syngas cleanup	Insulated pipe	Hot syngas exits reactor at 800-1,100C. Rapid water quench (<0.5 seconds) drops to <100C. 200mm diameter insulated pipe, 5-10m run to cleanup train
9	Syngas cleanup	Syngas buffer	Steel pipe	Clean, cool syngas at ~50C. Composition: H2 48-53%, CO 24-28%. Passes through cyclone, scrubber, carbon bed, cooler, moisture separator. Exits to 50m3 buffer tank at low pressure
10	Syngas buffer	Gas engine	Steel pipe	Regulated gas supply to Jenbacher J620 GS or equivalent. 150mm pipe, pressure-regulated, with flame arrestor at engine inlet
11	PRRS reactor	Slag hold	Gravity chute	Molten slag tapped from reactor bottom, water-quenched to granulate, conveyed to below-deck hold via enclosed chute. 100-300 kg/day
12	Gas engine	Ship electrical bus	Cable	2-3 MW output at 6.6 kV or 440V, synchronized to ship main switchboard

1.3 Secondary Flows

Process water loop: Rinse water + dewatering effluent + quench water + scrubber blowdown --> process water treatment (oil/water separator, filtration, pH adjustment) --> recirculation to rinse station and quench system. Makeup from RO watermaker. Zero overboard discharge.

Waste heat recovery: Reactor shell radiation + syngas sensible heat + engine exhaust heat --> ORC (Organic Rankine Cycle) evaporator --> additional 50-100 kW electricity + feedstock thermal drying. The ORC is the key patent (US 9,447,705) that makes the energy loop close.

Scrubber waste: HCl scrubber (from PVC content ~5% of feedstock) produces acidic waste water with dissolved chlorides. Neutralized with caustic soda, stored in dedicated hazmat tank (below deck, double-walled), offloaded at port. Volume: ~0.5-1.0 m3/day.

2. Interface Specifications

The interfaces between subsystems are where integration failures happen. Each interface has mechanical, electrical, control, and safety requirements.

2.1 Collection-to-Processing Interface (CRITICAL -- least mature)

Physical location: Stern deck, transition from open collection area to enclosed pre-processing area.

Mechanical interface:

Boom codend lifted by 25-40 tonne SWL crane onto receiving hopper
Hopper: 5m x 3m x 2m, steel construction, grated floor for drainage
Debris falls by gravity into rinse zone
Large debris (ghost nets > 2m) requires manual pre-cutting before shredder
Two-person crew station for manual sorting and oversized removal

Design challenge: The material arriving from the boom is heterogeneous -- tangled fishing nets, rigid containers, film plastic, biofouled debris, seawater, marine organisms. The transition from "wet ocean debris" to "uniform shredded feedstock" is the most operationally demanding part of the entire system.

Interface requirement: The receiving hopper and pre-processing line must handle:

Debris pieces from 1mm (microplastic) to 5m+ (ghost net tangles)
50-70% moisture content
Marine organism bycatch (crabs, fish, seaweed) -- must be sorted out before shredding
Occasional non-plastic debris (metal, wood, rope) -- must be diverted

Equipment at interface:

Hydraulic grapple on crane for net handling
Vibrating screen to separate fine debris from large items
Manual sorting conveyor (slow speed, 0.2 m/s, crew on each side)
Pre-cutting station: hydraulic shears for net bundles
Magnetic separator for ferrous metals
Metal detector on conveyor before shredder

2.2 Reactor-to-Syngas Interface

Physical location: Processing core, midship.

Mechanical interface:

Syngas exits reactor at 800-1,100C through refractory-lined exit port
Immediate water quench chamber (<0.5 second residence time) -- this prevents dioxin/furan formation
Quench chamber produces steam + cooled syngas at <100C
Quenched gas enters cyclone separator (removes particulates)
Then wet scrubber (removes HCl, trace metals)
Then activated carbon bed (removes remaining organics)
Then gas cooler (drops to ~50C)
Then moisture separator (removes water droplets)
Then syngas buffer tank (50 m3, low pressure)

Piping requirements:

Reactor exit to quench: 200mm bore, Inconel 625 or equivalent high-temperature alloy, < 2m length (minimize hot gas residence time)
Quench to cyclone: 250mm bore, stainless steel 316L, insulated
Cyclone to scrubber: 250mm bore, SS316L or FRP (fiberglass reinforced plastic)
Scrubber to carbon bed: 200mm bore, SS316L
Carbon bed to cooler: 150mm bore, SS316L
Cooler to separator: 150mm bore, SS316L
Separator to buffer tank: 150mm bore, carbon steel (gas is clean at this point)
Buffer tank to engine: 150mm bore, carbon steel, with flame arrestor, pressure regulator, and emergency vent

Control interface:

Gas composition analyzer after cleanup train (continuous H2, CO, CH4 monitoring)
Pressure/temperature sensors at each stage
Emergency vent to atmosphere (through flame arrestor) if syngas quality is off-spec
Automatic shutdown if H2S > 50 ppm or HCl > 10 ppm at engine inlet

2.3 Engine-to-Ship Electrical Interface

Physical location: Processing core / engine room boundary.

Electrical interface:

Syngas engine: Jenbacher J620 GS, 2-3 MW output
Generator: synchronous, 6.6 kV or 440V (depends on ship bus voltage)
Synchronization: automatic sync panel connects syngas genset to main bus
Diesel backup gensets remain on main bus for redundancy
Shore power connection retained for port operations

Integration requirement: The syngas genset must parallel with diesel gensets seamlessly. During cold start, diesel genset powers the ship. Once syngas is flowing, syngas genset takes load, diesel genset drops to standby. If syngas supply fails (reactor trip, cleanup system fault), diesel genset picks up load automatically within seconds. This requires:

Automatic bus transfer switch (< 0.5 second transfer)
Load sharing controller
Reverse power relay (prevents syngas genset from motoring if gas supply drops)
UPS for critical systems (navigation, comms, fire/gas detection): 30-minute battery backup minimum

2.4 Slag Handling Interface

Physical location: Below reactor, through deck penetration to cargo hold.

Mechanical interface:

Molten slag exits reactor bottom via gravity tap
Water granulation: molten slag drops into water bath, shatters into granules (2-10mm)
Granulated slag + water pumped via slurry pipe to dewatering screen
Dry granules drop into below-deck hold via enclosed chute through deck penetration
Hold: repurposed cargo tank, no special coating needed (slag is inert)

Volume: 100-300 kg/day (0.04-0.12 m3/day at 2,500 kg/m3). A single cargo tank (3,000-6,000 m3) holds 68-411 years of slag. This is a non-problem.

Deck penetration: The slag chute passes through the main deck into the hold below. This penetration must be:

Weathertight (prevents seawater ingress)
Fire-rated (H-120 minimum -- molten material above, cargo hold below)
Structurally reinforced (local deck stiffening around penetration)
Accessible for maintenance (removable cover/hatch)

3. Electrical Architecture

3.1 Single-Line Diagram (Conceptual)

                        MAIN SWITCHBOARD (440V/6.6kV)
                    ____________|____________
                   |            |            |
            [Syngas Genset] [Diesel G1] [Diesel G2]
             2-3 MW (primary)  1 MW (backup) 1 MW (emergency)
                   |
    _______________|________________
   |         |         |           |
[Process] [Collection] [Hotel]  [Propulsion]
 Bus       Bus          Bus      Bus
   |         |         |           |
 Reactor   Cranes    HVAC      Main Engine
 Cleanup   Conveyors  Lighting   Bow Thruster
 Shredder  Winches    Galley
 Pumps     Sensors    Comms
                      Navigation

3.2 Power Distribution

Bus	Consumers	Peak Demand	Normal Demand	Priority
Process	PRRS torch (200-500 kW), APT (200 kW), cleanup train (30-50 kW), feed system (20-30 kW)	780 kW	550 kW	Critical -- loss means reactor shutdown
Collection	Cranes (150 kW intermittent), conveyors (30 kW), shredder (50-80 kW), dewatering (20-40 kW), boom winches (30 kW)	330 kW	150 kW	Important -- can pause without reactor impact
Hotel	HVAC (40-60 kW), lighting (20-30 kW), galley (30-50 kW), watermaker (15-25 kW), comms (15-25 kW), sewage (5-10 kW)	200 kW	150 kW	Essential -- life safety
Propulsion	Main engine (12-15 MW transit), bow thruster (500 kW), steering (30 kW)	15,530 kW	30 kW (station-keeping)	Transit only -- zero during processing

Load shedding priority (if syngas supply drops): 1. Shed collection bus first (cranes, conveyors stop -- reactor continues from buffer) 2. Shed non-essential hotel (reduce HVAC, dim lighting) 3. Diesel genset auto-starts within 10 seconds 4. Never shed: navigation, comms, fire/gas detection, reactor cooling, emergency lighting

3.3 Hazardous Area Classification

Syngas (H2 + CO) is flammable and toxic. The processing core must be classified per IEC 60079:

Zone	Area	Equipment Requirement
Zone 0	Inside reactor, syngas piping, buffer tank	Intrinsically safe only (not normally accessible)
Zone 1	3m radius around syngas equipment, gas cleanup train	Ex d (flameproof) or Ex e (increased safety)
Zone 2	Processing deck generally, 5m from Zone 1 boundary	Ex n (non-sparking)
Non-hazardous	Accommodation, bridge, engine room (if separated by gas-tight bulkhead)	Standard equipment

Gas detection: Fixed H2 and CO detectors at all Zone 1/2 locations. Alarm at 20% LEL, automatic shutdown at 40% LEL. Portable monitors for all crew entering processing deck.

Ventilation: Processing deck is open (natural ventilation) wherever possible. Enclosed spaces within processing area have forced ventilation with independent fans, interlocked to gas detection. Minimum 12 air changes per hour in enclosed processing spaces.

4. Thermal Integration

The Claw generates significant waste heat. Capturing it improves energy efficiency and reduces cooling requirements.

4.1 Heat Sources

Source	Temperature	Thermal Output	Currently Wasted?
Reactor shell radiation	200-400C (outer shell)	50-150 kW thermal	Yes
Syngas sensible heat (pre-quench)	800-1,100C	200-400 kW thermal	Partially captured in quench
Engine exhaust	400-500C	300-600 kW thermal	Yes
Engine jacket cooling	80-90C	200-400 kW thermal	Yes
ORC condenser reject	30-50C	100-200 kW thermal	Yes (low grade, limited use)

Total recoverable waste heat: ~850-1,750 kW thermal

4.2 Heat Sinks (Useful Applications)

Application	Temperature Needed	Heat Required	Source Match
Feedstock thermal drying	80-120C	100-300 kW	Engine jacket water or reactor shell
Freshwater (RO preheat)	25-35C	10-20 kW	ORC condenser reject
Accommodation heating	20-25C	20-40 kW	ORC condenser reject
Process water heating	40-60C	20-50 kW	Engine jacket water
ORC working fluid	150-300C	200-500 kW	Engine exhaust + reactor shell (THIS IS THE KEY RECOVERY)

4.3 ORC Integration (Patent US 9,447,705)

The Organic Rankine Cycle recovers waste heat from the engine exhaust and reactor shell to generate additional electricity:

Engine exhaust (450C) ──> ORC evaporator ──> Working fluid vaporizes
                                                    |
Reactor shell (300C) ──> ORC evaporator ──>         v
                                              ORC turbine ──> Generator (50-100 kW)
                                                    |
                                                    v
                                              ORC condenser ──> Seawater cooling
                                                    |
                                              Pump ──> back to evaporator

ORC working fluid: R245fa or similar low-boiling-point organic fluid (boils at ~15C at atmospheric, operates at elevated pressure).

ORC location: Adjacent to engine and reactor, within processing core. Footprint: ~20-30 m2. Weight: ~5-10 tonnes.

The ORC is what makes the energy loop close at 5 TPD. Without it, the net energy surplus is marginal or negative at low throughput. With it, an additional 50-100 kW pushes the balance positive.

4.4 Cooling System

Seawater cooling is the primary heat rejection path. The GPGP surface water temperature is 18-24C (subtropical), providing an excellent cold sink.

Engine cooling: seawater-to-freshwater heat exchanger (standard marine)
ORC condenser: seawater-cooled (direct or via intermediate loop)
Syngas cooler: seawater-cooled
HVAC condenser: seawater-cooled

Total seawater cooling demand: ~1,500-3,000 kW thermal rejection

Seawater intake: existing tanker sea chest (hull-mounted intake), filtered. No modification needed. Discharge: overboard (heated seawater only -- no chemical contamination from cooling loop).

5. Control System Architecture

5.1 Distributed Control System (DCS)

The vessel needs an integrated control system that manages processing, power, and marine systems.

                    MAIN CONTROL ROOM
                    (Bridge Extension)
                         |
                    [DCS Server]
            _____________|_____________
           |             |             |
    [Processing     [Power          [Marine
     Controller]     Controller]     Controller]
         |              |              |
    - Reactor          - Syngas       - Navigation
    - Feed system        genset       - Ballast
    - Cleanup train    - Diesel       - Steering
    - Shredder          gensets       - Fire/gas
    - Dewatering      - UPS          - Comms
    - Slag handling    - Load shed    - HVAC
    - Collection       - Shore power  - Bilge

5.2 Automation Level

System	Automation Level	Human Role
Reactor temperature control	Fully automatic (PID loop)	Monitor, adjust setpoints
Feed rate	Semi-automatic (operator adjusts based on feedstock quality)	Set rate, watch for jams
Syngas cleanup	Fully automatic	Monitor gas quality
Power management	Fully automatic (load sharing, bus transfer)	Monitor
Collection/boom	Manual with powered assists	Crane operator, deck crew
Pre-processing	Semi-automatic (conveyors auto, sorting manual)	Manual sorting, shredder feed supervision
Slag tapping	Semi-automatic (timed tap, auto granulation)	Monitor
Navigation	Autopilot with manual override	Watch officer
Emergency shutdown	Fully automatic (gas detection, overpressure, fire)	Initiate manual ESD if needed

5.3 Emergency Shutdown (ESD) System

Independent from DCS (hardwired, fail-safe). Three ESD levels:

Level	Trigger	Action
ESD-1 (Process)	Gas detection 40% LEL, reactor overpressure, syngas quality off-spec	Stop feed, extinguish plasma arc, close syngas isolation valves, vent syngas through flame arrestor, maintain cooling
ESD-2 (Plant)	Fire in processing area, multiple gas alarms, loss of cooling	ESD-1 + trip syngas engine, start diesel genset, isolate processing area ventilation, activate fire suppression
ESD-3 (Abandon)	Uncontrollable fire, structural failure, vessel emergency	ESD-2 + general alarm, muster stations, prepare lifeboats

ESD response time: Gas detection to valve closure < 5 seconds. Plasma arc extinguish < 2 seconds (power cut). Syngas engine trip < 3 seconds.

6. General Arrangement: Plan Views

6.1 Main Deck Plan (Top View)

BOW                                                                         STERN
 |                                                                            |
 |  [HELIPAD]  [ACCOMMODATION]    [PROCESSING CORE]       [COLLECTION]  [BRIDGE]
 |  26m dia    3-4 deck block     Reactor + Syngas +       Receiving     Super-
 |  + HRF      Cabins, galley,    Engine + ORC +           hopper,       structure
 |  + foam     medical, rec,      Cleanup train +          rinse,        Nav,
 |  + fuel     workshop below     Buffer tank +            sort,         Ops center
 |             Fire wall (A-60) →  Exhaust stack           shredder,     Radio
 |                                 Fire wall (H-120) →     dewater,      GMDSS
 |  ~30m       ~45m               ~80m                     crane(s)      ~30m
 |                                                         ~60m
 |  PORT SIDE: Lifeboat station, pipe rack, walkway (3m min clearance)
 |  STARBOARD SIDE: Lifeboat station, pipe rack, walkway (3m min clearance)
 |

Key design decisions:

Processing core is midship (best motion characteristics -- least pitch/roll acceleration)
Collection is aft (boom deploys from stern, crane access to water)
Accommodation is forward (upwind of processing exhaust in prevailing trade winds)
Helipad at bow (furthest from hot exhaust and collection operations)
Bridge at stern superstructure (sightlines to collection operations)
Fire walls separate each zone: A-60 between accommodation and processing, H-120 between processing and collection (H-120 because hot slag/reactor side faces collection)

6.2 Below-Deck Tank Arrangement

BOW                                                                         STERN
 |                                                                            |
 | [Ballast] [Fresh  ] [Ballast] [Feed-  ] [Slag ] [Ballast] [Diesel] [Ballast]
 | Wing      Water     Wing      stock    Hold    Wing      Storage   Wing
 | tanks     2,000-    tanks     Buffer   3,000-  tanks     500-     tanks
 | (P+S)     3,000 m3  (P+S)    2,000-   6,000   (P+S)    1,000 m3  (P+S)
 |                               4,000 m3  m3
 | [Ballast] [Methanol] [Ballast] [Ballast] [Ballast] [Hazmat] [Slop/Sewage]
 | Center    1,000-     Center    Center    Center    500-     500 m3
 |           2,000 m3                                1,000 m3
 |           (Phase 1.5)

Tank assignment rationale:

Ballast in wing tanks: Standard tanker practice. Active ballast management compensates for changing topsides weight as feedstock is consumed and slag accumulates
Freshwater midship: Central location for distribution to accommodation (fwd) and processing (mid)
Feedstock buffer mid-aft: Close to collection deck (aft) and reactor (midship). Enclosed screw conveyor connects to reactor feed hopper above
Slag hold midship: Directly below reactor for gravity-fed slag chute. Shortest possible path for molten slag handling
Methanol center tank (Phase 1.5): Amidships for stability. Double-hull protection required per IBC Code. N2 blanket system, cofferdams on all sides
Diesel aft: Close to engine room. Standard tanker fuel tank location
Hazmat aft: Scrubber waste, contaminated process water. Small volume, double-walled, segregated

6.3 Processing Core Detail (Expanded View)

                    PROCESSING CORE (~80m x 40m)
    PORT                                              STARBOARD
     |                                                     |
     | [Pipe    [Syngas      [PRRS         [Feed     [Pipe  |
     |  rack]    Cleanup      Reactor       Hopper    rack]  |
     |           Train]       + Stack       + Ram            |
     |           Cyclone                    Feeder]          |
     |           Scrubber                                    |
     |           Carbon bed                                  |
     |           Cooler                                      |
     |           Separator]                                  |
     |                                                       |
     | [ORC      [Syngas      [Jenbacher   [Slag     [Elec- |
     |  Module]   Buffer       Gas Engine   Granu-    trical |
     |            Tank         + Generator  lation    Switch |
     |            50 m3]       2-3 MW]      + Chute]  room]  |
     |                                                       |
     |  3m egress walkway on both sides                      |

Equipment arrangement logic:

Reactor centrally located (heaviest item, best stability position)
Feed hopper adjacent to reactor (shortest possible feed path)
Syngas cleanup train inline from reactor exit (minimize hot gas piping length)
Buffer tank between cleanup and engine (decouples gas production from consumption)
Engine adjacent to electrical switchroom (shortest cable run for heavy power)
ORC module between reactor and engine (captures waste heat from both)
Slag granulation directly below reactor (gravity-fed through deck penetration)
Pipe racks on both port and starboard for syngas, process water, cooling water, instrument air

7. Conversion Sequence: Shipyard Order of Operations

The conversion takes 24-36 months. The sequence matters -- some work must happen before other work can begin.

Phase 1: Strip-Out & Survey (Months 1-4)

Month	Work	Notes
1	Vessel arrives at conversion yard. Drydock for hull survey	Full thickness measurement, ultrasonic testing, classification surveyor present
1-2	Strip cargo systems: pumps, piping, COW, IGS, heating coils	500-800 tonnes removed. Hazmat survey (asbestos in old insulation)
2-3	Tank cleaning and gas-freeing. Internal inspection of all cargo tanks	Hydrocarbon residue removal. Decide which tanks need recoating
3-4	Stability calculation with new loading condition (preliminary)	Naval architect runs intact + damage stability with estimated topsides weight
4	Scope confirmation meeting with classification society	Final strip-out complete. Yard, designer, class agree on conversion scope

Phase 2: Structural Modifications (Months 4-12)

Month	Work	Notes
4-6	Deck reinforcement: new stiffeners, pillar supports through to tank top	800-1,200 tonnes new steel. Hot work permits, confined space entry
5-7	Reactor foundation: grillage, thermal isolation, secondary containment	80-120 tonnes. Heaviest single foundation on the vessel
6-8	Bulkheads and fire walls: A-60 between zones, H-120 around processing	300-500 tonnes. Must be gas-tight where separating hazardous areas
7-9	Crane pedestals (2x), helipad structure, accommodation extension	Crane bases need deep foundations to hull structure
8-10	Exhaust stack structure, pipe rack foundations, equipment stools	All major steel complete by month 10
10-12	Hull repairs (as identified in survey), recoating, anode replacement	Drydock work if needed

Parallel (months 4-12): Equipment procurement. PRRS reactor has 12+ month lead time -- order at conversion start, not when foundation is ready.

Phase 3: Equipment Installation (Months 10-22)

Month	Work	Notes
10-12	Crane installation. Heavy lift required for 25-40 tonne SWL cranes	Yard crane or floating crane
12-14	PRRS reactor module delivery and installation	Heaviest single lift (80-150 tonnes). Must be lifted over side and set on foundation. Alignment critical
13-15	Syngas cleanup train installation (cyclone, scrubber, carbon bed, cooler)	Modular -- can be pre-assembled at manufacturer then shipped as skid
14-16	Jenbacher gas engine + generator installation	Engine room modification. Vibration mounts, exhaust routing, cooling connections
15-17	ORC module installation	Adjacent to engine. Thermal connections to engine exhaust and reactor shell
16-18	Collection equipment: boom winches, conveyors, shredder, dewatering	Stern area. Can proceed independent of processing core installation
17-19	Electrical: new switchboard, cable pulls, motor connections, lighting	Thousands of meters of cable. Hazardous area equipment installation
18-20	Piping: syngas, process water, cooling water, fire main, instrument air	Major piping campaign. Hydrostatic testing of all process piping
19-21	Instrumentation: DCS, gas detection, fire detection, ESD system	Control room fit-out. Loop testing of every instrument
20-22	Accommodation fit-out: cabins, galley, medical bay, recreation	Can proceed parallel to processing installation
21-22	Helipad: deck surfacing, lighting, foam system, fuel system	Late installation to avoid damage during construction

Phase 4: Commissioning & Testing (Months 22-28)

Month	Work	Notes
22-23	Mechanical completion. Punch list.	Walk-through every system, identify incomplete items
23-24	Cold commissioning: run all systems without feedstock/plasma	Pump tests, valve stroke tests, electrical load tests, control system verification
24-25	Hot commissioning: first plasma ignition, first syngas production	PyroGenesis engineers on board. Controlled feedstock (clean plastic pellets, not ocean debris)
25-26	Performance testing: energy balance verification, throughput test	Run at design rate for 48-72 hours continuous. Measure everything
26-27	Inclining experiment and stability verification	Required by classification society. Confirms actual vs. predicted stability
27-28	Sea trials: 3-5 days at sea. Full system testing underway	Navigation, propulsion, station-keeping, collection system deployment, processing at sea
28	Classification certificate issued. Flag state registration	Vessel officially approved for operations

Total: 28 months (optimistic), 36 months (realistic with delays)

8. Combined Weight & Stability Analysis

8.1 Weight Budget

Consolidating equipment weights from all subsystem research:

Item	Weight (tonnes)	Source Doc	CG Height Above Keel (m)
Lightship (stripped tanker)	14,000-16,000	Hull selection	~9.5 (standard Aframax)
New structural steel	1,800-2,700	Retrofit engineering	~14 (deck level)
PRRS reactor module	80-150	PRRS deep dive	~16 (on main deck)
Syngas cleanup train	54-103	Syngas / retrofit	~16
Gas engine + generator	85-100	Retrofit engineering	~8 (engine room level)
ORC module	5-10	This document	~15
Cranes (2x)	60-80	Retrofit engineering	~18 (above deck)
Collection equipment	50-80	Collection systems	~15
Helipad structure	80-120	Internal layout	~18 (elevated)
Accommodation extension	100-200	Retrofit engineering	~20 (multi-deck)
Piping + electrical	100-200	Retrofit engineering	~12 (distributed)
Misc (coatings, furniture, outfit)	50-100	Estimate	~12
TOTAL TOPSIDES	2,464-3,843	Combined	~14.5 (weighted avg)

8.2 Deadweight Items (Variable)

Item	Weight (tonnes)	CG Above Keel (m)
Ballast water	25,000-40,000	~5 (low, in double bottom and wing tanks)
Diesel fuel	400-800	~6
Freshwater	2,000-3,000	~6
Feedstock buffer	0-2,000	~6 (in cargo tank)
Slag (accumulated)	0-500	~5 (below deck)
Methanol (Phase 1.5)	0-200	~6
Provisions/stores	50-100	~12
Crew + effects	5-10	~15

8.3 Stability Assessment

Key metric: GM (metacentric height)

An Aframax tanker has GM of 2-5m in various loading conditions. Adding ~2,500-3,800 tonnes of topsides at ~14.5m CG height raises the overall KG (center of gravity).

Preliminary estimate (from internal layout doc): KG ~6.6m with topsides installed. This is LOW and favorable -- the heavy ballast water in low tanks keeps the CG well below the metacenter.

Stability is not a limiting factor. The vessel started as a tanker designed to carry 80,000-120,000 tonnes of crude oil at a high CG. The topsides equipment is ~3% of the original cargo weight. Ballast management provides ample margin.

What DOES matter: asymmetric loading. If feedstock accumulates on one side, or a crane lifts a heavy load to one side, the vessel lists. Active ballast management (automatic ballast transfer to compensate for list) is essential.

9. Critical Integration Risks

Risk	Impact	Mitigation
PRRS dimensions differ from estimates	Foundation doesn't fit, piping runs change	Get exact dims from PyroGenesis during FEED. Foundation design uses maximum envelope + 15% margin
Syngas composition varies with feedstock mix	Engine detonation, cleanup train overload	Gas composition analyzer before engine. Automatic feed rate adjustment. Conservative engine tuning
Collection interface doesn't handle net tangles	Processing starved, crew overworked at manual sorting	Size pre-cutting station for worst case. Budget for 2-person sorting crew per watch
Electrical load exceeds generation at 5 TPD	Must run diesel backup, breaks self-power narrative	Design for 10 TPD capacity, accept that 5 TPD may need diesel assist. ORC recovery is critical at low throughput
Vibration from processing equipment affects navigation/accommodation	Crew fatigue, instrument calibration drift	Vibration isolation mounts on all major rotating equipment. Vibration survey during commissioning
Thermal expansion of reactor piping	Pipe stress, flange leaks, syngas release	Expansion bellows, sliding supports, proper pipe stress analysis during detailed design
Hot work near syngas systems during maintenance	Fire/explosion risk	Comprehensive hot work permit system. Gas-free certification before any hot work. Never do hot work while reactor is operating

10. What FEED Must Resolve

The Front End Engineering Design (FEED) phase turns this conceptual design into an engineering specification. These items cannot be resolved without FEED:

1. Exact PRRS reactor dimensions and weight -- from PyroGenesis, after PoC results confirm technology selection 2. Specific hull selection -- hull condition determines structural modification scope 3. Syngas composition from actual ocean plastic -- from PoC Stage 2, determines engine selection and cleanup train sizing 4. Classification society requirements -- from AiP process, may drive design changes 5. Shipyard-specific constraints -- crane capacity, drydock dimensions, labor availability 6. Detailed pipe stress analysis -- thermal expansion, vibration, ship motion 7. Finite element analysis -- hull structure under combined loading (topsides + wave + mooring) 8. Electrical load study -- actual equipment specifications, cable sizing, short circuit analysis 9. HAZOP study -- systematic identification of process hazards, required for classification approval 10. Escape route analysis -- fire safety engineering, mustering routes, lifeboat access from all locations

Summary

This document provides the systems-level integration view that connects the subsystem research into a unified ship design. Key takeaways:

1. 12-step process flow from ocean to output, with every handoff specified 2. 4 critical interfaces defined: collection-to-processing (least mature), reactor-to-syngas, engine-to-electrical, slag handling 3. Electrical architecture with load shedding priority and hazardous area classification 4. Thermal integration recovers ~850-1,750 kW waste heat; ORC is the key to closing the energy loop at 5 TPD 5. 28-month conversion sequence (optimistic) with 4 phases and critical path through PRRS procurement 6. Combined weight budget shows ~2,500-3,800 tonnes topsides on a ship designed for 80,000-120,000 tonnes cargo. Stability is not a concern 7. 10 FEED items that must be resolved with actual equipment data before detailed design can proceed

The collection-to-processing interface is the least mature element. Everything else has industrial precedent (FPSO conversion, PAWDS marine plasma, syngas engines). The integration challenge is engineering, not invention.

Research compiled March 2026. Integrates content from 10 existing knowledge tree documents (nodes 6, 7, 22, 46, 54, 55, 56, 58, 65) into a unified vessel design view. No subsystem detail is duplicated -- this document covers only interfaces, integration, sequence, and combined analysis.