2.5 Bond-In Installation

2.5.1 Bond-In Installation Introduction

Seakeeper recommended adhesives are listed in TB-90382 – Structural Adhesives Recommendations. Seakeeper recommends using a structural adhesive with a lap shear strength of 2000 psi (13.8 MPa) or greater. Careful consideration should be exercised by the installer when selecting the appropriate adhesive, such as working time, material compatibility, and surface preparation are three important factors to consider. Proper surface preparation in accordance with the adhesive manufacturer’s recommendations prior to installation is critically important. Information regarding pot-life, structural properties and material compatibility can be found on the adhesive product’s technical data sheet (TDS). An etching/cleaning primer compatible with the adhesive should be used on all aluminum surfaces if recommended by the manufacturer. Typically, two-part methacrylate based adhesives are the best options for bond-in installations such as Plexus MA590 and Sci-GripSG300, which provide compatibility with aluminum and FRP substrates, adequate working time, and exceed the strength requirements. See Sheet 6 of Seakeeper Drawing No. 90226 – Seakeeper 9 Bond-In Installation Details for loads information and recommended adhesive properties.

2.5.2 Preparation of Hull Structure

Refer to Seakeeper Drawing No. 90226 – Seakeeper 9 Bond-In Installation Details. Important dimensional and load information is given in this drawing that will impact the design details of the structure that will receive the Seakeeper as well as selection of the adhesive to bond the Seakeeper into the hull.

The foundation “saddles” of the Seakeeper are designed to be bonded directly to the composite hull structure of the vessel to effectively distribute Seakeeper loads. A complete bond is required between the inside surface of the saddles and the hull structure. Seakeeper recommends having a minimum of 2.5 L / 0.66 gal of adhesive, on hand for installation. Number of cartridges required is determined by dividing total volume by cartridge volume. There is some adhesive waste as a part of the process so a good rule of thumb is to purchase 50% more adhesive than estimated volume to bond. Depending on conditions and adhesive used, two workers may be required to apply the adhesive at the same time to finish the installation before the adhesive starts to cure. To aid in determining the quantity of adhesive required, the interior surface area (bonding surfaces) of each saddle is 106 in.² (684 cm²) for a total bonded surface area for all four saddles of 424 in.² (2,736 cm²).

The hull structure supporting the Seakeeper should be installed so the Seakeeper is parallel to the waterline in the transverse direction and within 2 degrees longitudinally. The four areas on top of the beams that the saddles will bond to need to be co-planar within .13 in. (3 mm) for consistent adhesive bond gap. In addition, the four areas on top of the saddles on which the feet of the Seakeeper foundation will rest need to be co-planar within .06 in. (1.5 mm) to minimize potential distortion of Seakeeper support frame when installed.

Note that any paint or gel-coat present in bond area should be removed so that adhesive will bond directly to laminate fibers and resin.

Seakeeper provides an installation fixture template, P/N 90253, that locates the saddles at the proper spacing both in the forward-aft direction and the port-starboard direction. See Figures 11 & 12 below, and Figure 13 in the following section. Once assembled with the provided saddle fittings, the fixture can be used to check clearances and alignment of the hull structure. The fixture will allow the builder / installer to lay-up and adjust the foundation dimensions to create a low-clearance fit between the Seakeeper foundation saddles and the hull structure. Shear strength of the adhesive will be maximized if the cured thickness between the vessel structure and the Seakeeper saddles is at the thinner end of the adhesive manufacturer’s recommended range. Therefore, the fixture should be used to confirm that the overall dimensions of the foundations are square and level and that the adhesive gap is within Seakeeper’s recommended range of .04 in. to .13 in. (1 to 3 mm).

Note: Do NOT use the installation fixture to establish Seakeeper envelope dimensions. Refer to Drawing No. 90226 – Seakeeper 9 Bond-In Installation Details, for envelope dimensions. A 3-D model of the Seakeeper is available on the Seakeeper Technical Library (http://www.seakeeper.com/technical-library/) to aid in designing the Seakeeper foundation and the space around the Seakeeper.

NOTE: MAKE SURE NO OBSTRUCTIONS FROM THE HULL STRUCTURE CAN BE SEEN WITHIN THE INSIDE OF THE INSTALLATION TEMPLATE KIT (INSIDE THE MARKED RED LINES). SEE DRAWING NO. 90226 – SEAKEEPER 9 BOND-IN INSTALLATION DETAILS.

2.5.3 Hull Preparation

1. Position installation fixture (Figure 13) on hull girders noting recommended clearances for maintenance from Figure 4 (in Section: Selection of Installation Location). Check that the screws fastening the saddles to the installation fixture are tight (Figure 14).

2. Mask hull area (Figure 14) around foundation saddles for easy clean-up and to create outline of surface area to receive adhesive as (Figure 13). Ensure that the bond gap is within Seakeeper’s recommended thickness, or 3 mm if using Plexus MA590.

3. Raise fixture clear of foundation. Check all four mounting areas are co-planar to within .13 in. (3 mm) to each other, as well as parallel to the water line plane, as shown in Figure 13 and 15.

4. Thoroughly clean with alcohol or acetone all areas of girders to be bonded to remove any contaminates. Use new paper towels for cleaning, not shop rags.
5. Remove any paint or gel-coat from bond surfaces so that adhesive will bond directly to laminate fibers and resin as shown in Figure 15.
6. Thoroughly sand girder bond surfaces with 80 grit sandpaper. (IMPORTANT – BOND STRENGTH MAY BE REDUCED IF THIS STEP IS SKIPPED.)
7. Wipe surfaces clean from dust with alcohol or acetone using new paper towels, not shop rags.
8. Re-position installation fixture on girders and double-check that the adhesive gap is within the adhesive manufacturer’s maximum recommended thickness. Seakeeper recommends a maximum gap of 3 mm if using Plexus MA590.

Note: if bonding saddles to a metal structure, follow adhesive manufacturer instructions for metal substrates.

2.5.4 Seakeeper Saddle Preparation

1. Ensure that screws fastening saddles to the installation fixture are tight (Figure 14).
2. Check that each saddle contains 2 plastic screws which will ensure an adhesive gap of .080 in. (2 mm) on top surface of hull as shown in Figure 16. Do not remove these screws.

3. Thoroughly sand all saddle inside surfaces with 80 grit sandpaper in cross-hatch pattern. (IMPORTANT – BOND STRENGTH MAY BE REDUCED IF THIS STEP IS SKIPPED.)
4. Thoroughly clean with alcohol or acetone the inside surfaces of Seakeeper foundation saddles to remove any contaminates as shown in Figure 16. Use new paper towels for cleaning, not shop rags.

5. If using Plexus MA590 adhesive, apply Plexus PC-120 surface conditioner to inside surfaces of Seakeeper foundation saddles in accordance with manufacturer instructions. These instructions are located at the end of this section. If using an alternate adhesive, check with manufacturer if any surface conditioner/etch is required for the aluminum saddles.

2.5.5 Bonding Saddles to Hull

Note: This is a sample if using Plexus, if using another adhesive follow manufacturer’s recommendations.

If using Plexus MA590 adhesive, the Seakeeper saddles should be installed when PC-120 is confirmed dry.

1. Assemble Plexus cartridge into either the manual or pneumatic gun as shown. Remove cap on cartridge and attach mixing tip. For pneumatic gun, start with low air pressure and increase until desired flow rate is achieved.

2. Cut tip of mixing wand as shown in photo below.

3. Prepare a second mixing wand as shown in photo below by attaching the simple flexible nozzle to the end of the mixing tip. Set aside for now as this will be used to inject adhesive into the sides of each saddle after the fixture / saddles are in position.

4. Install provided rubber plugs in six holes of each saddle. The plugs will limit the adhesive being forced out of the injection holes in step 6 below.

5. Apply large bead of Plexus adhesive to the hull structure as shown in the figure to the right. Apply approximately ½ to ⅔ cartridges (200 – 275 mL) at each of the four locations. Work deliberate and fast as it takes some time to apply the adhesive to the structure. MA590 has a 90-minute working time at room temperature (73°F / 23°C). This working time can reduce to 40-50 minutes at elevated temperatures. Two workers should apply the adhesive at the same time to finish the installation before the adhesive starts to cure.

6. Lower fixture and saddles over the hull structure and apply light downward pressure to each of the four saddles until the two nylon screws rest on the hull structure (see Figure 7). The adhesive will be forced towards the forward and aft ends of each saddle and partially down the sides of the foundation beams.
7. Insert full adhesive cartridge along with mixing wand / nozzle assembled in Step 3 above into gun.
8. Begin to inject adhesive into the six holes provided on each of the four saddles. Follow the numbered sequence shown below until the adhesive pushes out the edges of the saddle perimeter. The intent is to pump in the adhesive working from the top down and from the middle to the ends to fill the gaps and displace any air.

A complete bond is required – excess adhesive will
be needed to make sure all bond gaps are filled.

9. When gaps of all four saddles have been completely filled, clean off excess adhesive, remove plugs, and remove masking tape.
10. Allow adhesive to cure per manufacturer’s recommendations. Follow adhesive guidelines for curing time versus temperature prior to removing the fixture.
11. Bonding of Seakeeper saddles onto the hull is now complete. Remove installation fixture.

2.5.6 Installation of Seakeeper

1. The four areas where the feet of the Seakeeper will rest should be coplanar to within .06 in. (1.5 mm). See figure to the right.
2. Rig Seakeeper for lifting and lower it into position onto top surface of four saddles.
3. Apply a small bead (approximately 4 mm wide) of sealant or caulk to the mating surfaces between the saddles and the Seakeeper foundation. Adjust position of Seakeeper until alignment is achieved for the 16 fasteners that will attach the Seakeeper foundation frame to saddles.
4. Install Seakeeper supplied Grade 8.8, M14-2.0 x 85 mm fasteners or alternative Grade M10.9, M14-2.0 bolts to maintain a minimum thread engagement of .084 in. (21 mm). Apply a moderate coat of nickel-based anti-seize (e.g., SAF-T-EZE nickel grade anti-seize, SBT-4N or equivalent) to the threads of each bolt and include a small bead of marine grade sealant (e.g., SILI-THANE 803 or equivalent) under each bolt head and washer before installation.
5. Torque all fasteners to 100 ft-lbs (136 N-m).
   
   1. New bolts, matching the Seakeeper specification, must be used for each installation and reinstallation that meet the requirements listed above.
6. Proceed to electrical and cooling portion of the installation.

3.1 Electrical Installation Introduction

This section for electrical installation explains how to mount the electrical equipment and how to connect the electrical cables.

Reference Documents & Drawings:

• 90221 – Seakeeper 9 Hardware Scope of Supply
• 90223 – Seakeeper 9 Operation Manual
• 90257 – Seakeeper 9 Cable Block Diagram
• 90438 – Touchscreen Display Envelope and Mounting Details
• 90467 – Seakeeper 5″ Display Kit
• TB-90640 – ConnectBox Connection Requirements
• MFD Compatibility Technical Bulletins
  
  • TB-90478 – Garmin and Seakeeper Compatibility
  • TB-90479 – Raymarine and Seakeeper Compatibility
  • TB-90480 – NAVICO (Simrad/Lowrance/B&G) and Seakeeper Compatibility
  • TB-90598 – Furuno and Seakeeper Compatibility

Figure 18 – Electrical Equipment for Seakeeper 9

3.2 Electrical Equipment Power Connections

230 VAC Power Source Requirements

1. 230 VAC (nominal), 1 Phase, 50/60 Hz, 20 A
2. For installations of more than one Seakeeper, a separate circuit breaker should be used for each Seakeeper Motor Drive Box.

Drive Box AC Power Input Connection Instructions

1. 230 VAC Input Cable: 3 x 10 AWG (3 x 6 mm² CSA), 10 ft. (3 m) length, Seakeeper supplied pre-installed.
   
   1. Locate 230 VAC Input Cable for AC power input to the Drive Box at the outboard of the Motor Drive Box cable glands.

2. Connect 230 VAC Input Cable wires to a 20 A, double-pole Circuit Breaker at an AC power distribution panel according to Figure 20 above.

24 VDC Power Source Requirements

1. One 24 VDC, 10 A (Customer supplied) for Seakeeper Control Power, AND
2. One 24 VDC, 10 A (Customer supplied) for DC Seawater Pump.
3. A separate breaker should be used for each Seakeeper.

DC Power Connection Instructions

Reversing polarity on the DC power input to the Seakeeper can result in damaging the electronics in the control system.

1. 24 VDC, 10 A, 2 x 12 AWG (3 x 4.0 mm² CSA) customer supplied.
   
   1. Install Seakeeper provided DC Power Input Cable, P/N 20248 (as shown in Drawing No. 90257).
      
      1. Route 24 VDC Power Cable to DC Power Distribution Panel.
      2. Terminate positive (B+, Red ) conductor to +24 VDC.
      3. Terminate negative (B-, Black) conductor directly to battery negative terminal.
   2. Before connecting cable to Seakeeper, check for proper voltage and polarity with a DC multimeter using Figure 21 below.
   3. Connect 24 VDC Input Cable to 24 VDC input receptacle on Seakeeper.

DC Seawater Pump 24 VDC Power Input Connection Instructions

Connecting the DC Seawater pump in any other manner than recommended by Seakeeper may cause internal failure.

1. Install Seawater Pump Input Cable (P/N 30327) to Seakeeper 9 “SW Pump DC In” (as shown in Drawing No. 90257) with overcurrent protection corresponding to seawater pump selected.
2. Connect the 16AWG positive conductor (Red) through dedicated overcurrent protection device (customer supplied), maximum of 10 A, to dedicated battery isolation switch.
3. Connect the 16 AWG negative conductor (Black) directly to battery negative terminal or DC main negative bus bar.
4. Before connecting Seawater Pump Input Cable to Seakeeper, check for proper voltage and polarity with a DC multimeter using Figure 8 below.

5. Connect Seawater Pump Input Cable to Seawater Pump 24 VDC In connector on the Seakeeper, DEUTSCH DT04-2P connector.

DC Seawater Pump 24 VDC Power Output Connection Instructions

1. Connect Seawater Pump Output Cable to the Seakeeper 9 “SW Pump 24VDC Out” for DC power to the seawater pump.
   
   1. Seawater Pump Output Cable is a 2 x 16 AWG cable, 16 ft (5m) length with a size 16 female Deutsch plug.
2. Pumps rated at 24 VDC, 10 A maximum, customer-supplied, must be configured with a Deutsch DT series, 2-pin receptacle to mate with the connector shown in Figure 23.

3. Seawater Pump Output Cable must be routed and installed in the vessel from the Seakeeper 9 “SW Pump 24VDC Out” Deutsch connector (pins end) to the DC seawater pump cable Deutsch connector (socket end).
4. Connect Seawater Pump Output Cable plug end (socket end) to the customer-supplied receptacle end (pins end). The recommended wiring is shown in Figure 24.
5. Contact Seakeeper if desired to install customer-supplied relay on Seawater Pump Output Cable to power seawater pump.

3.3 Electrical Equipment Ground Connections

Seakeeper to Vessel Ground Connection Instructions

1. Connect the Seakeeper foundation to vessel ground, as shown in Figure 25.
2. Install Ground Cable (10 AWG or 6 mm², Customer supplied) from the M6 brass ground stud on the Seakeeper rear brace to a suitable vessel ground.
   
   • EN/IEC 90204-1 Clauses 6.3.3 and 8.2.3
   • ABYC E-11 July 2018 Clauses 11.5.2 and 11.16.1.
3. Ground connection should be made with vessel bonding system, if available. However, the ground is not referring specifically to a bonding system but for outboard boats generally refers to the outboard engine negative terminal. Per ABYC E-11 (2018), Clause 11.5.2.7.4: If the negative side of the DC system is to be connected to the ground, the connection shall be made only from the engine negative terminal, or its bus, to the DC grounding bus. This connection shall be used only as a means of maintaining the negative side of the circuit at ground potential and is not to carry current under normal operating conditions.
4. A proper ground connection is critically important for corrosion protection and helps to ensure the ignition protection of the unit by ensuring it does not carry any stray current.

NOTE: THIS LOCATION SHOULD ONLY BE USED FOR GROUNDING THE SEAKEEPER TO THE VESSEL GROUND

3.4 ConnectBox Connections

Seakeeper 9 Display Options

A compatible display is required with the installation of a Seakeeper 9 to support the full functionality of the unit through the Seakeeper App in addition to the ConnectBox. The Seakeeper App provides an interface for controlling the Seakeeper 9 or viewing the Settings, Service, Info, and Alarm pages. The Seakeeper ConnectBox can be helm-mounted to provide an additional interface for the control of the Seakeeper 9 but does not replace the need for a Seakeeper compatible display.

The Seakeeper 9 has several control interface connection options to support the Seakeeper App:

1. Connect the Seakeeper 9 to a compatible Multifunction Display (MFD) as seen in Figure 26.
2. Install an optional Seakeeper 5″ Touch Display (P/N 90467) as seen in Figure 27.
3. A combination of a compatible MFD and an optional 5″ Touch Display is also available.

The following figures provide schematics of display options. The subsequent sections outline the instructions and references for connecting the Seakeeper 9 to a compatible MFD display or an optional Seakeeper 5″ Touch Display.

Connecting to a Compatible MFD

1. The Seakeeper 9 can be connected to a variety of available MFD systems. Refer to the Technical Bulletins Section of the Seakeeper Technical Library for manufacturer specific MFD compatibility technical bulletins.
   
   1. MFD specific Technical Bulletins will be updated regularly as new MFD systems become available. Currently Garmin, Raymarine, NAVICO (Simrad, Lowrance, B&G), and Furuno offer compatible MFD models.
   2. Once a compatible MFD has been selected, refer to the appropriate manufacturer specific Technical Bulletin for integration instructions.
2. Connect Seakeeper-supplied Ethernet Adapter cable, M12 D-Code, 82 ft (25 m), cable to MFD manufacturer-specific Ethernet adapter cable (See Figure 26 above). Custom Ethernet cables for specific MFD manufacturers are available through Seakeeper and must be purchased with the Seakeeper 9 when connecting to an MFD.

Connecting to an Optional Seakeeper 5″ Touch Display

If not utilizing a compatible MFD display, a Seakeeper 5” Touch Display must be purchased from Seakeeper. The Seakeeper 5” Touch Display (P/N 90467) includes the components shown in the following figure and will be integrated with the ConnectBox.

1. Determine location of Seakeeper 5” Touch Display:
   
   1. The desired location of the 5” Touch Display must be determined with respect to the vessel’s arrangement.
   2. The 5” Touch Display should be located on or near the helm or another easily accessible location.
2. Route CAN communications cable:
   
   1. The CAN Cable, (labelled NMEA 2000 Cable in Figure 28), is a 10 m shielded cable that connects the ConnectBox Tee adapter to the 5” Touch Display.
      
      • NOTE: Cable lengths are also available in 25, 35, 50, and 65 meters
   2. The 32.8 ft (10 m) CAN cable must be routed and installed in the vessel from the Seakeeper 9 wire harness CAN Tee to the Tee Adapter at the Seakeeper 5” Touch Display, included with P/N 90467.
3. Install Seakeeper 5″ Touch Display equipment:
   
   1. Console space required: Approx. 5.24 W x 3.70 H in. (133 x 94 mm)
   2. Mounting Instructions, Surface Mount: see Envelope and Mounting Details, in Drawing No. 90438 – 5” Display Envelope and Mounting Details.
4. CAN communications tee adapter and terminator mounting instructions:
   
   1. Console space required, Rear: Approx. 4 W x 3 H in. (102 x 76 mm)
   2. Mounting Instructions: Rear mount on vessel console panel, within 2 ft (0.6 m) of Display.
   3. Hardware required: One mounting screw for .197 in. (5 mm) diameter mounting hole on Tee Adapter.
5. Connect Seakeeper 5” Touch Display Equipment:
   
   1. The Seakeeper 5” Touch Display is connected in accordance with Figure 27 above.
6. The USB Extension Cable is 6.5 ft (2 m) long cable that enables software updating on a 5″ Touch Display where accessibility to rear panel is limited.

NMEA 2000 Network Connection

The Seakeeper 9 requires a connection to the vessel’s NMEA 2000 network backbone via a drop cable for access to the GPS signal. The Seakeeper 9 will monitor information on the NMEA network to support and optimize the performance of the Seakeeper 9. If no GPS signal is detected, a warning will appear on the Seakeeper display. The Seakeeper will not spool-down, but the operation of the unit will be limited until the GPS signal returns.

1. Install customer-supplied NMEA 2000 Tee Adapter (space required: approximately 4 W X 3 H in. (102 X 76 mm).
2. Connect NMEA Backbone to Tee Adapter. NOTE: NMEA drop cable can be no longer than 19.6 ft (6 m) in length.
3. Connect Seakeeper-supplied NMEA cable (P/N: 30332) to the customer-supplied NMEA 2000 Tee Adapter on vessel’s NMEA 2000 backbone.
   
   1. An active NMEA 2000 compatible GPS signal is required on the vessel’s NMEA 2000 backbone to operate the Seakeeper 9.
      
      • If no GPS signal is detected, a Speed Over Ground (SOG signal) warning will be present on the Seakeeper app. See TB-90640 for NMEA connectivity guidance.

ConnectBox Helm Mounting – Optional

1. Console space required: Approx. 3.41 L x 4.15 W in. (87 x 106 mm).
2. Mounting Instructions, Surface Mount: See Drawing No. 90558 – Seakeeper ConnectBox Helm Mounting Kit, for details. Seakeeper ConnectBox 3D Model available upon request.
3. Mount ConnectBox Replacement Blank insert into Seakeeper 9 enclosure at the original location of the ConnectBox.

4.1 Cooling Installation Introduction

Reference Documents & Drawings:

90257 – Seakeeper 9 Cable Block Diagram

90251 – Seakeeper 9 Cooling Water Schematic

30331 – Seakeeper DC Seawater Pump Assembly

TB-90191 – Seawater Cooling Pump Recommendations

The Seakeeper 9 is shipped with the cooling circuit filled and ready for use (See Figure 29). The Seakeeper 9 requires connection to a raw water pump, referred to as the seawater pump, to cool the closed loop cooling circuit on the unit. The required seawater flow through the Seakeeper 9 heat exchanger is between 4 – 8 GPM (15.1 – 30.3 LPM), under all vessel operating conditions. Prior to operation, confirmation of glycol level is required.

Seakeeper offers a compatible self-priming DC Seawater Pump (P/N 30331) that is pre-wired for the Seakeeper 9 installation and covered under the standard Seakeeper Warranty. See Drawing No. 30331, Seaflo Seawater Pump Assembly for details and the Seakeeper Options and Accessories Price List for pricing information.

4.2 Cooling System Considerations

1. Installer is responsible for supplying a dedicated seawater pump and associated plumbing. Seawater connections on the Seakeeper heat exchanger mate with ¾ in. (19 mm) hose. An optional seawater pump can be purchased through Seakeeper, P/N30331.
2. The seawater pump is powered by Cable 5, via “SW Pump 24 VDC Out” on the Seakeeper 9, as outlined in Electrical Installation Section.
   
   • This pump must operate on 24 VDC, 10 A OR 12 VDC, 15 A power. Pumps requiring other voltages or higher current can still be controlled by using this supply to trigger an installer-supplied relay but a separate source of power must be provided.
3. A dedicated through-hull fitting should be installed for each Seakeeper unit onboard the vessel to ensure sufficient seawater flow to each unit.
4. It is recommended that the seawater pump is located below the waterline, as close to the baseline of the vessel as practically possible, to maintain positive inlet pressure on the pump in all operating conditions.
5. A self-priming seawater pump is recommended to maintain water flow in all underway conditions. Cavitation can occur at the seawater inlet and potentially cause an air-lock condition restricting seawater flow to the heat exchanger.
6. Vented loops are optional and should only be considered with centrifugal style pumps. Self-priming or positive displacement style pumps do not require a vented loop, this includes Seakeeper P/N 30331.
7. Maximum seawater pressure in heat exchanger is 20 psi (1.4 bar)
8. Seawater flow requirement through heat exchanger is 4 GPM (15.1 LPM) minimum and 8 GPM (30.3 LPM) maximum under all operating conditions of the boat. When sizing seawater pump, installer should factor in losses for raw water plumbing. In addition to initial operation at dock, new Seakeeper installations should be checked to be within the flow requirements while vessel is at speed. Flows higher than 8 GPM (30.3 LPM) could affect heat exchanger life.

4.3 Connecting Seawater to Heat Exchanger

Refer to Figure 31 for typical Seakeeper 9 seawater plumbing arrangement.

1. Connect seawater from installer-supplied pump to lower ¾ in. (19 mm) hose barb on heat exchanger. (See Figure 1) Use the same practices as other below waterline seawater plumbing. Required flow rate is 4 GPM (16 LPM) minimum and 8 GPM (30.3 LPM) maximum.
2. Connect seawater discharge (upper hose barb) to overboard drain. (See Figure 29) Use the same practices as other below waterline seawater plumbing.
3. In addition to initial operation at dock, new installations should be checked for minimum 4 GPM (16 LPM) flow while vessel is at speed and when backing down. If no other method of confirming flow is available, discharge line may be temporarily diverted to a bucket. Flow is calculated from time to fill a known volume. A self-priming seawater pump (customer/installer supplied) may be required due to installation location to maintain water flow in all underway conditions where cavitation near the intake may occur and potentially cause an air-lock condition restricting seawater flow to the heat exchanger.
4. Inspect raw water plumbing after sea trial for any signs of leakage.
5. Heat exchanger contains removable endcaps to provide access for cleaning the tube bundle.

Seakeeper Optional DC Seawater Pump (P/N 30331)

1. Seakeeper offers a self-priming DC Seawater pump operated at 24 VDC for the Seakeeper 9 (Figure 32).
2. The pump assembly is pre-wired for connection to Seakeeper 9 Seawater Pump Output Cable, “SW Pump Output” and includes a seawater strainer and various fittings. The pump specifications are as follows:

NOTE: Only use SeaFlo-provided threaded fittings with DC Seawater Pump 30331.

4.4 Adding Coolant

1. Cooling system is filled to proper level when shipped, with a mixture of 50% ethylene glycol and 50% distilled water. The reservoir and clear tube between heat exchanger and reservoir should be filled with green coolant mixture, as shown in Figure 33. If level has dropped, check for evidence of leaks at all connections before adding fluid as described below. If coolant is at the correct level, skip to Section: Connecting Seawater to Heat Exchanger.
2. Note: Some amount of entrained air in the fluid is normal and acceptable.  This air will be evident by some cloudiness of the fluid.  As long as the fluid remains at the specified fill level during operation, the remaining cloudiness is not an issue.

2. Mix 50% ethylene glycol with 50% distilled water in a clean container. Refer to Table 1 or glycol manufacturer’s literature for freezing points.

3. Remove vent cap on top of reservoir. Pour mixture in until level reaches 2/3 reservoir as shown in Figure 33. Filling reservoir above this level will not cause any damage but coolant may be expelled from vent on top of cap due to normal thermal expansion of coolant.
4. Connect 24 V to controller.
   1. At the MFD app / optional 5″ Touch Display check for any ALARMS
      
      
   2. Press the POWER ON/OFF button.
   3. The flywheel will start to spin and the glycol pump will start.
   4. Recheck glycol level with fluid circulating in coolant circuit. Sight down inside reservoir and check that coolant level is above upper port on reservoir as shown in Figure 4. Replace cap.
   5. After several minutes of running, press POWER ON/OFF button to turn power off to the flywheel.
5. The cooling system is self-purging. If small amounts of air are in the system, they will most likely be dislodged during the first sea trial. Re-check glycol level after sea trial and add fluid if required.

5.1 Installation Requirements Introduction

The Installation Requirements section outlines the components and tools needed for the Seakeeper 9 installation that are not included within the scope of supply.

5.2 Required Supplies and Tools for Installation

5.2.1 Required Supplies Needed for Seakeeper Installation
(Not Supplied with the Seakeeper)

5.2.2 List of Common Tools That May Be Required for Installation

6.1 Checklists Introduction

This section describes the first startup of the Seakeeper.

Reference Documents & Drawings:

• 90223 – Seakeeper 9 Operation Manual
• 90437 – Seakeeper Commissioning Form
• 90569 – Seakeeper ConnectBox and App Quick Start Guide
• SWI-105 – Commissioning Checklist

• Previous sections for mechanical, electrical and cooling installation must be completed before this startup sequence is initiated.
• Before continuing, covers must be installed unless the Seakeeper is inaccessible and there is no risk to injury. Also, the area around the Seakeeper must be clear of personnel and equipment.

The Installation and Start Up Checklist section provides an overview of the primary steps covered in the installation manual and should be referenced throughout the installation process. Upon completion of the
Seakeeper 9 installation, the installer should commission each Seakeeper unit with the Seakeeper Commissioning Form (90437). The Commissioning Checklist Work Instruction (SWI-105) provides a checklist of items to inspect and verify during the commissioning process and serves as a supplement to the Seakeeper
Commissioning Form (90437).

All Seakeeper stabilizers should be commissioned to verify installation specifications and requirements have been implemented properly. The commissioning process should include completion of the Seakeeper
Commissioning Form (90437), all the items in the Installation Checklist, and verification of Seakeeper operation without alarms or abnormal behavior.

6.2 Installation Checklist

Please Complete Checklist and E-mail to
customerservice@seakeeper.com or telefax to +1.410.326.1199

5.1.1 Mechanical Checklist
(Reference Installation Manual Section: Mechanical Installation)

5.1.2 Electrical Checklist
(Reference Seakeeper Drawing No. 90257 – Seakeeper 9 Cable Block Diagram & Installation Manual Section: Electrical Installation)

Mount Components

_____ Display (near helm)

Connect Customer Supplied Cables

Seakeeper Ground Cable (Customer supplied)

_____ Install lugs on both ends of customer-supplied 10 AWG (6 mm²) ground cable

_____ Connect one end of ground cable to nearest vessel ground and other end to Seakeeper 9 rear
brace

Connect Seakeeper Supplied Cables

Control Power Cable

_____ Connect control power cable from Seakeeper to 24 VDC power at customer-supplied connection
box or directly to circuit breaker

_____ Plug connector of control power cable into mating connector on Seakeeper wire harness

AC Input Cable

_____ Connect AC input cable from Drive Box to 230 VAC single phase at customer-supplied connection
box or directly to circuit breaker

DC Seawater Pump Power Cable

_____ Connect DC seawater pump power input cable from Seakeeper to 24 VDC /10 A power at customer-
supplied connection box or directly to circuit breaker

_____ Plug connector of DC seawater pump power cable into mating connector on Seakeeper wire
harness at DC SW Pump In

DC Seawater Pump Output Cable

_____ Connect seawater pump output cable from DC SW Pump Out to 24 VDC seawater pump

MFD Ethernet Adapter Cable

_____ Connect male end of ethernet adapter cable to Ethernet connection on ConnectBox

_____ Route ethernet adapter cable to selected MFD compatibility cable towards helm

_____ Connect female end of ethernet adapter cable to MFD compatibility cable

_____ Connect MFD compatibility cable to MFD Display

OPTIONAL Seakeeper 5″ Display CAN Cable

_____ Connect female end of CAN communication cable to tee-adapter at ConnectBox
(at tee-adapter terminal resistor)

_____ Route CAN communication cable to Seakeeper 5″ display

_____ Connect male end of CAN communication cable to tee-adapter with terminal resistor at 5″ display

5.1.3 Cooling Checklist
(Reference Installation Manual Section: Cooling Installation)

_____ Verify coolant level in coolant reservoir

_____ Connect seawater hoses / open sea cocks to heat exchanger and test seawater pump

_____ Verify 4 GPM (15 LPM) minimum and 8 GPM (30 LPM) maximum seawater flow through heat
heat exchanger under all operating conditions of the boat

5.1.4 Start Up Checklist
(Reference Installation Manual Section: Start Up & Operation Manual Section: System Operation)

_____ Remove lifting eyebolts and install cover panels

_____ Turn on 24 VDC circuit breakers

_____ Turn on 230 VAC circuit breaker

_____ Verify display works and no ALARMS are present

_____ If display does not work, turn off both circuit breakers immediately

_____ Check polarity of 24 VDC power per Section 3.4

_____ Follow instructions in Installation Manual Section: Start Up Instructions to turn on the Seakeeper

_____ Verify seawater pump turns on while the Seakeeper is turned ON

_____ Verify no ALARMS are present

_____ Follow instructions in Installation Manual Section: Startup Instructions to turn off the Seakeeper

_____ AC & DC power and seawater pump may be turned off after the Seakeeper is turned off by placing the
Seakeeper in LOCK mode and turning the Seakeeper off

_____ Seakeeper 9 takes 4+ hours to coast down to 0 RPM from full speed

6.3 Start Up Checklist

Refer to Seakeeper 9 Operation Manual for detailed start up instructions.

Prior to beginning the start up sequence all previous Sections of the Installation Manual for Mechanical, Electrical, and Cooling installation must be complete.

Before continuing, the Seakeeper cover must be installed and the operating clearances must be clear of personnel and equipment.

7.0 Revision History