Tuesday, April 30, 2019

Marine DC Wiring Basics




Behind these gold-colored switch panels lurked a 40-year-old tangle of do-it-yourself wiring projects. The amazing thing is that all of the systems still worked. Does your boat have a similar legacy of bad electrical work?
There’s an old axiom that states, “The strongest chain is only as reliable as its weakest link.”
That same truism can be applied to your boat’s DC electrical system. Put it in a corrosive environment, where wiring and electrical components are subjected to more concentrated daily abuse than your family car will experience in five years, and it’s easy to see how small electrical problems can get out of hand very quickly.
Safety onboard begins with a reliable DC electrical system, properly installed with quality wiring, connections and components. Don’t take shortcuts when wiring your boat, or you may compromise the safety of your boat and crew. This is critically important because, according to BoatUS Marine Insurance, problems with DC electrical systems are responsible for more onboard fires, 32 percent, than any other category of causes.
In my several decades of owning and working on boats, I have personally seen more examples of scary do-it-yourself DC electrical projects than any other type of boat equipment disaster. Something about 12-volt DC power seduces and encourages hack electricians to try their hand using household-grade wire and terminals. The amazing thing is how many of these rat’s nests of wiring actually work, for the moment.
If you’re not familiar with basic electrical practices and theory, hire someone who is, and let them install that new fishfinder, LED cabin light, anchor windlass or subwoofer! With that said, there are a lot of great resources that you can purchase from your favorite book store, like Don Casey’s Sailboat Electrical Systems: Improvement, Wiring, and Repair, John C. Payne’s Marine Electrical Bible and Edgar J. Beyn’s The 12-Volt Doctor's Practical Handbook, so you really can learn to complete some simple electrical projects on your boat. This stuff really is not rocket science.
This West Advisor will help you understand some basic standards and practices of DC marine wiring. We’ll start with one of the most frequently asked questions, about which kind of wire to use.

Can I use “regular wire” for my boat?

The answer to this common question is a qualified “yes,” if the wire is SAE (Society of Automotive Engineering) J378, J1127 or J1128. These wires are designed for “surface vehicles,” not for the special requirements of the marine industry, but meet the minimum standards for boats in limited circumstances.


Ancor Marine Grade wire products are the longest lasting and most rugged available, exceeding UL 1426, ABYC and US Coast Guard Charter boat (CFR Title 46) standards. Notice the silver color of the conductors, because the wire is “tinned.”
Even if tinned copper, your wiring should not be run in bilge spaces or other areas subject to moisture from spray or dripping. American Boat and Yacht Council (ABYC) standards include this requirement: “Current-carrying conductors shall be routed as high as practicable above the bilge water level and other areas where water may accumulate. If conductors must be routed in the bilge or other areas where water may accumulate, the connections shall be watertight (11.14.4.1.5 ).” They should not be run in engines spaces, unless marked “oil resistant” and “75°C”. They should not be used in applications where subjected to vibration or frequent flexing and must never be used for 110 volt applications. For safety, use only wire that is marked with size and type.
Most importantly, SAE wire is up to 12 percent smaller than American Wire Gauge (AWG) Boat Cable which means that, in many applications, larger gauge wire must be used to stay within the voltage drop limits recommended by experts (see our West Advisor on Marine Wire Size and Ampacity). The wire charts found in Chapman’s Piloting and other publications are all for AWG wire like that made by our supplier, Ancor, not SAE type wire. In general, wiring on boats should be of the stranded type, not solid copper wire used in household applications, which does not withstand the vibration found onboard a boat.
With that said, why not just use real marine grade wire?

Primary wire color standards

The ABYC (American Boat and Yacht Council) Standards & Technical Information Reports for Small Craft recommends the following color standards for marine wiring of boat engines and accessories. Select wire color from the list below.
Marine wire color codes

What size wire should I use?

This is a basic question you need to tackle when designing your own wiring. Installing overly large wire is expensive and adds weight, but installing wire of inadequate size is a safety concern. There are four key variables you should consider: amperage or ampacity, temperature, whether the wires are bundled closely together, and voltage drop.

Ampacity

Ampacity is defined as the current carrying capacity of a conductor or device—how many amperes of current you can run through it. Many electrical loads, such as LED lights, for example, draw a constant amount of amps so are simple to calculate by checking the specs of the device. Others, such as power inverters or any device operating an electrical motor, will have a large spike in amperage when they start operating. Your circuit needs to be sized to handle all of the maximum amperages of all the devices in the circuit. If you’re installing an anchor windlass that typically draws 80 amps, but may draw 300 amps when you’re trying to break your anchor loose from a rocky bottom, you need to size the wiring accordingly.

Temperature

The temperature where you’re running your wiring affects how much current it can safely carry. Briefly, the higher the ambient temperature of the environment, the lower the amount of amperage the cable can carry. If you’re running wiring through your boat’s engine room, ABYC standards assume the temperature is 122°F (50°C). If you’re planning a circuit with #6 AWG wire size, it can safely carry 80 amps outside the engine room, but only 46.4 amps in the hotter engine room environment. In general, maximum current is 15% less in engine spaces, which are assumed to be 20°C hotter than non-engine spaces (50°C vs. 30°C).

Cable bundling

While we’re on the topic of heat, you should understand that cables that are bundled together generate a cumulative amount of heat, and have more difficulty dissipating that heat than when they are run individually. This is something to be aware of, but the relevant ABYC standard only applies to wiring carrying 50 volts or more, so it is typically a problem with AC circuits on a boat, not your typical 12 volt DC wiring installation. In general, if three conductors are bundled, reduce maximum amperage by 30%. If four to six conductors are bundled, reduce maximum amperage by 40%. If seven to 24 conductors are bundled, reduce amperage by 50%.


Voltage drop

Voltage drop, our fourth key variable in wire sizing, introduces the factor of the length of the wires into your calculations. Each wire has a predictable level of internal resistance, so that in a DC circuit, you will lose a certain amount of energy that’s turned into heat. The longer the wiring run, the greater the voltage drop. This can be a real problem with some types of electronics or with electric motors, which will run more slowly at 11.5 volts.
The solution is to use a wire with lower internal resistance—a larger diameter wire, since bigger wires have less resistance—and ABYC gives us a choice of two voltage drop tables to calculate this size. We have shared both of these voltage drop tables in our Advisor, Marine Wire Size and Ampacity. The ABYC’s standards for voltage drop read as follows: “Conductors used for panelboard or switchboard (main) feeders, bilge blowers, electronic equipment, navigation lights, and other circuits where voltage drop must be kept to a minimum, shall be sized for a voltage drop not to exceed three percent. Conductors used for lighting, other than navigation lights, and other circuits where voltage drop is not critical, shall be sized for a voltage drop not to exceed 10 percent.”
I don’t know about you, but on my boat, I don’t want any of my 12 volt devices running at a voltage that’s 1.2 volts (10 percent of 12 volts) less than what it’s designed for! Nigel Calder agrees with this viewpoint in his Boatowner’s Mechanical and Electrical Manual, one of the key books you should have on your shelf if you own a boat. He writes, “I recommend always using the 3% table, given the harshness of the marine environment, it just does not pay to start out by trying to cut calculations as fine as possible.” So, if you take our advice—and Calder’s—just use the 3% voltage drop numbers. This makes sizing wire much easier, because if you make your wiring large enough to prevent a drop in voltage, you’ll have cables that will easily meet the ampacity requirements.

Making secure connections

Which is better, soldering or crimping terminals?


Nylon 8 AWG Red Ring Terminal

12-10 #10 Heat Shrink Spade Terminal

Heat Shrink Butt Connectors, 22-18 gauge red, 16-14 gauge blue, 12-10 gauge yellow

Red male and female nylon disconnects, 22-18 gauge

Red Heat Shrink Snap Plugs, 22-18 gauge
Most wire problems happen at the connections, and the experts are mostly in agreement on this one. Connections should be mechanically connected, not just soldered. Per ABYC (E-11.16.3.7), “Solder shall not be the sole means of mechanical connection in any circuit”. Further, crimping provides a solid mechanical connection resistant to “cold joints” breaking under fatigue, and removes strain.
NEVER twist wires together, connect wires together with household “wire nuts” or wrap a bare wire around a terminal screw to connect wires together. A proper crimp connection is essential for safety and current-carrying ability. Use a good quality crimper, like the Ancor Double Crimp Ratcheting Wire Terminal Crimper. The ABYC Standards (11.14.3.8) have something to say about this too, advising that “Solderless crimp on connectors shall be attached with the type of crimping tools designed for the connector used, and that will produce a connection meeting the requirements of E-11.14.3.3.” That means they recommend you use a crimper made by Ancor if you’re crimping Ancor-made terminals, because the barrel and insulation thicknesses vary from one manufacturer to another.

Use the pull test

Put the terminal in the correct die in the crimper, insert the wire into the terminal, and squeeze until the jaws grip the terminal lightly and hold it in place without distortion. Check the finished crimp to see that the wire is firmly in place by giving it a good solid tug. By the way, 16 Gauge AWG connectors are designed to safely handle a pull of 15 pounds; 10 Gauge terminals are rated for 40 pounds; 00 battery cable terminals are rated for 150 pounds, per ABYC. Finish the job with heat-activated, adhesive-lined heat shrink tubing.
Terminals are color-coded to fit different gauges of wire: red for 22- to 18-gauge wire, blue for 16- to 14-gauge wire and yellow for 12- to 10-gauge wire. Select the proper terminal for your job. Below are some examples and their uses:

Ring terminals

For permanent secure termination. Ring terminals can’t pull off, and for that reason are preferred over spade terminals. Per ABYC E-11.14.4.1.11, “Ring and captive spade type terminal connectors shall be the same nominal size as the stud.”

Flanged spade terminals

For permanent termination when terminal screw is captive. ABYC recommends: “Terminal connectors shall be of the ring or captive spade types.” E-11.16.3.4

Butt connectors

For connecting two wire leads of the same size. Step-down butt connectors join a pair of conductors to a third, all of the same size, or join two conductors of different sizes.

Disconnects and snap plugs

Quick-disconnect connectors, also called “disconnects,” are common as a quick connect/disconnect solution for electronic and digital equipment. The ABYC recommends their use for circuits of not more than 20 amps, with a voltage drop of less than 50 mV with a 20-amp current, and as long as they stay connected with up to a six-pound pull.

Wire support standard

The ABYC recommends that wires be supported every 18" along their path. This is to prevent repeated flexing, due to the boat’s motion through the water, or the engine’s vibration. Cable ties and clamps are approved methods of securing wires.

More wiring standards from ABYC

Extra wire at junction boxes or distribution panels

“11.14.4.1.12 Conductors terminating at panelboards in junction boxes or fixtures shall be arranged to provide a length of conductor to relieve tension, to allow for repairs and to permit multiple conductors to be fanned at terminal studs.”

Chafe protection

“11.14.4.1.7 Conductors that may be exposed to physical damage shall be protected by self-draining loom, conduit, tape, raceways, or other equivalent protection. Conductors passing through bulkheads or structural members shall be protected to minimize insulation damage such as chafing or pressure displacement. Conductors shall also be routed clear of sources of chafing such as steering cable and linkages, engine shafts, and control connections.”

Only four terminals

“11.14.4.1.10 No more than four terminals shall be secured to any one terminal stud. If additional connections are necessary, two or more terminal studs shall be connected together by means of jumpers or copper straps.” See also 11.14.4.1.10.2.1. It states that you can also swage multiple conductors into one terminal, provided that “the combined circular millimeters of the conductors does not exceed the circular millimeter capacity of the terminal“ and that you test the connection using the pull test described in E-11.14.3.3.

Install the highest ampacity terminal first

If you’re installing more than one ring terminal onto a stud, the largest and therefore highest ampacity terminal should be installed first, with successively smaller and lower-ampacity terminals installed afterward (11.14.4.1.10.1). Also note 11.14.4.1.11, which states that “Ring and captive spade type terminal connectors shall be the same nominal size as the stud.”

Avoiding magnetic interference with a compass

“11.14.4.2.1 Wiring shall be installed in a manner that will avoid magnetic loops in the area of the compass and magnetically sensitive devices. Wires that may create magnetic fields in this area shall run in twisted pairs.”

Ancor heat shrink tubing specs

ABYC recommends: “The shanks of terminals shall be protected against accidental shorting by the use of insulation barriers or sleeves, except for those used in grounding systems.” E-11.16.3.9. Heat shrink tubing, lined with adhesive, creates water, oil and acid-resistant seal, preventing corrosion at the electrical connection. It shrinks to one-third of its original size (a 3:1 shrink ratio).
Size Shrinks to Wire Range (AWG)
1/8" 1/32" <18
3/16" 1/16" 20 -12
1/4" 5/64" 16 - 10
1/2" 1/8" 12 - 8
3/4" 5/32" 8 - 4
3/4" 1/4" 6 - 2/0

DC circuit wizard

Blue Sea Systems’ DC Circuit Wizard performs calculations and recommends appropriate circuit protection options—fuse or circuit breaker—and wire size for just about all DC applications. DC Circuit Wizard
Design rule: a change in six gauge numbers is a fourfold increase in wire size. When the wire size goes down two numbers (from 14 to 12), the amount of copper in the wire goes up by 59 percent.

Marine Grounding Systems

This article was originally published in the October 15, 1996 issue of Practical Sailor magazine. The author, Stan Honey, is a renowned sailor, navigator and electrical engineer.

Marine Grounding Systems

ground n. 12. Electricity. A large conducting body, such as the earth or an electric circuit connected to the earth, used as an arbitrary zero of potential.
In a normal house on land, the problem of grounding is simple. It consists of the green grounding wire in the AC wiring system and serves the purpose of preventing shocks or electrocution. The ground connection is usually made by clamping to a metal water pipe or by driving a long copper stake into the ground.
On a boat, things are considerably more complicated. In addition to the AC ground, we need a DC ground or return line, a lightning ground, and a RF ground plane for the radio systems. Our first thought might be to simply make the ground connection to a metal thru-hull, propeller shaft or other underwater metal. This underwater metal will be grounded by connection to the seawater will serve as our water pipe. Unfortunately, a connection between any of these systems and underwater metal can, and probably will, give rise to serious electrolytic corrosion problems. This article will discuss the particular requirements of each system, resolve the contradictions between the systems and present a consistent and correct solution for a complete, integrated, marine grounding system.
Seawater Grounding Diagram
Figure 1. The boat's electrical system should be connected to seawater at one point only, via the engine negative terminal or its bus.

DC Ground

Every light or appliance should be wired with its own DC return wire. Never use the mast, engine, or other metal object as part of the return circuit. The DC load returns of all branch circuits should be tied to the negative bus of the DC distribution panel. In turn, the negative bus of the DC distribution panel should be connected to the engine negative terminal or its bus. The battery negative is also connected to the engine negative terminal or its bus. The key factor here is that the yacht's electrical system is connected to seawater ground at one point only, via the engine negative terminal or its bus. See figure one.

AC Ground

See Practical Sailor, August 15, 1995 for a detailed treatment of the green wire. The best solution is a heavy and expensive isolation transformer. The acceptable solution (for the rest of us) is to install a light and inexpensive Galvanic Isolator in the green wire, between the shorepower cord socket on your boat, and the connection to the boat's AC panel. Then, connect the grounding conductor (green) of the AC panel directly to the engine negative terminal or its bus.
Note that this meets the ABYC recommendation. In choosing Galvanic Isolators, make sure that you select one that has a continuous current rating that is at least 135% the current rating on the circuit breaker on your dock box. Certain Galvanic Isolators (e.g. Quicksilver) include large capacitors in parallel with the isolation diodes, which in certain situations theoretically provide better galvanic protection. Unfortunately, these units cost substantially more than conventional Galvanic Isolators. If you feel like spending real money on galvanic isolation, you might as well do it right and buy an isolation transformer.
It is also a good idea to use a Ground Fault Circuit Interrupter (GFCI) in your AC wiring. GFCI's will occasionally "nuisance trip" due to the humidity surrounding the wiring on boats, but the additional safety that they offer (particularly to nearby swimmers) in disconnecting power in the presence of ground currents is worth the nuisance. If your GFCI starts to nuisance trip, it is probably a very good idea to track down and clean up your damp wiring in any event.
GFCI diagram
Figure 2. Ground fault circuit interrupters (GFCI) should be installed in each AC circuit. A GFCI will disconnect power in the presence of ground currents, helping prevent an electrocution.

Lightning Grounds

Connect a 4 AWG battery cable from the base of your aluminum mast to the nearest keel bolt from external ballast. If you have internal ballast, you should install a lightning ground plate. One square foot is recommended for use in salt water; fresh water requires much more. Do not rely on a thru-hull or a sintered bronze radio ground (e.g. Dynaplate) for use as a lightning ground.
For additional comfort, also run a 6 AWG wire from your keel bolt or ground plate to the upper shroud chainplates, and to your headstay chainplate. Don't bother with the backstay if it is interrupted with antenna insulators. Have each of the cables that are used for lightning ground wires lead as directly as possible to the same keel bolt, with any necessary bends being smooth and gradual.
Given that you have grounded your mast solidly to the ocean, your mast will be at exactly the same electric potential as the ocean. There is no chance that you can dissipate the charge between the ocean and the atmosphere, so don't bother with a static dissipater at the masthead. Wire "bottle brush" static dissipaters may be useful to dissipate seagulls, however, but that is beyond the scope of this article.

RF Ground

Your VHF doesn't need to use the ocean as a counterpoise, so here we are dealing only with the ground needed for your HF/SSB radio.
Mount your automatic tuner as close to the backstay as possible, preferably just under the after deck. Run copper ground tape from the tuner to the stern pulpit/lifelines, to the engine, and to a keel bolt. It is good practice to include the HF/SSB radio itself in this network of ground tapes. If the builder of your yacht had the foresight to bond into the hull a length of copper tape or an area of copper mesh, be sure to run a copper ground tape to this as well, and say a blessing for builders such as these. Sintered bronze ground plates (e.g. Dynaplates) can be used as radio grounds in situations where the ballast or engine is unavailable or awkward to connect. If the ballast, engine, and lifelines are available, however, they generally make a high performance ground.

Bonding and Electrolytic Corrosion Due to Hot Marinas

Do not bond any thru-hulls or other immersed metal that can be electrically isolated. Specifically, keep your metal keel/ballast, your metal rudder shaft, your engine/prop, and all thru-hulls electrically isolated, from each other, and from the engine.
It's worth understanding the reason. In an increasing number of marinas, there are substantial DC electric currents running through the water. If your bits of immersed metal are bonded, the electric current will take the lower resistance path offered by your boat in preference to the water near your boat, and the current will flow into one of your bits of metal, through your bonding wires, and then out another bit of metal. The anodic bit of metal or thru-hull that has the misfortune to be on the "out current" side of the current running through your bonding system will also become "out metal" and will disappear, sometimes rapidly.
Your zinc is only intended to protect against the modest galvanic potentials and therefore currents that are caused by the dissimilar metals that are immersed and electrically connected together on your own boat. Your zinc is incapable of supplying enough galvanic potential to protect against substantial DC currents that may be flowing in the water. These DC currents in the water will cause electrolytic corrosion to your bonded thru-hulls or metal parts.

Zincs and Protection from Galvanic Corrosion

Use zincs to protect against the galvanic currents that are set up by dissimilar metals on your boat that are immersed and that are in electric contact with one another. The best example is your bronze propeller on a stainless shaft. The best protection is to put a zinc right on the shaft next to the propeller, or a zinc on the propeller nut. An isolated bronze thru-hull doesn't need protection because it is not in electrical contact with another immersed dissimilar metal. If electrically isolated, high quality marine bronze, is electrochemically stable in seawater; nothing good can come from connecting wires to it.
Diagram for lightning strike protection
Figure 3. Conductors running from the external keel or ground plate to the mast, stays and to the metal fuel tank will protect against a lighting strike, and there will be no DC connections to the engine or to the electrical system.
Stainless steel is a special case. Generally, it is a bad idea to use stainless steel underwater, because it can pit. When it pits the "nobility" of the metal changes locally, and you end up with tiny galvanic couples that are made up of different parts of the same piece of metal and the pits grow deeper. One school of thought suggests that if you must use stainless steel underwater (e.g. you need its strength), then you should connect a nearby, immersed zinc to it; this protects the stainless steel from itself, reducing the rate of pitting. The electrochemistry of this assertion is compelling enough to recommend that you protect a stainless steel rudder shaft with a zinc.
This may be done by mounting a zinc on the hull near the rudder shaft, and electrically connect it (inside the hull) to the stainless rudder shaft. For the reasons described above, ensure that your metal rudder shaft is not electrically connected to anything else. Your stainless steel propeller shaft will be protected from itself, by the same shaft zinc that protects the propeller from the stainless steel shaft. In both cases the pits, if they appear, will appear where the stainless steel is not exposed to the water. Trouble areas are in the cutlass bearing, inside the rudder bearing, and just inside the top of the rudder.
Keep your metal keel/ballast electrically isolated from all other bits of metal. If you have the misfortune to have an external iron or steel keel, however, mount a zinc directly on it to reduce the rate of corrosion. Leave lead keels/ballast isolated.
Alternative RF grounding solution
Figure 4. To avoid making another DC ground to the engine via the HF/SSB radio copper ground strip, fasten the copper tape securely to an insulating piece of phenolic or to a terminal strip, cut a 1/10" gap across the tape, and solder several 10.15 uF ceramic capacitors across the gap.

Inconsistencies in the Ground Rules

So now, you are annoyed with the inconsistencies. We said to leave all bits of immersed metal electrically isolated when we described electrolytic corrosion and hot marinas, but then we said to connect wires and copper tape to your keel and engine for lightning and RF grounds. So what to do?
RF ground. The RF ground needs to be a ground for RF signals only. It does not need to conduct DC, and as described in "Bonding and Electrolytic Corrosion..." above, you do not want to connect another DC ground to your engine and to your keel etc.
The solution is to find a dry secure place along each of the copper RF ground tapes that are running to your engine and keel. Fasten the tape securely to an insulating piece of phenolic or to a terminal strip, cut a 1/10-inch gap across the tape, and solder several 0.15uF ceramic capacitors across the gap. These capacitors will be transparent to the RF, which will be happily grounded by the ground tape system, but they will block any DC currents from running through the RF ground system, and will avoid any resulting susceptibility to hot marina electrolytic corrosion. It is worth selecting the capacitors carefully, because they may carry a significant amount of RF current.

Lightning Ground

The lightning ground needs to be a direct DC connection to the keel or to a ground plate to handle currents due to lightning strikes. So how do we keep the keel or ground plate electrically isolated as required in "Bonding and Electrolytic Corrosion..." above?
The solution is to connect the keel or ground plate directly to the mast, but make sure the mast is not electrically connected to the boats DC ground system. If your steaming light, masthead light, tricolor, Windex light etc. are wired carefully and correctly, they each will have their own DC return wire; there should be no ground connection between their wiring and the mast itself. Make sure that this is the case.
This should also be true of your masthead instruments. The unintended DC connection between mast and DC ground is typically made by the masthead VHF whip, which connects the shield of the coax to the bracket connected to the mast. That shield also connects to the VHF radio which is DC grounded by its power connection. The easiest solution is to insert what is called a "inner-outer DC block" into the coax.
This RF device puts a capacitor in series with the center conductor, and another capacitor in series with the shield. This device is transparent to the VHF RF signals in the center conductor and shield, but blocks any DC current in either the center conductor or shield. This device can be made by a good radio technician, or purchased from radio supply houses, pre-fitted with any kind of coax connection on both ends. The commercial units look like a coax "barrel" connector. A vendor is listed at the end of the article.
Once the DC connection from the mast to the VHF is broken, check for any other connections with an ohmmeter, and straighten out any other wiring errors or unintended connections. If your metal fuel tank is also bonded to the lightning ground system (per ABYC) then make sure that it does not have DC connections either to the engine via the fuel line or to the electrical system via the fuel level sensor. A piece of approved rubber fuel hose in the fuel lines to the engine solves that connection, and a well designed fuel level sensor will not make electrical contact with the tank.
When you're done, there will be heavy conductors running from the external keel or lightning ground plate to the mast, stays, and to the metal fuel tank, but there will be no DC connections to the engine or to the yacht's electrical system. See Figure 3.

Summary

By using capacitors to block DC connections in a few key areas, it is possible to have perfect ground systems for AC, DC, RF, lightning, and corrosion, and have a boat that is immune to stray DC currents that are traveling through the water in "hot marinas."
In the old days, the technique of bonding everything together worked okay. In its defense, the "bond everything together" approach makes your boat less sensitive to electrolytic corrosion that can result from faulty wiring on your own boat. The problem is, the "bond everything" approach leaves your boat totally defenseless to wiring errors in nearby boats and nearby industry, that cause stray DC currents to run through the water.
Today the technique of bonding everything together would still work fine if your boat spent all of its time on the high seas, in remote anchorages, or in marinas that were wired perfectly and in which all of the nearby yachts were wired perfectly. Having underwater metal bonded together in crowded marina's today, however, is asking for expensive trouble. As outlined above, it is avoidable trouble. It is possible, with careful wiring and a few capacitors, to have the best of all worlds, good RF and lightning grounds, ABYC-approved DC and AC grounds, and security against electrolytic corrosion caused by hot marinas.

Data

Sailboat Specifications

  1. Hull Type
        • Fin w/transom hung rudder
  2. Rigging Type:
        • Masthead Sloop
  3. LOA:
        • 5.78 m
  4. LWL:
        • 5.24 m
  5. Beam:
        • 1.87 m
  6. S.A. (reported):
        • 14.12 m2
  7. Draft (max):
        • 0.91 m
  8. Displacement:
        • 681 kg
  9. Ballast:
        • 340 kg
  10. S.A./Disp.:
        • 18.59
  11. Bal./Disp.:
        • 49.97
  12. Disp./Len.:
        • 131.92
  13. Construction:
        • Fiber Glass
  14. Ballast Type:
        • Steel
  15. First Built:
        • 1972
  16. Last Built:
        • 1982
  17. # Built:
        • 750
  18. Builder:
        • Hunter Boats (UK)
  19. Designer:
        • Oliver Lee
  20. Sail Areas (sq m):
        •  Main 7.80, Jib 6.30, Genoa 11.10
  21.  Berths:
        •  2 to 3 
  22.  Engine: 
        • O/B
 

Sailboat Calculations

  1. S.A./Disp.:
        • 18.59
  2. Bal./Disp.:
        • 49.97
  3. Disp./Len.:
        • 131.92
  4. Comfort Ratio:
        • 11.66
  5. Capsize Screening Formula:
        • 2.15 

 Sailboat Links

  1. Designers:
  2. Builders:
  3. Associations:
  4. Related Sailboats:

Notes

A development of the SQUIB day boat with cabin added. Known as the EUROPA after 1974.
Shoal draft version draws 2.23'.
Hunter 19s built Sep 72 - Feb 74, Europas built Apr 74 - Nov 82 
 National Handicap for Cruisers (NHC) - Base List
Design  Base Number Design Year
HUNTER 19 0.822 1972