Sounding the Depth, Sea Marks and Bridge Lights

Posted by PITHOCRATES - December 11th, 2013

Technology 101

It’s Important to know both the Depth of the Water beneath you and the Hidden Dangers below the Surface

On November 10, 1975, the Great Lakes bulk ore carrier S.S. Edmund Fitzgerald sank in a powerful Lake Superior storm.  Waves of 35 feet crashed green water across her deck.  But time and again she bobbed back up from under the waves.  Until she began to lose her buoyancy.  No one knows for sure what happened but the Fitzgerald was taking on water prior to her sinking.  One theory said that she bottomed out on Six Fathom Shoal off of Caribou Island.  As she fell into the trough between two huge waves.

A fathom is 6 feet.  So six fathoms would be 36 feet.  Though the water over Six Fathom Shoal could be as shallow as 26 feet.  Which is pretty deep.  But is dangerously shallow for a ship like the Fitzgerald.  For she had a draft of 25 feet.  At best she had 11 feet (36-25) of clearance between the shoal and her hull.  Or in the worst case, 1 foot (26-25).  With the gale force winds pushing the waves as high as 35 feet that would put the trough approximately 17.5 feet (35/2) below the ‘calm’ surface level of the lake.  Which would bring the top of the shoal above the hull of the Fitzgerald.  Thus making a strong case that she bottomed out and fractured her hull and began to take on water.

The theory continues that as she took on water she settled deeper and deeper into the water.  Growing heavier.  And less buoyant.  Until a wall of water swept across her that was too great for her to shake off.  Sending her to the bottom of Lake Superior so quickly that the propeller was still spinning when the bow hit bottom.  Causing the hull to break.  With the torque of the spinning shaft rotating the stern over until she rested hull-up on the bottom.  This is only one theory of many.  People still debate the ultimate cause of her sinking.  But this theory shows the importance of knowing the depth of the water beneath you.  And the great danger of unseen objects below the surface of the water.

Ships use Sea Marks to guide them Safely through Navigable Channels

Those mariners who first crossed the oceans were some of the bravest ever to live.  For if a ship sank in the middle of the ocean chances are people never saw those sailors again.  For there’s nothing to sustain life in the middle of the ocean.  Everything you ate or drank you brought with you.  And crossed at the greatest speed possible to get to your destination before your supplies ran out.  Which was easy to do in the deep waters of the middle of the ocean.  But very dangerous when the water grew shallower.  As you approached land.  Especially for the first time.

If a ship struck a submerged object it could break up the hull and sink the ship.  Especially if you hit it at speed.  This is why they had lookouts high up in the crow’s nest looking for land.  Or indications that the water was growing more shallow.  And they would ‘heave the lead’.  Big burly men (leadsmen) would throw a lead weight on a rope as far out in front of the ship as possible.  Once the lead hit bottom they’d pull it up.  Counting the knots in the rope spaced at 6-foot intervals.  Or fathoms.  Sounding the depth of the water beneath them.  As the sea bottom raced up to the water’s surface they furled their sails to catch less wind.  And slow down.  As they approached land they would approach only so far.  And safely anchor in a safe depth of water near a promising location for a harbor.  Some sailors would then board a dinghy and row into the shallow waters.  Sounding the depth.  And making a chart.  Looking for a safe channel to navigate.  And a place suitable to build a deep-water dock.  Deep enough to sail in to and moor the large sailing vessels that would sail to and from these new lands.

Of course, we could do none of this during the night.  It may be safe to sail in the middle of the ocean at night but it is very dangerous in the shallow waters around land.  At least, for the first time.  After they built a harbor they may build a lighthouse.  A tall building with a beacon.  To guide ships to the new harbor in the dark.  And even add a fog horn to guide ships in when fog obscures the light.  This would bring ships towards the harbor.  But they needed other navigational aids to guide them through a safe channel to the dock.  As time passed we made our navigational aids more advanced.  As well as our ships.  Today a ship can enter a harbor or river in the black of night safely.  Thanks to sea marks.

If Ships wander just Inches off their Course the Results can be Catastrophic

Landmarks are navigational aids on land.  Such as a lighthouse.  While a sea mark is a navigational aid in the water.  Typically a buoy.  A buoyant vessel that floats in the water.  But held in place.  Typically with a chain running from the bottom of the buoy to an anchorage driven into the bottom of the water channel.  Holding it in place to mark the edge of the navigable channel.  In North America we use the colors green and red to mark the channel.  With the “3R” rule “Red Right Returning.”  Meaning a ship returning from a larger body of water to a smaller body of water (and ultimately to a dock) would see red on their right (starboard).  And green on their left (port).  If you’re leaving dock and heading to open water the colors would be the reverse.

As ships move up river the safe channel narrows.  And there are bridges to contend with.  Which compounds the problem of shallow waters.  Fixed bridges will have red lights on piers rising out of the water.  And a green light over the center of the safe channel.  A vertical lift span bridge or a double leaf (lift) bascule bridge will have red lights at either end.  And red lights over the center of the channel when these bridges are closed.  When the center span on a lift bridge is open there will be a green light marking the center of the channel on the lifted center span.  Showing the center of the channel and the safe height of passage.  When the bascule bridge is open there will be a green light on the tip of each open leaf.  Showing the outer edges of the safe channel.

Ships are massive.  And massive things moving have great momentum (mass multiplied by velocity).  The bigger they are and the faster they go the harder it is to stop them.  Or to turn them.  Which means if they wander out of that safe channel they will probably hit something.  And cause great damage.  Either to the ship.  Or to the fixed structures along the waterway.  Like on an Alabaman night.  When a river barge made a wrong turn in poor visibility and entered an un-navigable channel.  Striking a rail bridge.  Pushing the bridge out of alignment.  But not enough to break the welded rail.  Which left the railroad block signal green.  Indicating the track was clear ahead.  The river pilot thought that one of the barges had only run aground.  And was oblivious to what he did.  And when Amtrak’s Sunset Limited sped through and hit that kink in the track it derailed.  Killing 47 people.  About twice the loss of life when the Fitzgerald sank.  Showing the importance of navigation charts, sea marks and bridge lights.  For if ships wander just inches off their course the results can be catastrophic.

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Archimedes’ Principle, Buoyancy, Spar Deck, Freeboard, Green Water, Bulkheads, Watertight Compartments, RMS Titanic and Edmund Fitzgerald

Posted by PITHOCRATES - January 2nd, 2013

Technology 101

(Originally published April 4th, 2012)

The Spar Deck or Weather Deck is Where you Make a Ship Watertight

Let’s do a little experiment.  Fill up your kitchen sink with some water.  (Or simply do this the next time you wash dishes).  Then get a plastic cup.  Force the cup down into the water with the open side up until it rests on the bottom of the sink.  Make sure you have a cup tall enough so the top of it is out of the water when resting on the bottom.  Now let go of the cup.  What happens?  It bobs up out of the water.  And tips over on its side.  Where water can enter the cup.  As it does it weighs down the bottom of the cup and lifts the open end out of the water.  And it floats.  Now repeat this experiment.  Only fill the plastic cup full of water.  What happens when you let go of it when it’s sitting on the bottom of the sink?  It remains sitting on the bottom of the sink.

What you’ve just demonstrated is Archimedes’ principle.  The law of buoyancy.  Which explains why things like ships float in water.  Even ships made out of steel.  And concrete.  The weight of a ship pressing down on the water creates a force pushing up on the ship.  And if the density of the ship is less than the density of the water it will float.  Where the density of the ship includes all the air within the hull.  Ships are buoyant because air is less dense than water.  If water enters the hull it will increase the density of the ship.  Making it heavier.  And less buoyant.  As water enters the hull the ship will settle lower in the water.

The spar deck or weather deck is where you make a ship watertight.  This is where the hatches are on cargo ships.  We call the distance between the surface of the water and the spar deck freeboard.  A light ship doesn’t displace much water and rides higher in the water.  That is, it has greater freeboard.  With less ship in the water there is less resistance to forward propulsion.  Allowing it to travel faster.  However, a ship riding high in the water is much more sensitive to wave action.  And more susceptible to rolling from side to side.  Increasing the chance of rolling all the way over in heavy seas.  (Interestingly, if the ship stays watertight it can still float capsized.)  So ship captains have to watch their freeboard carefully.  If the ship rides too high (like an empty cargo ship) the captain will fill ballast tanks with water to lower the ship in the water.  By decreasing freeboard the ship is less prone to wave action.  But by lowering the spar deck closer to the surface of the water bigger waves can crash over the spar deck.  Flooding the spar deck with ‘green water’.  Common in a storm with high winds creating tall waves.  As long as the spar deck is watertight the ship will stay afloat.  And the solid water that washes over the spar deck will run off the ship and back into the sea.

The Titanic and the Fitzgerald were Near Unsinkable Designs but both lost Buoyancy and Sank

Improvements in ship design have made ships safer.  Steel ships can take a lot of damage and still float.  Ships struck by torpedoes in World War II could still float even with a hole below their waterline thanks to watertight compartments.  Where bulkheads divide a ship’s hull.  Watertight walls that typically run up to the weather deck.  Access though these bulkheads is via watertight doors.  These are the doors that close when a ship begins to take on water and the captain orders, “Close watertight doors.”  This contains the water ingress to one compartment allowing the ship to remain buoyant.  If it pitches down at the bow or lists to either side they can offset this imbalance with their ballast tanks.  Emptying the tanks where the ship is taking on water.  And filling the tanks where it is not.  To level the ship and keep it seaworthy until it reaches a safe harbor to make repairs.

They considered RMS Titanic unsinkable because of these features.  But they didn’t stop her from sinking on a calm night in 1912.  Why?  Two reasons.  The first was the way she struck the iceberg.  She sideswiped the iceberg.  Which cut a gash below the waterline in five of her ‘watertight’ compartments.  Which basically removed the benefit of compartmentalization.  They could not isolate the water ingress to a single compartment.  Or two.  Or three.  Even four.  Which she might have survived and remained afloat.  But water rushing into five compartments was too much.  It pitched the bow down.  And as the bow sank water spilled over the ‘watertight’ bulkheads and began flooding the next compartment.  Even ones the iceberg didn’t slash open.  As water poured over these bulkheads and flooded compartment after compartment the bow sank deeper and deeper into the water.  Until the unsinkable sank.  The Titanic sank slowly enough to rescue everyone on the ship.  She just didn’t carry enough lifeboats.  For they thought she was unsinkable.  Because of this lack of lifeboats 1,517 died.  Of course, having enough lifeboats doesn’t guarantee everyone will survive a sinking ship.

The Edmund Fitzgerald was the biggest ore carrier on the Great Lakes during her heyday.  These ships could take an enormous amount of abuse as the storms on the Great Lakes could be treacherous.  Like the one that fell on the Fitzgerald one November night in 1975.  When 30-foot waves hammered her and her sister ship the Arthur Andersen.  No one knows for sure what happened that night but some of the clues indicate she may have bottomed out on an uncharted shoal.  For she lost her handrails indicating that the ship may have hogged (where the bow and stern bends down from the center of the ship held up by that uncharted shoal).  The handrails were steel cables under tension running around the spar deck.  If the ship hogged this would have stretched the cable until it snapped.  She had green water washing across her deck.  Lost both of her radars.  A vent.  Maybe even a hatch cover.  Whatever happened she was taking on water.  A lot of it.  More than her pumps could keep up with.  Causing a list.  And the bow to settle deeper in the water.  Waves crashed over her bow as well as the Andersen’s.  The ships disappeared under the water.  Then reemerged.  As they design ships to do.  Then two massive waves rocked the Andersen.  She was following the Fitzgerald to help her navigate by the Andersen’s radar.  So these two waves had hit the Fitzgerald first.  The Fitzgerald had by this time taken on so much water that she lost too much freeboard.  When she disappeared under these two waves she never came back up.  It happened so fast there was no distress call.  The ship was longer than the lake was deep.  So her screw was still propelling the ship forward when the bow stuck the bottom.  She had lifeboat capacity for all 29 aboard.  But the ship sank too fast to use them.  Or even for the Andersen to see her as she sailed over her as she came to a rest on the bottom.

Our Ships have never been Safer but Ship Owners and Merchants still need to Protect their Wealth with Marine Insurance

We build bigger and bigger ships.  And it’s amazing what can float considering how heavy these ships can be.  But thanks to Archimedes’ principle all we have to do to make the biggest and heaviest ships float is too keep them watertight.  Keeping them less dense than the water that makes them float.  Even if we fail here due to events beyond our control we can isolate the water rushing in by sealing watertight compartments.  And keep them afloat.  So our ships have never been safer.  In addition we have far more detailed charts.  And satellite navigation to carefully guide us to our destination.  Despite all of this ships still sink.  Proving the need for something that has changed little since 14th century Genoa.  Marine insurance.  Because accidents still happen.  And ship owners and merchants still need to protect their wealth.

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Archimedes’ Principle, Buoyancy, Spar Deck, Freeboard, Green Water, Bulkheads, Watertight Compartments, RMS Titanic and Edmund Fitzgerald

Posted by PITHOCRATES - April 4th, 2012

Technology 101

The Spar Deck or Weather Deck is Where you Make a Ship Watertight

Let’s do a little experiment.  Fill up your kitchen sink with some water.  (Or simply do this the next time you wash dishes).  Then get a plastic cup.  Force the cup down into the water with the open side up until it rests on the bottom of the sink.  Make sure you have a cup tall enough so the top of it is out of the water when resting on the bottom.  Now let go of the cup.  What happens?  It bobs up out of the water.  And tips over on its side.  Where water can enter the cup.  As it does it weighs down the bottom of the cup and lifts the open end out of the water.  And it floats.  Now repeat this experiment.  Only fill the plastic cup full of water.  What happens when you let go of it when it’s sitting on the bottom of the sink?  It remains sitting on the bottom of the sink.

What you’ve just demonstrated is Archimedes’ principle.  The law of buoyancy.  Which explains why things like ships float in water.  Even ships made out of steel.  And concrete.  The weight of a ship pressing down on the water creates a force pushing up on the ship.  And if the density of the ship is less than the density of the water it will float.  Where the density of the ship includes all the air within the hull.  Ships are buoyant because air is less dense than water.  If water enters the hull it will increase the density of the ship.  Making it heavier.  And less buoyant.  As water enters the hull the ship will settle lower in the water.

The spar deck or weather deck is where you make a ship watertight.  This is where the hatches are on cargo ships.  We call the distance between the surface of the water and the spar deck freeboard.  A light ship doesn’t displace much water and rides higher in the water.  That is, it has greater freeboard.  With less ship in the water there is less resistance to forward propulsion.  Allowing it to travel faster.  However, a ship riding high in the water is much more sensitive to wave action.  And more susceptible to rolling from side to side.  Increasing the chance of rolling all the way over in heavy seas.  (Interestingly, if the ship stays watertight it can still float capsized.)  So ship captains have to watch their freeboard carefully.  If the ship rides too high (like an empty cargo ship) the captain will fill ballast tanks with water to lower the ship in the water.  By decreasing freeboard the ship is less prone to wave action.  But by lowering the spar deck closer to the surface of the water bigger waves can crash over the spar deck.  Flooding the spar deck with ‘green water’.  Common in a storm with high winds creating tall waves.  As long as the spar deck is watertight the ship will stay afloat.  And the solid water that washes over the spar deck will run off the ship and back into the sea.

The Titanic and the Fitzgerald were Near Unsinkable Designs but both lost Buoyancy and Sank

Improvements in ship design have made ships safer.  Steel ships can take a lot of damage and still float.  Ships struck by torpedoes in World War II could still float even with a hole below their waterline thanks to watertight compartments.  Where bulkheads divide a ship’s hull.  Watertight walls that typically run up to the weather deck.  Access though these bulkheads is via watertight doors.  These are the doors that close when a ship begins to take on water and the captain orders, “Close watertight doors.”  This contains the water ingress to one compartment allowing the ship to remain buoyant.  If it pitches down at the bow or lists to either side they can offset this imbalance with their ballast tanks.  Emptying the tanks where the ship is taking on water.  And filling the tanks where it is not.  To level the ship and keep it seaworthy until it reaches a safe harbor to make repairs.

They considered RMS Titanic unsinkable because of these features.  But they didn’t stop her from sinking on a calm night in 1912.  Why?  Two reasons.  The first was the way she struck the iceberg.  She sideswiped the iceberg.  Which cut a gash below the waterline in five of her ‘watertight’ compartments.  Which basically removed the benefit of compartmentalization.  They could not isolate the water ingress to a single compartment.  Or two.  Or three.  Even four.  Which she might have survived and remained afloat.  But water rushing into five compartments was too much.  It pitched the bow down.  And as the bow sank water spilled over the ‘watertight’ bulkheads and began flooding the next compartment.  Even ones the iceberg didn’t slash open.  As water poured over these bulkheads and flooded compartment after compartment the bow sank deeper and deeper into the water.  Until the unsinkable sank.  The Titanic sank slowly enough to rescue everyone on the ship.  She just didn’t carry enough lifeboats.  For they thought she was unsinkable.  Because of this lack of lifeboats 1,517 died.  Of course, having enough lifeboats doesn’t guarantee everyone will survive a sinking ship.

The Edmund Fitzgerald was the biggest ore carrier on the Great Lakes during her heyday.  These ships could take an enormous amount of abuse as the storms on the Great Lakes could be treacherous.  Like the one that fell on the Fitzgerald one November night in 1975.  When 30-foot waves hammered her and her sister ship the Arthur Andersen.  No one knows for sure what happened that night but some of the clues indicate she may have bottomed out on an uncharted shoal.  For she lost her handrails indicating that the ship may have hogged (where the bow and stern bends down from the center of the ship held up by that uncharted shoal).  The handrails were steel cables under tension running around the spar deck.  If the ship hogged this would have stretched the cable until it snapped.  She had green water washing across her deck.  Lost both of her radars.  A vent.  Maybe even a hatch cover.  Whatever happened she was taking on water.  A lot of it.  More than her pumps could keep up with.  Causing a list.  And the bow to settle deeper in the water.  Waves crashed over her bow as well as the Andersen’s.  The ships disappeared under the water.  Then reemerged.  As they design ships to do.  Then two massive waves rocked the Andersen.  She was following the Fitzgerald to help her navigate by the Andersen’s radar.  So these two waves had hit the Fitzgerald first.  The Fitzgerald had by this time taken on so much water that she lost too much freeboard.  When she disappeared under these two waves she never came back up.  It happened so fast there was no distress call.  The ship was longer than the lake was deep.  So her screw was still propelling the ship forward when the bow stuck the bottom.  She had lifeboat capacity for all 29 aboard.  But the ship sank too fast to use them.  Or even for the Andersen to see her as she sailed over her as she came to a rest on the bottom.

Our Ships have never been Safer but Ship Owners and Merchants still need to Protect their Wealth with Marine Insurance

We build bigger and bigger ships.  And it’s amazing what can float considering how heavy these ships can be.  But thanks to Archimedes’ principle all we have to do to make the biggest and heaviest ships float is too keep them watertight.  Keeping them less dense than the water that makes them float.  Even if we fail here due to events beyond our control we can isolate the water rushing in by sealing watertight compartments.  And keep them afloat.  So our ships have never been safer.  In addition we have far more detailed charts.  And satellite navigation to carefully guide us to our destination.  Despite all of this ships still sink.  Proving the need for something that has changed little since 14th century Genoa.  Marine insurance.  Because accidents still happen.  And ship owners and merchants still need to protect their wealth.

www.PITHOCRATES.com

Share

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