engine room – Page 2 – NOAA Teacher at Sea Blog

July 6, 2022July 6, 2022

Oktay Ince: Reporting from the Ship Engine Room, June 28, 2022

NOAA Teacher At Sea

Oktay Ince

Aboard NOAA Ship Thomas Jefferson

June 20- July 1, 2022

Mission: Hydrographic Survey

Geographic Area of Cruise: Lake Erie

Date: Tuesday, June 28, 2022

Latitude: 41° 36′ 5 N

Longitude: 81° 30.7′ W

Altitude: 138 m

Weather Data from Bridge

Wind Speed: 1.6 kts

Surface Water Temperature: 22.2 °C

Air Temperature (Dry Bulb Temperature): 18.2 °C

Wet Bulb Temperature: 12.7 °C

Relative Humidity: 55 %

Barometric Pressure: 10.24 in

Science blog

Today, I am going to share some science and technology information from the engineering department. The engine room is located on the two decks below the main deck. The engineers have many tasks and responsibilities on the ship. I am going to share some of the main ones.

The first responsibility is to make sure the ship engine is working properly. Engineers work around the clock to make sure that in the case of an emergency, they can act quickly. As you may imagine, the ship has a huge engine with many cylinders. I was very lucky to see the engine before and after it was working. When we anchored our ship near the Rocky River, we stopped the engine. The ship’s electric power is powered by three diesel generators. This powers various systems in the ship such as AC, heating, computers, refrigerators etc.

When we were ready to get underway from anchorage for our next journey on Lake Erie, I thought it was a good idea to observe the engineering department and see how they start and operate the engine. Anyway, I went down there about 20 minutes before our departure. Engineers were busy as bees around the machines touching, clicking, opening/closing valves. There was a constant movement. They all know what to do, including me. My job is to watch how the ship engine operates. I was roaming around to see what would be the best place for me to videotape the moment when they start the engine. Luckily, I found one, and “loudly” waited there. Oh, I forgot to mention. Before you enter this place, you have to have hearing protection. I put my ear plugs in and on top I put on ear muffs. I was told the noise was going to be so loud. Once they checked all the parts, it was time to start the engine. All the pistons started to move, and it reminded me of the sound of my mom’s old sewing machine, where there was constant ticking, clicking sounds. It was fascinating to witness that moment.

Starting the ship’s engine

The ship engine is fully operational

Oktay and an engineer pore over notebooks at a table in the engine room — Learning about engineering concepts

four computer monitors in a line, above a control panel — Learning about engineering concepts

Hear this! Every important part in the ship has a back up. Some of them even have third, or fourth back up. For example, when I went to the bridge to learn about how they control the ship up there, the first thing they told me was that everything has a back up. If one screen shows a map, here is the same map on a different screen. So the engine also has a back up, an auxiliary engine, in the case of an emergency it would quickly kick in. However, the auxiliary engine does not have the same power as the main engine. Its role is to keep the ship out of danger, until the main engine issue is resolved, or the ship can pull into port. There was also a steering room down in the engine room in case the deck loses its steering control, they can manually steer the ship down below. Isn’t that cool! For that purpose, there is always an engineer on watch who monitors the steering gear around the clock. Remember, the ship works 24 hours.

Besides engines, the ship has a water treatment system down in the engine room. To be honest, this was the moment where my excitement made its zenith point. You would understand this when you read what I am about to say on this. The water treatment system consists of many tubes which contain membranes to filter the water, desalinate it, and make it ready to drink. The system uses the concept of reverse osmosis (RO) to make drinkable water out of any water systems, even the ocean. However, I must note that even though the technology allows you to make the water, engineers make decisions whether to make the water based on several factors. First, it is preferred to be at least 12 nautical miles offshore in open water. This is because the water is less likely to have pollutants that could clog the filters, which would quickly lead to other issues for engineers to deal with. Deep water is also preferable for similar reasons; sediment, mud, and sand that can be churned up in shallow waters is another way for the filters to be clogged. In the case of Lake Erie, engineers decided to NOT make water because we are working relatively close to shore, and would not be an efficient use of resources. This is because the ship fills all its potable water tanks (~50,000 gallons!) in port using municipal water from the City, which is enough to supply the ship for several weeks. The ship uses ~1,500 gallons of freshwater a day! But remember, that is for a 30 person crew – eating/drinking, showering, cleaning, etc. Long story short, we have sufficient water in the tanks for the duration of our mission. Therefore, there is no need to make more water.

large pipes in an array; tubing; wires — Reverse Osmosis (RO) System

Okay, let’s go back to the concept of desalination by using reverse osmosis. It sounds complicated, right? It is quite simple in principle. To be honest, even myself, who trained in biology both during my bachelors and graduate school, thought that so many people in the world can’t use ocean/sea water to solve the water crisis because the technology is very “expensive” and that is not an option. On the contrary, it is a very simple science concept and it is relatively cheap when you think of the product and the benefits it has. However, why is it still not accessible to everyone in the world? I guess the question will stick in my mind from now on.

Let’s get back to the science concept of osmosis and reverse osmosis. In osmosis, you have a semi-permeable membrane where water moves freely without energy input to the system until the two sides of the membrane have equal number of water molecules. The osmotic pressure to the membrane is equal in both sides due to having the same amount of water molecules on both sides of the membrane. Cells in our body are semi-permeable and water can go in and out of the cell based on the concentration of solutes in both sides of the membrane. You can see the concept of osmosis in every biological system. We have even applied the concept of osmosis since ancient times to preserve foods by dehydration with salt or sugar such as jams, pickles, pastrami and so on. The microorganisms that make food go bad can’t survive without the presence of water. That’s why honey is the only natural product that never goes bad due to its high concentration of substances.

In reverse osmosis, the movement involves water molecules passing through a higher substance concentration (sea water) to a lower substance concentration. As you can see it is the opposite of osmosis. Water should move the other way around. How do we achieve that? When we apply a pressure high enough to the point where it is higher than the osmotic pressure to the saline water, it causes fresh water to flow through the membrane while holding back the salt. The higher the applied pressure above the osmotic pressure, the higher the rate of fresh water transports across the membrane. Here you have freshwater on the other side of the membrane. Pure and simple. Based on the membrane you use in the system, it also traps all the other pollutants as well. Mind blowing! This is how the ship makes its own freshwater.

So far, we talked about engines and the RO system of the ship. We also have generators down there. They are the ones that generate electricity by using fuel. The ship generally runs on one generator at a time, but may require two during some operations. However, the ship has three generators on board in case others fail.

I guess I’ll leave it here and let you learn more about the science and technology of ship engines and RO systems on your own!

Personal Log

As educators, we often fail to connect our discipline to other disciplines. We usually don’t understand how one concept has many other applications. If being a Teacher at Sea on Thomas Jefferson taught me one thing, it’s that science concepts intervene with other disciplines. If students don’t see these connections, or how the concepts they learned apply to different circumstances, then I believe they fail to see the bigger picture. As a result, “true” learning will never be achieved.

I was a scientist by training before I became an educator, and of course I know what osmosis is in biological systems. However, I must confess that I did not see the applications of osmosis this far, not even during my graduate studies. There has not been a single educator who showed me the concept of osmosis in this perspective. I don’t blame them. They probably haven’t had a chance to learn that way too. All I remember is the “U” shaped diagram with a semi-permeable membrane in the middle, and each side having different concentrated solutions, which shows how the water moves freely. And then they explained how once it reached equilibrium, both sides of the membrane had equal concentration. From there, they talked about different solution types, energy requirements of moving molecules from one side to another, etc. I guess you all remember this from your biology or related courses.

From this teaching, did you ever think about how this science concept is used in different applications? Like in this case, reverse osmosis to make freshwater from seawater. If you did, lucky you! You are one of those lucky ones- I didn’t have that opportunity. At least, I did not think about it at the moment. All I worried about was learning the concept and moving on. I guess my teachers at that time had the same “vision” as me. Teach the concept, test it with multiple choice questions and then move on thinking that students learned. When those students come across the same concept in different settings, they mostly fail. The justification of the educator would be like, “I don’t know why they failed. I taught them the materials and had great scores. They must have had a bad day during the testing.” Yeah! Yeah! Yeah! I know those.

Sorry for my long thoughts about our educational system. We really should, at least, teach science concepts to our classroom through its real world application. Only then, would they appreciate the power of the science concept they are learning, which could open a lot more creative ideas on their own, leading to innovation. These were thoughts that sparked my mind thanks to reverse osmosis (RO) system technology on the ship.

Another important thing that came to mind while I was down in the engine room was the importance of teamwork, and how important it is to always have a back up. We all know the importance of teamwork, and how the members of each team are equally important. But when it comes to teaching teamwork to the kids who have not experienced real teamwork, do they really understand its importance? If we want our students to work as a team in our classrooms, we need to design our lessons in a way that if one of the team members fails to complete a task assigned to them, the whole task fails along with it. Once they know this, I think the true understanding of teamwork will prevail to the students.

These were the thoughts that I have been contemplating while witnessing all the cool things I saw in the engine room. Who knows how students would be impacted if they saw these things?

Did you know?

Waves in Lake Erie are mainly caused by winds because of its shallow nature. If those waves move away from their generation zone, they become more regular and then are referred to as swells.

August 26, 2019

Linda Kurtz: Women in STEM-(at Sea): Meet Allyson Causey, August 23, 2019

NOAA Teacher at Sea

Linda Kurtz

Aboard NOAA Ship Fairweather

August 12-23, 2019

Mission: Cascadia Mapping Project

Geographic Area of Cruise: Northwest Pacific

Date: 8/23/2019

engineer Allyson Causey — Allyson Causey – Engineer aboard NOAA Ship Fairweather

Women in STEM – Engineering

Meet Allyson Causey! Engineer aboard NOAA ship Fairweather

Job Title:

3^rd Assistant Engineer

Time in current position:

2 ½ months aboard Fairweather

Education and/or Specialized training:

Texas A & M- Bachelor of Science in Marine Engineering Technology

Wage Mariners-civil service federal employee (nonmilitary)

Do you have any plans for future education?

Currently investigating at master’s programs in Nuclear Engineering

Engineering aboard Fairweather

Generator
Boiler
Reverse Osmosis Machine
Reverse Osmosis Machine
Controller
Main engine
Air compressor
Fire main
Marine Sanitation Device

How did you find out about your current position at NOAA?

I met a NOAA recruiter at a job fair at Texas A & M, submitted resume and 3 weeks later I got the call! After that the lengthy background check and physical for Federal employees, I came to work at NOAA aboard Fairweather.

1) When you were a child, what was your dream career?

I wanted to be an astronaut when I was young. I looked into aeronautical engineering and attended a Federal Service academy – the United States Merchant Marine Academy. My Dad is an engineer and contractor, so I grew up on job sites and always had the mindset of math and science. I knew my career would be something in the STEM field

2) What was your favorite subject in school?

My favorite class was differential equations. Why I like engineering so much is everything is one big puzzle, and differential equations is like one big puzzle.

3) Why is what you do important to on the ship?

Engineers on ships are essentially the lifeblood of the ship, we keep the ship moving. We are the electricians, plumbers, the mechanics, and even the firefighters. The ship can’t go anywhere without engineers!

4) What would you tell an elementary school student about your work that is important to you?

I enjoy solving the puzzles. When something goes wrong, I enjoy finding out why something is not working and then solving the problem. That is what is so rewarding — figuring out what is wrong and fixing it!

5) Where do you do most of your work?

In the engine room. That’s where I spend my 8-hour shifts. The engineering room is on A & B deck — the 2 bottom-most levels of the ship. That is where most of the mechanisms that run the ship are located.

6) What tool do you use in your work that you could not live without?

A crescent wrench! Mine is handy because it can measure and tell you the exact size of the nut which makes things a lot easier!

7) If you could invent any tool to make your work more efficient and cost were no object, what would it be and why?

I would invent a tool that could reach bolts at odd angles. Like a magnetic wrench that could adjust to the size bolt head you need and could bend around the odd angles and apply torque when I need it.

8) What part of your job with NOAA did you least expect?

I never expected to be in Alaska!

9) How could teacher help students understand and appreciate NOAA engineering opportunities?

I think it would be valuable to have better understanding of what we engineers do! It’s a really cool job, with a really good salary, and very few people know there are positions like this available.

10) What is your favorite part of your day when you are working and why?

Every day is a little different, you are never doing the same thing over and over again. Something is always breaking and needs immediate attention.

11) What was your favorite book growing up?

My favorite book series when I was growing up was Junie B. Jones! I come from Florida and loved Jacques Cousteau. He inspired me to become a scuba diver at 17.

12) What do you think you would be doing if you were not working for NOAA?

I would be still be working on a boat!

13) Do you have an outside hobby?

I love camping and hiking, I’ve hiked 40 miles of the Appalachian Trail and would like to hike the rest!

14) What is your favorite animal?

Manta Rays!

15) If you could go back in time and tell your 10 year old self something, what would it be?

Take more math and science classes! It really helps you get ahead in life!

Did you know?

All of the electrical power on Fairweather comes from the generators, not the engines. It’s a common misconception!

Want to learn more about careers like and Allyson Causey’s and NOAA resources? See the resource links below:

NOAA ENGINEERING

US MERCHANT MARINES ACADEMY

NOAA Teacher Ready Resources

July 22, 2019

Erica Marlaine: What’s an Oiler? And Where Does All That Water Come From? July 14, 2019

NOAA Teacher at Sea

Erica Marlaine

Aboard NOAA Ship Oscar Dyson

June 22 – July 15, 2019

Mission: Pollock Acoustic-Trawl Survey

Geographic Area of Cruise: Gulf of Alaska

Date: July 14, 2019

Weather Data from the Bridge:

Latitude: 56º 58.03 N
Longitude: 151º 26.26W
Wind Speed: 17 knots
Wind Direction: 120º
Air Temperature: 13º Celsius
Barometric Pressure: 1010.5 mb
Depth of water column 565 m
Surface Sea Temperature: 12.9º Celsius

Science & Technology Log

Ever heard of oilers? I hadn’t until I got to know Daniel Ruble, a member of the engineering crew on the NOAA Ship Oscar Dyson.

Daniel is originally from Chicago but now calls Virginia home. After serving our country for 20 years in the Marine Corps, a friend mentioned that it was always good to have a Mariner’s Document (a license from the Coast Guard) “just in case.” Years later, he finally decided to put it to use, and got a job with NOAA in 2014. He started doing deck work, but his interest and experience in mechanical engineering eventually led him to the NOAA engineering crew. He is what they call an “oiler.” Oilers maintain, clean, and oil the ship’s engine, including the motors, gears, and compressors. Daniel has worked on every class of NOAA vessel (Oceanographic and Atmospheric Research, Charting and Hydrographic, and Fisheries Research) and all but one of the NOAA ships.

Daniel and the other engineers onboard the NOAA Ship Oscar Dyson are easy to spot as they often have bulky, protective ear coverings either on or nearby. That is because the engine room is VERY LOUD. When I was given a tour, I was first given ear coverings, and much of the explanation about what I was seeing had to come later as it was too difficult to hear each other. I was told that seeing the engine room is like looking under the hood of your car. Just imagine your car’s engine magnified 1000 times.

The engineering crew is responsible for all of the internal systems of the ship. Without them, the ship wouldn’t run, and there would be no power or water. The engineering room actually makes all of the water we use onboard by distilling saltwater into potable (drinkable) water. Here’s how it works.

Saltwater is boiled using energy from the ship itself. Hot engine steam is passed through an evaporation unit, causing the saltwater to boil. The saltwater steam rises and then travel through a water separator which prevents any droplets of saltwater from passing through. After the steam becomes pure water, it is then carried away by a distillate pump. It is then safe for drinking and showering.

Each of the two evaporators on the NOAA Ship Oscar Dyson can distill between 600-900 gallons of water per day, depending upon how fast the ship is moving. On an average day, the ship uses 800-1000 gallons!

July 22, 2019

Erica Marlaine: Bear Onboard, July 12, 2019

NOAA Teacher at Sea

Erica Marlaine

Aboard NOAA Ship Oscar Dyson

June 22 – July 15, 2019

Mission: Pollock Acoustic-Trawl Survey

Geographic Area of Cruise: Gulf of Alaska

Date: July 12, 2019

Weather Data from the Bridge:

Latitude: 57º 9.61 N
Longitude: 152º 20.99W
Wind Speed: 15 knots
Wind Direction: 210 º
Air Temperature: 12º Celsius
Barometric Pressure: 1013 mb
Depth of water column 84 m
Surface Sea Temperature: 12º Celsius

Welcome to a tour of the NOAA Ship Oscar Dyson.

Your tour guide today is the Room 11 Bear.

Allow me to explain.

When I am not a Teacher at Sea on the NOAA Ship Oscar Dyson, I am the special education preschool teacher in Room 11 at Nevada Avenue Elementary School in Canoga Park, California. My classroom has a classroom bear (made of construction paper) that “hides” every night when the students go home. In the beginning of the year, he is sort of easy to find, but as the year progresses, he is harder and harder to find. By the end of the year, only a paw or an ear might be showing!

The first thing my students want to do every morning is look for the bear. When they find it, they excitedly explain where it is. Speech and language are things we work on in class all the time, and the bear gives us something fun to talk about! For some students, a single word might be the goal. Other students may be working on putting a few words together, or even enough to make a sentence. It’s also a great time for them to learn prepositional words or phrases to describe where the bear is hiding, such as next to, under, beneath, or on top of.

Now it’s YOUR turn. I hope you have fun touring the NOAA Ship Oscar Dyson with the Room 11 Bear and finding him in the photos where he decided to hide in a tricky spot. He is in EVERY picture.

bear in captain's chair — Commanding Officer Bear up on the Bridge (the part of the ship above the weather deck which houses the command center). I also spy a snack that is a favorite of some students in Room 11.

bear charting the course — Bear charting our course on the Bridge

bear steering — Steering the NOAA Ship *Oscar Dyson* (up on the Bridge)

bear lookout — Binoculars are used to check for whales or other boats before the trawl nets are put out.

bear in the galley — Food is cooked in the galley (the nautical term for kitchen)

bear in the mess hall — This is the mess (the nautical term for eating place) where all of the delicious meals are served.

bear in gym — One of the two gyms onboard the NOAA Ship *Oscar Dyson*

bear at fire station — There are “fire stations” onboard in case of an emergency

bear in jackets — This is where we put on our waterproof rain gear and high boots before entering the fish lab

bear on rubber gloves — High rubber gloves are worn so that we stay somewhat clean and to protect our hands as we use sharp tools and touch jellyfish or pointy quills

bear in acoustics lab — Lastly, a visit to the acoustics lab, where the scientists read and analyze the data from the echo sounders and determine when and where to drop the trawl nets.

June 6, 2019

Jill Bartolotta: Start Your Engines, June 1, 2019

NOAA Teacher at Sea

Jill Bartolotta

Aboard NOAA Ship Okeanos Explorer

May 30 – June 13, 2019

Mission: Mapping/Exploring the U.S. Southeastern Continental Margin and Blake Plateau

Geographic Area of Cruise: U.S. Southeastern Continental Margin, Blake Plateau

Date: June 1, 2019

Weather Data:

Latitude: 28°19.3’ N

Longitude: 079°21.6’

Wave Height: 1-2 feet

Wind Speed: 11 knots

Wind Direction: 195

Visibility: 10 nautical miles

Air Temperature: 28°C

Barometric Pressure: 1012.5

Sky: Broken

Making the Engines Run

Engines on this ship are run with marine grade diesel. Before the diesel can be put through the engine it must be cleaned of any impurities. A centrifuge system is used to spin the diesel at a very fast pace in a circle. As the diesel spins any impurities are flung out leaving behind the purified fuel. If the fuel is not purified before it is put through the engines, they will gunk up and not function properly. NOAA Okeanos Explorer has 4 engines. Currently we are running 3 of them and the fourth one is the backup. There is also a fifth generator that can serve as a backup if needed. There are roughly 180,000 gallons of diesel on the ship and roughly 2,200 gallons of fuel are used per day. In order to make the engine work, air in the engine is compressed causing the air to heat up. Then you spray fuel into the compressed air and the heat of their air causes an explosion leading to the process of combustion. In order to determine if complete combustion is occurring and the engine fuel is clean of impurities you look at the exhaust. If the exhaust is clear it means you are seeing full combustion and the fuel is clean. If the exhaust is not clean, black for example, it means that combustion is not complete or the fuel is dirty.

Fuel purification centrifuge — The fuel purification centrifuge system. If you look closely you can see a pink liquid, purified diesel.

Cooling the Engines

The engines must run at a temperature below 200°F. When these engines run they create heat so to keep them at a temperature under 200°F you need to cool them off using a heat exchanger. A heat exchanger is a series of pipes that run hot substances past cooler substances. These substances do not come into contact with one another, but are piped past one another. The heat transfers to the cooler substance through the series of pipes thus cooling the previously hot substance. On this ship, oil is used to lubricate the pistons on the engine, but it also serves a coolant. The oil is then cooled via freshwater called jacket water and the freshwater is cooled via seawater taken from the ocean. The ocean surface water is 74°F when it enters the ship and leaves the ship at roughly 84°F.

However where does this heat go? The first law of thermodynamics, The Law of Conservation of Energy, tells us that energy cannot be created or destroyed, only transferred or converted. So why not convert this heat energy into some of use? Well guess what. The engineers on Okeanos Explorer do just that. Some of the heat goes into the seawater used to cool the jacket water and some of the heat is used in the desalination system.

Remember we left off with desalination in the previous blog. They use the heat coming off the engines to heat the saltwater, evaporate it, and retrieve the freshwater. However, if you remember these engines must run below 200°F and in order to boil water you must be at a temperature of 212°F. I know many of you are probably thinking salt in water actually lowers the boiling point, but really the opposite is true. Salt actually increases the temperature needed to boil water. However, it is minimal so it won’t affect your pasta too much. Feel free to add that pinch of salt like a true chef.

In order to boil water with 200°F of temperature or less we need to change the pressure of the system. This is done through a vacuum that decreases the pressure in the system allowing water to boil at a lower temperature. It is similar to when you go hiking in the mountains (less pressure than when you are at sea level) and go to boil water. It boils quicker because less heat is needed since the pressure is lower. So by changing the pressure in the system to one that would be seen at a higher altitude, engineers are able to use the heat from the engines to boil the salt water on the ship, allowing us to have access to freshwater for drinking, bathing, and cooking purposes. Pretty ingenious right?

Maintaining Balance

Now hopefully you were paying attention in the first paragraph when I talked about how much fuel is on board and how much is used each day. As fuel is used, the weight on the ship will change affecting stability. A ship with weight is more stable in the water than a ship will little to no weight. Therefore as fuel weight is lost it must be replaced. One gallon of diesel weighs approximately 7 pounds. So if we are using 2200 gallons a day we are losing 15,400 pounds of weight. How do the engineers accomplish the task of adding more weight? What is all around us weighing 8.6 pounds per gallon??? Seawater! Yes! So ballast tanks are filled with seawater to add weight to the ship that is removed when fuel is used.

Ballast water filtration and UV purification system. The parts to the right are the filtration system and the parts to the left are the UV system.

Ballast water is taken in through a filtration system before it even reaches its holding tanks (separate than the fuel tanks). The water first passes through a filter to remove large particles (such as larger pieces of plant material or debris) and then passes through a UV system that will kill any organisms. When the ballast water is released from their holding tanks in order to allow more fuel to come on board, the water must pass through the UV system once more to make sure nothing alive (plants, animals, bacteria, etc.) is getting into the water.

This purification of ballast water occurs to prevent invasive species from entering new areas. An invasive species is a plant or animal that is from somewhere else and is introduced through human actions. When these species establish in a new area and begin to outcompete native species, affect human health, and become costly to remove, they are classified as invasive.

Where I live on Lake Erie several species such as zebra and quagga mussels, round goby, and spiny water flea have all been introduced from ballast water from ships coming from the inland lakes of Eurasia. These ships would need to dump their water when they entered the shallower river ports of the Great Lakes, spurring a silent invasion. All four species are negatively affecting native populations of important species and are costly to manage. Then same is happening along the East Coast with species such as European green crab.

I would like each of you reading this blog to learn more about a species introduced to U.S. waters, whether they be fresh or salt, through ballast water. Feel free to let me know which organism you chose to learn more about in the comments section of the blog.

Personal Log

Today was a really special day at sea. It was my 30^th birthday. I could not have imagined a more amazing place to turn 30. I spent the day learning all about the engine systems on board, out on the bow enjoying the breeze and sunshine while looking for ocean critters, and was treated to the sweetest cake ever. It was so kind of the chefs on board to make me a cake for my birthday. It was a red velvet cake (my favorite) with chocolate frosting and decorated with chocolate pieces and white icing. We had it with some chocolate raspberry swirl ice cream. Truly a wonderful celebration with my new friends.

Jill with birthday cake! — My delicious birthday cake. Thank you everyone for a great birthday!

I spent the hour before sunset enjoying a nice yoga and meditation session before the most amazing sunset we have seen at sea yet. The clouds and sun put on the most spectacular display of color. Afterwards I learned more about the happenings of the mission control room (basically the mapping hub for the ship). I learned how we launch equipment to collect water column data and how we clean the data removing noise. I will be writing a blog on the mapping mission soon.

After our shift ended, my roommate and I ventured to the bridge to learn about piloting a vessel at night. We learned what equipment they rely on and how they manage their night vision. And then the most spectacular part of the whole night! The stars! Wow! It looks like someone through glitter (plastic free glitter preferably) into the sky. I have never seen so many stars in my life. We saw the Milky Way, Big Dipper, Little Dipper, North Star, Jupiter and so many other constellations. It was a wonderful end to a great birthday day.

Did You Know?

Even numbered locations (such as muster stations or staterooms) on ships are located on the port (left) side of the ship and odd numbered locations are located on the (starboard) right side of the ship.

Sea Measurements

Different ways to measure are used at sea. You can see some measurement conversions below.

1 nautical mile = 1.151 statute mile

1 knot = 1 nautical mile per hour = 1.151 statute mile per hour

1° Celsius = 33.8 °F

Animals Seen Today

Flying fish

Northern gannet