some of the pages are not relevant to some people. If you are a teacher you can use this as someone of the pages needs groups.If you are by your self then skip the pages with groups.
Do You Know working less can actually produce better results?
I think working harder is not always the right path to success. The right path is smart working. One of my brother told me that if some one order you to make a cup of tea for him, but you have all materials without milk then you may go market and takes milk after that you make a cup of tea for him but when you give him the tea that time he was sleeping .So wheres goes your hard work to collect milk? Rather if you make a cup of tea without milk that was smart work for you.So the key to success is not hard working but smart working.
#Productivity # smartwork
To know more click here http://visionit.org/do-you-know-working-less-can-actually-produce-better-results/
some of the pages are not relevant to some people. If you are a teacher you can use this as someone of the pages needs groups.If you are by your self then skip the pages with groups.
Do You Know working less can actually produce better results?
I think working harder is not always the right path to success. The right path is smart working. One of my brother told me that if some one order you to make a cup of tea for him, but you have all materials without milk then you may go market and takes milk after that you make a cup of tea for him but when you give him the tea that time he was sleeping .So wheres goes your hard work to collect milk? Rather if you make a cup of tea without milk that was smart work for you.So the key to success is not hard working but smart working.
#Productivity # smartwork
To know more click here http://visionit.org/do-you-know-working-less-can-actually-produce-better-results/
English Fluency is important because it provides a bridge between word recognition and comprehension. Follow this simple steps to improve fluency.
For More Details: https://www.aksent.org.in/courses/communicative-english/
If you understand how English is important for you, then there is the next question: HOW can you improve your English skills? Check this presentation to find out the 10 best ways of making your English better.
We offer english speaking course for all sorts of ages as well as exams. Our main focus is to provide practical training rather than theoritical training.
Physics Investigatory Project on Fluid Mechanicsashrant
A project on the relation between the coefficient of viscosity and the SAE grading system of engine oils.
Complete with a postulated equation to calculate the viscosity of a liquid at ant given temperature.
Debunking Common misconceptions in Physics and clarifying difficult concepts.pdfSG Physics Tuition
With a physics tutor in Singapore, students can learn intricate subjects and debunk some myths surrounding the subject. To simplify things for you, here is a simplified version of some difficult concepts.
English Fluency is important because it provides a bridge between word recognition and comprehension. Follow this simple steps to improve fluency.
For More Details: https://www.aksent.org.in/courses/communicative-english/
If you understand how English is important for you, then there is the next question: HOW can you improve your English skills? Check this presentation to find out the 10 best ways of making your English better.
We offer english speaking course for all sorts of ages as well as exams. Our main focus is to provide practical training rather than theoritical training.
Physics Investigatory Project on Fluid Mechanicsashrant
A project on the relation between the coefficient of viscosity and the SAE grading system of engine oils.
Complete with a postulated equation to calculate the viscosity of a liquid at ant given temperature.
Debunking Common misconceptions in Physics and clarifying difficult concepts.pdfSG Physics Tuition
With a physics tutor in Singapore, students can learn intricate subjects and debunk some myths surrounding the subject. To simplify things for you, here is a simplified version of some difficult concepts.
#class9 Newton's laws complete summary #Learning the infamous newton laws of motion through fascinating narrative and storyline #simple easy explanation
Powerpoint presentation created by Jan Parker for use in her 9th grade physics class. This powerpoint - and many more - can be purchased and downloaded for classroom use at: http://www.teacherspayteachers.com/Store/Jan-Parker/Products
Operation “Blue Star” is the only event in the history of Independent India where the state went into war with its own people. Even after about 40 years it is not clear if it was culmination of states anger over people of the region, a political game of power or start of dictatorial chapter in the democratic setup.
The people of Punjab felt alienated from main stream due to denial of their just demands during a long democratic struggle since independence. As it happen all over the word, it led to militant struggle with great loss of lives of military, police and civilian personnel. Killing of Indira Gandhi and massacre of innocent Sikhs in Delhi and other India cities was also associated with this movement.
Instructions for Submissions thorugh G- Classroom.pptxJheel Barad
This presentation provides a briefing on how to upload submissions and documents in Google Classroom. It was prepared as part of an orientation for new Sainik School in-service teacher trainees. As a training officer, my goal is to ensure that you are comfortable and proficient with this essential tool for managing assignments and fostering student engagement.
Unit 8 - Information and Communication Technology (Paper I).pdfThiyagu K
This slides describes the basic concepts of ICT, basics of Email, Emerging Technology and Digital Initiatives in Education. This presentations aligns with the UGC Paper I syllabus.
How to Make a Field invisible in Odoo 17Celine George
It is possible to hide or invisible some fields in odoo. Commonly using “invisible” attribute in the field definition to invisible the fields. This slide will show how to make a field invisible in odoo 17.
The Roman Empire A Historical Colossus.pdfkaushalkr1407
The Roman Empire, a vast and enduring power, stands as one of history's most remarkable civilizations, leaving an indelible imprint on the world. It emerged from the Roman Republic, transitioning into an imperial powerhouse under the leadership of Augustus Caesar in 27 BCE. This transformation marked the beginning of an era defined by unprecedented territorial expansion, architectural marvels, and profound cultural influence.
The empire's roots lie in the city of Rome, founded, according to legend, by Romulus in 753 BCE. Over centuries, Rome evolved from a small settlement to a formidable republic, characterized by a complex political system with elected officials and checks on power. However, internal strife, class conflicts, and military ambitions paved the way for the end of the Republic. Julius Caesar’s dictatorship and subsequent assassination in 44 BCE created a power vacuum, leading to a civil war. Octavian, later Augustus, emerged victorious, heralding the Roman Empire’s birth.
Under Augustus, the empire experienced the Pax Romana, a 200-year period of relative peace and stability. Augustus reformed the military, established efficient administrative systems, and initiated grand construction projects. The empire's borders expanded, encompassing territories from Britain to Egypt and from Spain to the Euphrates. Roman legions, renowned for their discipline and engineering prowess, secured and maintained these vast territories, building roads, fortifications, and cities that facilitated control and integration.
The Roman Empire’s society was hierarchical, with a rigid class system. At the top were the patricians, wealthy elites who held significant political power. Below them were the plebeians, free citizens with limited political influence, and the vast numbers of slaves who formed the backbone of the economy. The family unit was central, governed by the paterfamilias, the male head who held absolute authority.
Culturally, the Romans were eclectic, absorbing and adapting elements from the civilizations they encountered, particularly the Greeks. Roman art, literature, and philosophy reflected this synthesis, creating a rich cultural tapestry. Latin, the Roman language, became the lingua franca of the Western world, influencing numerous modern languages.
Roman architecture and engineering achievements were monumental. They perfected the arch, vault, and dome, constructing enduring structures like the Colosseum, Pantheon, and aqueducts. These engineering marvels not only showcased Roman ingenuity but also served practical purposes, from public entertainment to water supply.
Francesca Gottschalk - How can education support child empowerment.pptxEduSkills OECD
Francesca Gottschalk from the OECD’s Centre for Educational Research and Innovation presents at the Ask an Expert Webinar: How can education support child empowerment?
Palestine last event orientationfvgnh .pptxRaedMohamed3
An EFL lesson about the current events in Palestine. It is intended to be for intermediate students who wish to increase their listening skills through a short lesson in power point.
Synthetic Fiber Construction in lab .pptxPavel ( NSTU)
Synthetic fiber production is a fascinating and complex field that blends chemistry, engineering, and environmental science. By understanding these aspects, students can gain a comprehensive view of synthetic fiber production, its impact on society and the environment, and the potential for future innovations. Synthetic fibers play a crucial role in modern society, impacting various aspects of daily life, industry, and the environment. ynthetic fibers are integral to modern life, offering a range of benefits from cost-effectiveness and versatility to innovative applications and performance characteristics. While they pose environmental challenges, ongoing research and development aim to create more sustainable and eco-friendly alternatives. Understanding the importance of synthetic fibers helps in appreciating their role in the economy, industry, and daily life, while also emphasizing the need for sustainable practices and innovation.
2024.06.01 Introducing a competency framework for languag learning materials ...Sandy Millin
http://sandymillin.wordpress.com/iateflwebinar2024
Published classroom materials form the basis of syllabuses, drive teacher professional development, and have a potentially huge influence on learners, teachers and education systems. All teachers also create their own materials, whether a few sentences on a blackboard, a highly-structured fully-realised online course, or anything in between. Despite this, the knowledge and skills needed to create effective language learning materials are rarely part of teacher training, and are mostly learnt by trial and error.
Knowledge and skills frameworks, generally called competency frameworks, for ELT teachers, trainers and managers have existed for a few years now. However, until I created one for my MA dissertation, there wasn’t one drawing together what we need to know and do to be able to effectively produce language learning materials.
This webinar will introduce you to my framework, highlighting the key competencies I identified from my research. It will also show how anybody involved in language teaching (any language, not just English!), teacher training, managing schools or developing language learning materials can benefit from using the framework.
S.i.p. 4th year (pls improve format if will be used as guide)(try APA style)
1. Holy Child Educational Center, Inc.
San Jose, Iriga City
S/Y 2013-2014
(Science Investigatory Project)
Members:
Luzille Rodriguez
Abigail Gorgonia
Nikka Estallo
Justin Ayubo
Froilan Gentalian
Noelan Serrano
Submitted To:
Rolando B. Bancaso
2. Approval Sheet
Mdm. Maricee S. Bernal
Adviser Date
Critic Date
Critic Date
Critic Date
Sir Rolando B. Bancaso
Subject Area Head Date
Accepted as partial fulfilment of the requirements for the
Chemistry Subject.
3. Acknowledgement
We would like to extend our deepest gratitude to those who have, in one
way or another helped us complete this project.
First and foremost, to Angeli Nanali, for help given;
To Julie Ann Pontanares, and Nathaniel Lareza for all their guidance and
enthusiasm;
To all St. Peregrine family, thank you for the moral support;
To our family and friends, who had given us financial support;
To Vic Anthony Rodriguez, for the interpretation of our data;
To Engr. Hilario Gorgonia, for giving us the materials needed;
To Larnny Ibias, for providing reference books;
To Jessamae Agnas for the electronic devices our group needed;
To our physics teacher, Sir Rolando Bancaso, for the guidance and
To God, who always gives hope to our group.
4. Abstract
What keeps you in your seat of a giant loop-de-loop roller coaster?
Surprisingly, it is not the seatbelt but the seat! It works because of something
called centripetal force and it does much more than make a great roller coaster.
It keeps a satellite in orbit, you in your bicycle seat during a turn, and earth’s
revolution around the sun. Centripetal force is a great study that let people
understand those natural events.
5. I. Introduction
Sir Isaac Newton was a careful observer of the world around him. He
used mathematics and science to describe natural phenomenon which, at the
time, were not understood. Newton discovered that to get an object to move,
the object must experience a force that makes it move in a certain direction.
Once the object experiences this force, it is set in motion and will continue
this motion until it experiences an opposite force that causes the motion to
stop. You have felt this phenomenon when riding a roller coaster. When the
roller coaster starts moving, you rock backwards because your body wants to
stay in its stationary position, but after you move, if the roller coaster
suddenly stops, you will rock forward because your body wants to keep
moving forward at the same speed and direction. This example describes
what happens when you experience motion in a straight line.
In circular path and curves, newton realized that the object wants to
move away from the center of the circle. For example, when you are riding in
a loop-de-loop roller coaster. The tracks are moving in a circle, and we move
along with it, but what is keeping us in our seat? Gravity is a force that push
us down toward the ground, which may help us stay in our seat at the bottom
of the loop, but it probably does not help us stay in our seats at the top of the
loop! The force from our seatbelt may help us stay in our seat but centripetal
force is the one that is constantly pulling us towards the center of the loops.
Which force is the centripetal force when we ride in the loop-de-loop?
In this physics science project we will investigate the movement of
an object during circular motion and determine what the centripetal force is
that keeps the object moving in a circular way.
6. II. Review of Related Literature
The review of the literature for this study focuses on centripetal
force and its importance. The study focuses to the location of the force
when a certain circular motion happens. The research outcomes germane
to other studies such as newton’s first law of motion, gravity, forces
applied, and many more.
The centripetal force is directed inwards, from the object to
the center of rotation while centrifugal force is directed outwards; in the
same direction as the velocity of the object. Centripetal force occurs
everywhere so loads of experiments and activities can be done to visualize
or observe its existence.
Comparison of Centripetal force and Centrifugal force
Many researchers have proclaimed that centripetal and centrifugal
forces differ depending on the situation of an object undergoing motion in
a curve line or circular motion. Based from www.diffen.com:
Centrifugal Force Centripetal Force
Meaning: Tendency of an object
following a curved path to fly
away from the center of
curvature. Might be described
as “lack of centripetal force.”
The force that keeps an object
moving with a uniform speed
along a circular path.
Direction: Along the radius of the circle,
from the center towards the
object.
Along the radius of the circle,
from the object towards the
center.
Example: Mud flying off a tire; children
pushed out on a roundabout.
Satellite orbiting a planet
Formula: Fc = mv2
/r Fc = mv2
/r
Defined by: Chistiaan Hygens in 1659 Isaac Newton in 1684
7. Centrifugal Force Centripetal Force
Is it a real
force?:
No; centrifugal force is the
inertia of motion.
Yes; centripetal force keeps the
object from "flying out".
Other experiments in connection with Centripetal force
The spinning penny, it shows the relationship of the size of the coin to the
time it spins, and it also proves that the centripetal force is a center seeking
force, (Steve Spangler). Bucket swing, defying gravity, ping pong challenge.
From www.afterschooltreats.com
Centrifugal Force doesn’t exist?
According from www.regentsprep.org centrifugal force doesn’t exist. It is
only the absence of centripetal force. An example is when a car is experiencing
a turn, a light object on the dashboard moves at the opposite direction of the
turn. The object moved because of the lack of friction or another object with
centripetal force not because of the centrifugal force.
8. III. Objectives of the Study
To investigate the movement of an object during circular motion.
To determine what the centripetal force is.
To know what factors affect centripetal force.
To help students gain knowledge about centripetal force.
9. IV. Statement of the Problem
Whenever an object moves in a circular path we know the object is
accelerating because the velocity is constantly changing direction. All
accelerations are caused by net force acting on an object. In the case of an
object moving in a circular path, the net force is a special force called the
centripetal force.
So a centripetal force is the center seeking force which means that
the force is always directed toward the center of the circle. Without this
force, an object will simply continue moving in straight line motion. This
study aims to determine this centripetal force and compare it with the
balancing force of gravity on a hanging object.
1. What is the relationship of mass, velocity, radius and the
centripetal force experienced by the object?
2. Is there other factors affecting Centripetal force that can be seen
in the study?
10. V. Hypothesis
If an object is in circular motion and something pulls it to the center
or holds it to retain in a certain position while experiencing the motion, then
the object is experiencing centripetal force.
If the object involved is heavy and if it undergone an increase in
velocity, then it needs a greater amount of centripetal force. If radius
increases the needed centripetal force decreases.
If circular motion can be horizontally or vertically, then both of it
has different effect to the amount of centripetal force because of gravity
and other forces.
If the object did not take the right amount of velocity and
centrifugal force and it has short radius, then if it is in horizontal circular
motion, it will acquire less centripetal force, and if it is in vertical circular
motion, it may fall due to powerful gravity than the centripetal force.
11. VI. Significance of the Study
Anytime anything goes round in a circle, or even just a bit of a curve,
a centripetal force must have operated. These forces are just the ordinary,
everyday forces like gravity, tension, electric and magnetic forces which get
called "centripetal" when they make things move in circles. So their practical
use is endless - keeping electrons moving about atoms, keeping planets
moving round stars and stars moving round galaxies and cars moving round
corners and turbine blades revolving - you can come up with dozens more.
Centripetal force is important because:
It helps drivers avoid car accidents.
It gives ideas for useful appliances; one example is the
washing machine.
It identifies the right road design to avoid car accidents
It helps ensure safety at amusement parks and carnivals
by having the right design of rails.
12. VII. Scope and Limitation
Our study focuses only to some factors affecting centripetal
force, these are the following: mass, velocity radius, and area
This study is applied to horizontal circular movement.
Its main focus is the centripetal force even though other forces
are evident in the study.
We focused more on the observable components of the
factors affecting Centripetal force, if new factor will be
observed in the experimentation, No formula can be
formulated in the study.
13. VIII. Research and Design
Materials
Stove
Cooking pot
Measuring cup
Tap water, normal
temperature and cold
JELL-O packages (2).
Use two very different
colors of JELL-O, both
light-colored (like
cherry and lime).
Stirrer
Plastic cups, clear (6)
have extra cups for
mistakes)
Permanent marker
Calculator
Refrigerator
Timer or clock
Marbles (3 small and
light in weight and big
heavier) (weigh the 2
kinds of marbles and
convert to kg and take
note)
Oven mitt
Scissors
String (at least 2 yards
long)
Electrical tape or duct
tape
Optional: Flashlight
Lab notebook
Methodology
Making the Centripetal Force Test Chambers
In this part of the science project, you will make 6 centripetal force test
chambers using JELL-O, cups, and marbles. You will want to make more than
one to have replicates, or copies, of your data.
1. Make a package of JELL-O by following the instructions on the box, except
use more cold water than is recommended.
Making JELL-O using 3.5 cups of water will make it less thick and
more liquid. This will make it easier for the marble to move when
you test it later.
14. a. On the stove in the cooking pot, have an adult help you warm the
appropriate amount of water according to the instructions on the
box.
b. Continue following the box's instructions by adding the JELL-O mix
to the warm water. Stir the JELL-O mix in the water for 2 minutes
while keeping the pot on the hot burner.
c. After stirring for 2 minutes, the JELL-O should be completely
dissolved and no particles of JELL-O powder should be visible. It
should look clear.
d. Take the JELL-O off of the hot burner and add 1.5 times the amount
of cold water that is recommended on the box's instructions. Use
cold tap water and stir it in as it is added.
i. For example, if the instructions say to use 1 cup of cold water,
use 1.5 cups of cold water instead.
2. Pour the JELL-O into six of the plastic cups, filling each cup a little less
than halfway full. These will be your centripetal force test chambers.
a. Use a permanent marker to label these cups #’s 1,3,5 for small
marbles and #’s 2,4,6 for big ones.
15. 3. Place the cups in the refrigerator and refrigerate them for 4 hours.
a. Because you used more water than is recommended in the box's
instructions, the JELL-O will not be very firm after 4 hours, but it
should be firm enough to support the marble in the next step.
4. In each cup, place a marble on the top of the JELL-O in the center of the
cup. Gently press into the JELL-O just until the marble is secure and will
not move around.
5. Make the second batch of JELL-O by preparing it as you did in step 1. The
second batch must be different in color with the first batch.
6. After adding the cold tap water to the JELL-O, place an oven mitt in the
refrigerator and have an adult help you place the pot with the JELL-O on
the oven mitt. Refrigerate the pot of JELL-O for 30 minutes.
a. This second batch of JELL-O will be added to the JELL-O already in
the plastic cups. However, if the second batch of JELL-O is not
refrigerated before it is added, it may be too hot and melt the first
layer of JELL-O.
7. After refrigerating the pot of JELL-O, slowly and carefully pour the JELL-O
into the cups, covering the first layer of JELL-O and the marble, until the
cups are almost full. Leave about 2.5 centimeters (cm) (1 inch) at the top
of the cups.
a. It is important to slowly and carefully pour the second layer of JELL-
O on top of the first layer because otherwise the second layer may
damage the first layer.
b. Do not worry if the two layers of JELL-O mix together a little where
they meet. However, check to make sure that the marble stays
16. roughly in the middle, between the two layers. Do not use any cups
in which the marble is not near the middle.
i. If multiple cups have marbles that are not near the middle, try
repeating steps 1-7 but use less cold water in step 1e, such as
1.25 cups instead of 1.5 cups.
c. Your cups should look similar to the one in Figure 1 below, although
your layers of JELL-O may be different colors.
Figure 1. Once you have poured two layers of JELL-O into your cups, they should look similar to
the one, with the marble in between the two layers.
1. Place the cups in the refrigerator and refrigerate them for 4 hours.
2. While your JELL-O solidifies, prepare your centripetal force generator.
You will be testing your test chambers inside of the generator.
a. Take an empty plastic cup and use the scissors or any sharp object
to make a small hole about 2.5 cm (1 inch) from the top rim of the
cup. Make a second hole on the opposite side of the cup.
b. Put a small piece of electrical tape or duct tape on the edge of the
cup, just above each hole. Fold over the tape so it is on the outside
and inside of the cup, but not blocking the holes. This will help
prevent the string, which you will attach next, from detaching.
17. c. Attach the string to the top of the cup, tying one end of the string
through one of the holes at the cup's top and the other end through
the other hole.
d. Your cup should now look like the one in Figure 2 below. This cup
will be your centripetal force generator. Test to make sure that the
string is strongly attached to the cup by holding on to the string and
pulling down on the cup.
Figure 2. Prepare your centripetal force generator cup, as shown here, by making two holes in the
top of the cup, placing electrical or duct tape above the holes, and tying string through the holes.
e. Cut two pieces of strings. One short and one long. Tie both of it
tightly at the center of the semi-circle string attached to the
centripetal force generator.
18. Testing the Centripetal Force Test Chambers
1. After refrigerating the cups, take #1 of your test chambers and place it in
the centripetal force generator by stacking the plastic cup with the JELL-O
into the plastic cup with the string.
a. Do not use any cups in which the marble is not near the middle. If
multiple cups have marbles that are not near the middle, try
repeating the section titled "Making the Centripetal Force Test
Chambers" but this time use less cold water when making the JELL-
O in steps 1e and 5, such as 1.25 cups instead of 1.5 cups.
2. Now hold the short string and quickly twirl the cup around for 5 sec.
Another member should count the number of complete circle made. You
must spin the cup hard and fast to get enough centripetal force for the
marble to move!
3. After 5 sec. stop spinning and separate the two cups. Multiply the
number of complete circle made to the circumference. Formula:
2 (length of the short string)
4. Then divide to 5 sec. The quotient is the velocity.
5. Observe the JELL-O, and the position of the marble relative to the two
different colors of JELL-O. Remember that the marble started out right at
the dividing line between the two colors. Make observations, drawings,
and record data in a table similar to Table 1. Put it in your lab notebook
a. If you have trouble locating the marble, try backlighting the marble
by shining a flashlight through the back of the cup, toward you.
Test
chambers
mass of
the marble
(kg)
Velocity
(m/s)
Radius
(m)
Centripetal
force (N)
Where did
the marble
move to?
Other
observations
#1 Small Same as #2 Short
#2 Big Same as #1 Short
#3 Small Higher to #1 Short
#4 Big Same as #3 Short
#5 Small Same as #1 long
#6 Big Same as #1 long
Table 1. In your lab notebook, make a table like this one to record your observations and data.
19. b. If the marble did not move, the JELL-O may be too firm. First try
spinning it again with the same procedure but faster this time. The
velocity will surely change. Do the computation again. If the marble
has still not moved, either let the cups sit out at room temperature
overnight to soften the JELL-O or repeat the section titled "Making
the Centripetal Force Test Chambers" but this time use more cold
water when making the JELL-O in steps 1e and 5.
6. Repeat steps 1-4 with #2 test chambers. The velocity should be the same
with #1 test chamber
7. For test chamber #3 and #4 repeat steps 1-4 but with higher velocity. Let
your strongest member do it. The velocity of #3 and #4 should be the
same.
8. For test chamber #5 and #6 repeat steps 1-4 but use the longer string.
The velocity of test chamber #’s 5 and 6 should be the same with #’s 1
and 2.
9. Did you notice any patterns of movement? Did the marbles always move
in the same direction? Did they move in the direction you thought they
would? How far did they move? What is the relationship of the mass,
velocity and radius to the centripetal force? Where do you think the
centripetal force is occurring?
a. Based on where the marbles went during circular motion, what do
you think is the centripetal force that keeps the marbles moving in a
circular way, and prevents them from flying off in a straight line?
b. For more accurate result, video every spinning.
20. IX. Results and Discussion
Test
cham
bers
Description
of the area of
the marble
mass
of the
marble
(kg)
Velocity
(m/s)
Radius
(m)
Centripetal
force (N)
Where did
the marble
move to?
Other
observat
ions
#1 Same as 3 and 5 0.0047 2.58 0.158 0.198
#2 Same as 4 and 6 0.0207 2.58 0.158 0.872
#3 Same as 1 and 5 0.0047 4.17 0.158 0.517
#4 Same as 2 and 6 0.0207 4.17 0.158 2.278
#5 Same as 1 and 3 0.0047 2.58 0.31 0.101
#6 Same as 2 and 4 0.0207 2.58 0.31 0.444
#7 Same as 2, 4 & 6 0.0414 2.58 0.31 0.889
Computations:
Circumference Short String Circumference Long String
= 2(3.1416) (0.158) =2(3.1416)(0.31)
# of circles made in 5 sec.
Test Chambers #1 & #2 = 13, Test Chambers #3 & #4 = 21, Test Chambers #5 & #6 = 13
Velocity
Formula: (Circumference)(# of circles made in 5 sec.)/ 5 sec.
Centripetal Force
Formula: = mv2
/r Legend: m = mass, v = velocity, r = radius
21. Observations
1) Test chamber #1, the marble moved downward and a little sideward, it is
already in the estimated middle of the bottom color.
2) Test chamber #2, the marble moved downward, but higher than #1. This
chamber has the bigger and heavier marble.
3) Test chamber #3, the marble moved downward and sideward. It reached the
bottom of the plastic cup.
4) Test chamber #4, the marble moved downward. Compared to test chamber
#2, #4 is lower. #2 and #4 contain marbles with same size and mass.
5) Test chamber #5, the marble moved a little downward.
6) Test chamber #6, the marble, at first sight didn’t seem to move. But when
inspected keenly, it moved a little.
7) Test chamber #7, the marble moved to the middle side of the lower color of
the jell-o
8) No marble moved upward
9) Test chambers # 2,4,6 with heavier marbles have higher centripetal force
compared to test chambers #1,3,5
10) Test chamber #4 had the highest Centripetal force
11) Test chamber #3 had a higher Centripetal force compared to other
chambers with same marble.
12) Test chambers #5 and #6 have lower centripetal force compared to #1
and #2 considering these chambers having same velocity.
13) Test chamber marble #7 is heavier to test chamber marble number #6
and it moved really downward compared to #6. But Test chamber marble
#2, #4 and #6 is heavier to #1, #3, and #5 and yet #1, #3, and #5 moved
more downward than those with heavier marbles.
22. X. Conclusion
We therefore conclude that Mass, velocity, and radius are all related
when you calculate centripetal force. Also Area of the object experiencing the
net force affects the needed amount of centripetal force needed. The
Centripetal force in the experiment is located on the Jell-o, the plastic cup and
the rope.
Increasing mass, increasing Centripetal force needed and vice versa.
Increasing speed or velocity, increasing Centripetal force needed and Vice
versa
Decreasing radius, increasing Centripetal force needed and vice versa
Area of the object experiencing the net force affects specific objects
having the centripetal force.
Recommendation
We would like to recommend this further analysis about Centripetal force. It
can help to the learning about centripetal force and the three factors affecting
it.