Difference between revisions of "AY Honors/Hot Air Balloons/Answer Key/es"

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<!-- 1. Decir el papel que tuvo cada una de las siguientes personas en el desarrollo de globos volantes: -->
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Image:Josephmontgolfier.jpg|Joseph Michel Montgolfier
 
Image:Josephmontgolfier.jpg|Joseph Michel Montgolfier
 
Image:Jacques Étienne Montgolfier.jpg|Jacques-Etienne Montgolfier
 
Image:Jacques Étienne Montgolfier.jpg|Jacques-Etienne Montgolfier
 
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Joseph-Michel Montgolfier (26 August 1740 – 26 June 1810) and Jacques-Étienne Montgolfier (6 January 1745 – 2 August 1799) were the inventors of the montgolfière, or airship. The brothers succeeded in launching the first manned ascent, carrying a young physician and an audacious army officer into the sky.
 
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Of the two brothers, it was Joseph who first contemplated building "machines". Joseph observed laundry drying over a fire incidentally form pockets that billowed upwards. Joseph set about building a box-like chamber {{units|1 by 1 by 1.3 meters|3 by 3 by 4 ft}} out of very thin wood and covering the sides and top with lightweight taffeta cloth. Under the bottom of the box he crumpled and lit some paper. The contraption quickly lifted off its stand and collided with the ceiling. Joseph then recruited his brother to balloon building.
 
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The two brothers then set about building a contraption 3 times larger in scale (27 times larger in volume). The lifting force was so great that they lost control of their craft on its very first test flight on 14 December 1782. The device floated nearly 2 kilometres (about 1.2 mi). It was destroyed after landing by the "indiscretion" of passersby.
 
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[[image:Early flight 02562u (4).jpg|thumb|200px|The first untethered balloon flight, by Rozier and the Marquis d'Arlandes on 21 November 1783.]]
 
Jean-François Pilâtre de Rozier (30 March 1754 – 15 June 1785) was a French chemistry and physics teacher, and one of the first pioneers of aviation. His balloon crashed near Wimereux in the Pas-de-Calais during an attempt to fly across the English Channel, and he and his companion, Pierre Romain, became the first known victims of an air crash.
 
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In June 1783, he witnessed the first balloon flight of the Montgolfier brothers. On 19 September, he assisted with the untethered flight of a sheep, a cockerel and a duck from the front courtyard of the Palace of Versailles. After a variety of tests in October, he made the first manned free flight in history on 21 November 1783, accompanied by the ambitious Marquis d'Arlandes. During the 25-minute flight using a Montgolfier hot air balloon, they traveled 12 kilometres from the Château de la Muette to the Butte-aux-Cailles, then in the outskirts of Paris, attaining an altitude of 3,000 feet.
 
 
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In December of 1783, these two flew the first gas balloon, filled with hydrogen. This flight lasted for at least 2 hours, starting from the Tuileries gardens in Paris, and landing outside Paris where it was destroyed by terrified peasants.
 
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Charles went on to discover [[w:Charles's_Law| Charles' Law]] which describes the relationship between the density of a gas and its temperature.
 
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From 11 August to 17 August, 1978, these three completed the first transatlantic balloon flight in the [[w:Double_Eagle_II|Double Eagle II]]. They began their flight from Presque Isle, Maine and ended their flight at Miserey, France.
 
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Ben Abruzzo and Larry Newman were also pilots on the [[w:Double_Eagle_V|Double Eagle V]] which in 1981 was the first balloon to cross the Pacific Ocean.
 
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On March 1, 1999, Bertrand Piccard and Brian Jones began the first balloon flight to circumnavigate the earth. Their flight was a success and ended on March 20, 1999. The flight took 19 days and 21 hours. The flight started in Switzerland and ended in Egypt.
 
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<!-- 2. Citar el principio de Arquímedes de Siracusa. Describir brevemente cómo se aplica a cada uno de los siguientes: -->
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::Archimedes' Principle states: ''any body fully or partially submerged in a fluid is buoyed up by a force equal to the weight of the fluid displaced.''
 
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Cork is less dense than water, and weighs less than the volume of water displaced, causing the cork to float.
 
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Ships, though made of dense materials, are shaped so that much of the interior is air. Because the weight of the ship and its cargo is less than the volume of water displaced, the ship will float.
 
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As long as a balloon plus the gas it contains weighs less than the atmospheric air which it displaces, the balloon will float in the air.
 
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<!-- 3. Usando un libro de texto de química o un libro de referencia de las tablas científicas, elaborar una sencilla tabla que demuestra la composición del peso del aire y el volumen del aire. -->
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{|border=1 cellspacing=1 cellpadding=5 align="center"
 
|-
 
! Gas || Air Percentage || Weight of pure gas
 
|-
 
|Nitrogen || 78%|| 1.25 g/liter
 
|-
 
|Oxygen ||21%|| 1.43 g/liter
 
|-
 
|Argon ||.93%|| 1.78 g/liter
 
|-
 
|Carbon Dioxide ||.03%||1.96 g/liter
 
|-
 
|Other (including Neon, Helium, <br>Hydrogen, Xenon, & Radon)|| .04%||
 
|}
 
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The average weight of air in a balloon can be worked out using rough percentages 80% Nitrogen and 20% oxygen as the make up of air. Atomic weight of Nitrogen is 14. Atomic weight of Oxygen is 16. Nitrogen and Oxygen gases are formed using two atoms. So for a balloon containing one mole (22.4 liters) of air, we can compute its weight:
 
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80% x 28 + 30% x 32 = 0.8 x 28 + 0.2 x 32 = 22.4 + 6.4 = 28.8
 
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So a balloon with 22.4 liters of air weighs 28.8 grams plus the weight of the balloon.
 
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To calculate weights of gases. One mole of the gas has a volume of 22.4 liters.
 
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Helium has an atomic weight of 4 g per mole so the weight of 22.4 l = 4 grams. Oxygen as a gas has two Oxygen atoms so the weight is twice the atomic weight.
 
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<!-- 4. Elaborar una simple tabla que muestre una comparación del número atómico, peso atómico y la densidad del hidrógeno, helio, nitrógeno y oxígeno. -->
<!-- 4. Draw up a simple table showing a comparison of the atomic number, atomic weight, and density of hydrogen, helium, nitrogen, and oxygen. -->
 
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{|border=1 cellpadding=5 align="center"
 
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!
 
![[w:Atomic_number|Atomic Number]]
 
![[w:Atomic_weight|Atomic Weight]]
 
![[w:Density|Density]] (g/cm³)
 
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![[w:Hydrogen|Hydrogen]]
 
!1
 
!1.008
 
!align="left"|0.00008988
 
|-
 
![[w:Helium|Helium]]
 
!2
 
!4.003
 
!align="left"|0.0001785
 
|-
 
![[w:Nitrogen|Nitrogen]]
 
!7
 
!14.01
 
!align="left"|0.0012506
 
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![[w:Oxygen|Oxygen]]
 
!8
 
!16.00
 
!align="left"|0.001429
 
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<!-- 5. Nombrar dos gases que se utilizan en los globos llenos de gas. -->
<!-- 5. Name two gases that are used in flying gas filled balloons. -->
 
Hydrogen & Helium are both less dense than air and may be used when flying a balloon. Warm air is also used for flying balloons, since it is less dense than cold air.
 
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*Note: Hydrogen burns violently when ignited. After the destruction of the Hindenburg, hydrogen was largely abandoned for the flying of manned balloons.
 
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<!-- 6. Explicar cómo el calor y la temperatura afectan la densidad del aire y cómo esto se aplica a los globos aerostáticos. -->
<!-- 6. Explain how heat/temperature affect the density of air, and how this applies to flying hot air balloons. -->
 
As described by [[w:Charles's_Law|Charles' Law]], heat applied to a gas will cause its molecules to move farther apart, reducing it's density. When the air in a balloon is heated above the temperature of the surrounding air, the air in the balloon becomes less dense than the air outside the balloon. Because the balloon is less dense, it will float or rise. The greater the difference in temperature between the air in the balloon and the surrounding air, the greater the difference in density between the air inside and outside the balloon, which increases the lift that the balloon will generate. This explains why balloons are mostly launched in cooler weather.
 
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<!-- 7. Explain the role of each of the following in the structure and flying of a hot air balloon. -->
 
; a. Envelope: The outer skin of the balloon, forming the container that holds the gas.
 
; b. Support structure: The framework of larger balloons.
 
; c. Throat: The lower opening through which the hot flame is applied to heat the air.
 
; d. Fuel source: The fuel used to heat the air to make the balloon less dense than the surrounding air.
 
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<!-- 8. Name two materials that may be used for the envelope of a hot air balloon, and compare the advantages each accords because of its properties. -->
 
;Paper: Paper may be used for model hot air balloons because of ease of acquisition and low price.
 
;Plastic: Plastic may be used for model hot air balloons because it is water resistant, easy to work with, and easy to acquire.
 
;Fabric: Fabric is usually used for larger, manned balloons. The fabric is specially treated.
 
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Military uses include: “eyes in the sky”, observation of enemy troops and positions, delivery of explosives to enemy positions, and defensive use of entangling incoming enemy flying craft.
 
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Scientific uses include instrument transport for data collecting, atmospheric studies, and aerial photography.
 
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Early morning is best because the air has cooled over night making the difference of temperature inside & outside greater, thus increasing buoyancy.
 
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The pilot controls the vertical movement of a hot air balloon by burning more fuel to make the air in the balloon hotter, causes the air in the balloon to become less dense, making it rise. Conversely, turning off the flame and allowing the air in the balloon to cool renders the air in the balloon more dense with respect to the surrounding atmosphere, causing the balloon to descend. More rapid increases in altitude can be achieved by lessening the weight of the balloon usually by dropping ballast, however this is limited by the amount of ballast available.
 
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Adding more of the lighter than air gas to ascend, and spilling some of the gas in order to descend varies the altitude of a helium or hydrogen filled balloon.
 
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<!-- 12. Describir cómo un piloto controla el movimiento horizontal o lateral de un globo en vuelo. -->
<!-- 12. Describe how a pilot controls the lateral or horizontal movement of a flying balloon. -->
 
Horizontal movement of a gas filled flying balloon is entirely at the mercy of air currents. The pilot can only vary the altitude so as to get into the path of air currents, such as the jet stream. This involves careful study of charts of air currents, close attention to weather data, and a certain element of trial and error. Older airships, like the Hindenburg, had a rudder and propellers to move it so that it did not have to depend on air currents.
 
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<!-- 13. Construir y completar un modelo a escala de un globo aerostático (o dos si trabaja en pares). -->
<!-- 13. Build to completion one model hot air balloon ( or two if working in pairs ). -->
 
===Materials===
 
* Tissue paper
 
* Scissors
 
* Glue Stick(s)
 
* Sewing pins (optional)
 
* Thin wire (22 gauge is suggested)
 
* Needle-nose pliers & wire cutters
 
* 1 50"x20" piece of Linoleum (for making balloon panel form)
 
* A spool of string
 
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===Directions for balloon panel form===
 
[[image:AYHAB-Model-Hot-Air-Balloons-draw2.png|thumb|400px|Illustration of distance from center]]
 
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Use a rigid or semi-rigid material such as poster board or a piece of linoleum flooring. I would suggest a piece of linoleum flooring,as it is more rigid and can be used more times. Cut out a piece that is 50 inches long and 20 inches wide. For every other measurement, you will have to measure from the center of the form you are creating. You will need to mark each measurement on the outside edge (furthest from the center of the form).
 
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* The first measurement is the very bottom of the form (and all others will be going from bottom to top) and is 3 1/2 inches each direction from the center.<br>
 
* Seven inches from the bottom is another measurement of 3 1/2 inches from center.<br>
 
* Four inches up the center line is a measurement of 4 7/8 inches from center.<br>
 
* Four more inches up the center line is a measurement of 6 3/4 inches from center.<br>
 
* Six inches up the center line is a measurement of 8 5/8 inches from center.<br>
 
* Six more inches up the center line is a measurement of 9 5/8 inches from center (this is the widest measurement).<br>
 
* Six inches beyond the widest measurement is a smaller measurement of 9 1/8 inches from center.<br>
 
* Three inches up the line is a measurement of 7 1/2 inches from center.<br>
 
* Three inches further is a measurement of 6 1/2 inches from center.<br>
 
* Three inches further is a measurement of 4 3/4 inches from center.<br>
 
* Three inches further is a measurement of 3 inches from center.<br>
 
* Finally, 2 3/4 to 3 inches further is your top measurement. The top measurement is 1 5/8 inches from center.
 
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Take the pen you are using to mark the measurements with and draw a line, starting from the bottom measurement, all the way around the outside of the measurement. It will look like a light bulb.
 
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Cut along the line that you just drew to remove the extra material around the "light bulb" shape. That should give you the form needed to create the proper shape for the panels of your balloon.
 
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===Directions for making balloon===
 
# Take 2 pieces of tissue paper and glue them end to end (vertically). Continue doing this with each set of tissue paper until you have 6 panels (a panel is 2 pieces of tissue paper glued end to end (vertically). You should only glue about a thumb's width or one straight line with the glue stick.
 
# Once you have 6 panels, lay them one on top of another, making sure that one end of the stack has an even edge at the bottom of the panels.
 
# Take the Panel Form and lay it on top of your 6 panels. Line up the bottom of the form with the straight edge of the 6 panels.
 
# Trace, with a marker, along the edge of the form (making sure not to move the form or the panels). The form will not reach the other end your your panel stack. This is alright. Just keep tracing beyond the form in a diagonal line until you reach the top of your panel stack. Then remove the form from the stack of panels.
 
# Take scissors and cut on the outside of the lines made earlier with the marker when you traced the panel form. When you are done, you should have two sets of scrap, one on each side of your panels. DO NOT THROW THESE AWAY! You may need to patch some panels that develop holes as well as use some of it to create a top for your balloon.
 
# Remove two panels from your pile and set the other four aside. Place the two panels one-on-top-of-the-other, and then pull the top panel about one inch to the side of the bottom panel. With scissors, cut flaps along the exposed, curvy edge of the bottom panel, making the cuts two or three inches apart, and about a half inch deep. Do this all the way along one side of the bottom of the two panels. The flaps make it much easier to attach panels together.
 
# Take a glue stick and apply glue to the top panels, right next to the tabs you just cut on the bottom panel. When applying the glue, you will only need one glue stick width of glue along the edge. Because the glue dries quickly, you may want to apply, at most, enough glue for 2 or 3 flaps at a time. Then you will fold over the flaps on the bottom panel onto the edge of the top panel where the glue was applied. Continue doing this until you have fully attached 2 of the panels together.
 
# Take a third panel and lay it on top of the two panels that you just glued together. Lay it so that the edge of the top panel, of the 2 attached panels, that has not been glued is exposed about an inch.
 
# Once again, cut flaps on the inch of exposed panel that are about a half inch deep. The glue and fold over the flaps to attach the third panel to the second panel. Now you should have 3 panels attached together. Continue repeating steps 8 & 9 until all of your panels have been attached. '''Remember to alternate which side you are cutting the flaps on so that you do not tamper with any of the joints of the other panels.'''
 
# Once you have attached all 6 of your panels together, flip them over. Raise the top panel and fold the inner panels back. Do not crease the inner panels. Then replace the top panel.
 
# Cut the bottom panel just as you have every panel before. Remember to make the cuts only about 1/2 inch deep. Then pull the top panel towards the edge of the bottom panel until you have the same width of the bottom panel as you would have for previous panels.
 
# Apply glue to the top panel just as you have for every panel before. Remember that it may be easier to apply glue for only 2 or 3 panels at a time and then fold the flaps over before continuing to apply the glue.
 
# Now. Open up your balloon. You will notice that it does not have a top yet. From the scraps that you saved, when you cut out your panels, pick as large a piece as possible. From this piece, cut as large a circle as you can. (You may fold the piece of paper over once or twice to make cutting out the circle easier.)
 
# Apply glue to the circle you just cut out (around the outside edges by one or two glue stick widths). Then attach the circle to the top of your balloon to cover the hole.
 
# Take some wire and cut roughly a 2 foot section off of the spool.
 
# Take some needle-nose pliers and shape the wire into a rigid circle. (I suggest making a little loop in one end. Turning it slightly. Threading other end of the wire through the loop a little ways and the twisting the threaded wire around the looped end. This keeps the wire circle from expanding or contracting in size.)
 
# Put the open end of the balloon through the wire circle. Then fold the balloon over the wire and glue the folded over end back to the balloon. (You may cut flaps in the open end of the balloon to make it easier to glue.) There will be more balloon surface than wire. You may have to fold the end of a panel or two over a little to decrease the amount of panel that you have to deal with while gluing the balloon over the wire.
 
# At this point your balloon is finished. You will want to go over the entire surface of the balloon to make sure there are no holes in the panels, no unglued panel joints, no unglued balloon cap spots, or rips at the bottom where the wire is. If there are any of these issues, take some of your left over scraps (Aren't you glad you saved them?) and patch the balloon by gluing pieces from your scraps over any holes.
 
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<!-- 14. Lanzar con éxito, volar y recuperar el modelo a escala del globo aerostático que construyó. -->
<!-- 14. Successfully launch, fly, and recover the model hot air balloon(s) which you have built. -->
 
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[[Image:launching balloon at night.jpg|thumb|300px|left|launching balloon at night]]
 
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Take a single burner camp stove and use it to heat the air underneath your balloon. Be careful not to get the balloon too close to the flame as it will ignite and burn up.
 
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A more efficient way of getting hot air into your balloon is to take some rigid dryer vent, cut notches that can be slid over the pot stabilizers on your camp stove, and then slide the vent pipe onto the stove. This causes the heated air to be channeled up the vent pipe into the balloon. However, this does not eliminate the possibility of your balloon igniting and burning up. You will have to keep the balloon from touching the vent pipe and also watch the balloon to make sure it doesn't start turning brown nearest the vent pipe.
 
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You will need two (2) people to launch the balloon. One to hold the top end of the balloon up (until enough hot air is within the balloon), and the other to hold the balloon mouth over the stove. Before holding the balloon over the stove, tie a spool of string to the wire that keeps the form of the balloons mouth. Hold the balloon over the stove so that hot air may enter the balloon. Keep the balloon over the stove until it looks/feels as though it is ready to take off (usually anywhere from 30-45 seconds will do). When enough hot air has entered the balloon, release the balloon and let it fly up and away. Let the balloon fly for about twenty (20) seconds. When the balloon has successfully been flown pull on the string that you attached to the balloon to recover the balloon. The string keeps the balloon from being blown away as well as keeping it from flying into trees or other objects.
 
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Please keep safe by using heat resistant gloves such as oven mitts or welders gloves. The metal duct does get hot. The balloon is not over the duct pipe long enough to catch fire. We had to have both gas burners going to get sufficient heat up the pipe. Happy flying. There is a good DVD called ''Night Crossing'' about a family who escaped over the Berlin border. They built two balloons and had two attempts to freedom.
 
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==Referencias==
==References==
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Latest revision as of 02:19, 4 January 2023

Other languages:
English • ‎español
Globos aerostáticos

Nivel de destreza

1

Año

2008

Version

22.11.2024

Autoridad de aprobación

Asociación General

Hot Air Ballooning AY Honor.png
Globos aerostáticos
Artes y actividades manuales
Nivel de destreza
123
Autoridad de aprobación
Asociación General
Año de introducción
2008
Vea también


1

Decir el papel que tuvo cada una de las siguientes personas en el desarrollo de globos volantes:


1a

Joseph-Michel Montgolfier y Jacques-Michel Montgolfier



1b

Jean-François Pilâtre de Rozier y François Laurent le Vieux d'Arlandes



1c

Jacques Alexandre César Charles y Nicolas-Louis Robert



1d

Benjamín L. Abruzzo, Max Leroy Anderson y Larry Newman



1e

Bertrand Piccard y Brian Jones




2

Citar el principio de Arquímedes de Siracusa. Describir brevemente cómo se aplica a cada uno de los siguientes:


2a

Un pedazo de corcho flotando en un recipiente de agua


2b

Un barco flotando en el océano



2c

Un globo aerostático flotando en la atmósfera




3

Usando un libro de texto de química o un libro de referencia de las tablas científicas, elaborar una sencilla tabla que demuestra la composición del peso del aire y el volumen del aire.



4

Elaborar una simple tabla que muestre una comparación del número atómico, peso atómico y la densidad del hidrógeno, helio, nitrógeno y oxígeno.




5

Nombrar dos gases que se utilizan en los globos llenos de gas.



6

Explicar cómo el calor y la temperatura afectan la densidad del aire y cómo esto se aplica a los globos aerostáticos.



7

Explicar el papel de cada una de las siguientes en la estructura y el vuelo de un globo aerostático:



8

Nombrar dos materiales que pueden utilizarse para la envoltura/vela de un globo aerostático y comparar las ventajas que cada uno de los cables tiene por sus propiedades.



9

Describir la forma como globos en vuelo han servido en forma útil en:


9a

Campañas militares



9b

Investigaciones científicas




10

¿A qué hora del día la mayoría de los vuelos en globos deportivos toman lugar? ¿Por qué?



11

Describir cómo un piloto controla el movimiento vertical de:


11a

Un globo aerostático



11b

Un globo lleno de gas




12

Describir cómo un piloto controla el movimiento horizontal o lateral de un globo en vuelo.



13

Construir y completar un modelo a escala de un globo aerostático (o dos si trabaja en pares).



14

Lanzar con éxito, volar y recuperar el modelo a escala del globo aerostático que construyó.




Referencias