you sould have learnd that in preschool but.............. the anser to your problem? is yes a ball is a sphere and so is a balloon and a orange and a apple and a grape......and do i have to say any more
It depends on many things, but if you're going by the equatorial radius as the same size, the balloon should be about 10-15% larger. Note that you can mesure the volume of irregular shapes, thanks to my good friend Archemedes ("Eurika!"). Take a mesuring container large enough to easily hold the balloon and fill it about 2/3 full. Note the volume the water occupies by the water level. Now, immerse the balloon in the water and mesure the volume by the water level again. the difference is the volume of the balloon.
The radius of a sphere is equal distance from the center of the sphere to all points within the sphere.
Sphere is one syllable: sphere.
It is a representation of a sphere.
A electric sphere.
you sould have learnd that in preschool but.............. the anser to your problem? is yes a ball is a sphere and so is a balloon and a orange and a apple and a grape......and do i have to say any more
When you fill a balloon with air, the air molecules displace the surrounding space inside the balloon, causing the balloon to expand and stretch. The pressure of the air inside the balloon exceeds the pressure outside, creating tension in the balloon material, which keeps it inflated.
The volume of air in a balloon can be calculated by measuring the dimensions of the balloon and using the formula for the volume of a sphere (4/3 x pi x r^3) if the balloon is spherical. If the balloon is not spherical, the volume can be estimated by using the formula for the volume of a cylinder (pi x r^2 x h) or a different geometric shape that closely approximates the balloon's shape.
To find the volume of an inflated balloon, you can measure its diameter using a ruler and then use the formula for the volume of a sphere, V = (4/3) * pi * r^3, where r is the radius (half of the diameter) of the balloon. Plug in the radius and calculate the volume. Alternatively, you can submerge the inflated balloon in a container of water and measure the water displacement to find the volume of the balloon.
If the surface area of a spherical balloon increases by 11%, the radius will increase by approximately 3.3%. This relationship is based on the formula that relates surface area to radius in a sphere (Surface Area = 4πr^2).
It would take approximately 0.85 cubic meters of helium to fill a 3 ft balloon.
Use the formula for a sphere. First divide the diameter by 2; that will give you the radius.
The list of colours that end with sphere (the same with geometric shapes, animal shapes, plant shapes, balloons, etc.) are: Red sphere Black sphere Blue sphere Yellow sphere Pink sphere Silver sphere Green sphere Purple sphere Orange sphere Crimson sphere Navy sphere White sphere Gold sphere Teal sphere Brown sphere Indigo sphere Saffron sphere Amethyst sphere Vermilion sphere Chartreuse sphere Magenta sphere Viridian sphere Burgundy sphere Powder blue sphere Scarlet sphere Cyan sphere Azure sphere Lavender sphere Gray sphere Beige sphere Cerulean sphere Slate sphere Cobalt sphere Gunmetal sphere Copper sphere Bronze sphere Khaki sphere Citrine sphere Maroon sphere Olive sphere Peach sphere Cream sphere Sangria sphere Plum sphere Emerald sphere Cerise sphere Mauve sphere Moccasin sphere Aquamarine sphere Pearl sphere Turquoise sphere Platinum sphere Tan sphere Bittersweet sphere Periwinkle sphere Sapphire sphere Fuchsia sphere Dark green sphere Mahogany sphere Sea green sphere Claret sphere Lime sphere Amber sphere Ecru sphere Taupe sphere Tawny sphere Lilac sphere Ochre sphere Sepia sphere Celadon sphere Rust sphere Orchid sphere Ash gray sphere Steel blue sphere Sky blue sphere Burnt orange sphere Brick red sphere Caramel sphere Marigold sphere Burnt sienna sphere Verdigris sphere Indochine sphere Carmine sphere Linen sphere Goldenrod sphere Butterscotch sphere Dark gray sphere Harlequin green sphere Amaranth sphere Ultramarine sphere Royal blue sphere Garnet sphere Ebony sphere Ivory sphere Thistle sphere Jade green sphere Auburn sphere Sienna sphere Umber sphere Cadet blue sphere Dark brown sphere Orange peel sphere Salmon sphere Wisteria sphere Persimmon sphere Apricot sphere Brass sphere Ruby sphere Mint sphere Forest green sphere Aubergine sphere Hazel sphere Topaz sphere Bisque sphere Spring green sphere Rainbow sphere
An example of an induction charging of two metal spheres. The metal spheres are supported by insulating stands so that any charge acquired by the spheres cannot travel to the ground. The spheres are placed side by side (see diagram i. below) so as to form a two-sphere system. Being made of metal (a conductor), electrons are free to move between the spheres - from sphere A to sphere B and vice versa.
The volume of a bubble can vary depending on its size, but generally, bubbles are small spheres filled with gas. The volume of a bubble is determined by its radius and follows the formula for the volume of a sphere: V = (4/3)πr^3, where r is the radius of the bubble.
Depending on what size you want, you can get a balloon, and blow it to appropriate size, then cover it with paper mashay, and when it dries, pop the balloon, and paint the sphere to look like earth. Another option is go to Michael's craft store and just buy a Styrofoam ball, and paint it.