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Norma releases a bowling ball from rest it rolls down a ramp with constant acceleration After half a second it has traveled 0.75m how far has it traveled after two seconds?
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∙ 14y ago
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∙ 14y ago
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What is an x-factor?
it is an bowling ball made by storm products. they produce bowling balls and accessories. their is an x-factor and an x-factor 2 of which i own. great bowling ball.
What makes a bowling ball harder to stop than a soccer ball when they are both traveling at the same speed?
The bowling ball is harder to stop because it has a greater mass, and therefore a greater momentum. But the answer is that the bowling ball has a greater mass.
Does gravity pull things down 32.2 feet per second?
Absolutely Not.Gravity is NOT a pulling Force. Gravity is a "Pushing" Force of Mass Expansion.Earth Mass is Expanding at the Gravitational Acceleration rate of 9.808175174 m/s^2In order to understand you must first accept the Mathematics on EinsteinElectricitydotcom because Math does not lie. Then you can move on to EinsteinGravitydotcom.Acceleration due to gravityNo. There is a difference between speed (or velocity) and acceleration. They are, of course, related, but acceleration is the rate of change of velocity. When you are sitting in your car at a red light and the light turns green and you step on the gas (or accelerator!), your car accelerates from zero to some final velocity (hopefully not much more than the posted speed limit). Your speedometer clearly shows the change in velocity as the needle moves clockwise. The faster that needle moves, the greater the acceleration.On Earth, objects do not fall at constant speed, as your question suggests. Gravity accelerates objects toward the center of the Earth at 32.2 ft per second per second (which can also be written as 32 ft/s2). In other words, an object's velocity will increase by 32.2 ft/s (or 9.8 m/s) for each second the object falls until it reaches its terminal velocity, which you can think of as a kind of speed limit. Terminal velocity is reached when air friction equally opposes the force of gravity. Different objects will have different terminal velocities, depending upon their shapes.More discussionImagine you are on top of a tall building and holding a bowling ball over the side of the building. At time t = 0 seconds, you let go of the ball. At that exact moment, the ball is traveling at 0 ft/s, but as the ball experiences gravity without your holding it, it starts to fall. After one second, the ball will be traveling 32.2 ft/s. After two seconds, it is traveling 64.4 ft/s, and after three seconds, it is traveling at 96.6 ft/s.So you see that falling objects do not fall at the constant rate of 32.2 feet per second but actually accelerate -- that is, pick up speed -- at a rate of 32.2 feet per second per second.Note: The equation of rectilinear motion can be found at:Uh, Update: This article doesnt seem to mention "terminal velocity." Eventually, a falling bowling ball will not continue to pick up speed, it will reach Terminal Velocity, and stay at that speed. Terminal velocity is reached as the air resistance on a falling object approaches the momentum of the object. For example, as a bowling ball falls, gravity makes it accelerate at 32.2 feet per second. The bowling ball also hits air molecules, which slows it's acceleration. This is air resistance. As the bowling ball falls faster, more air molecules hit it per second. This is because the bowling ball travels a greater distance per second and passes through more air, and more air molecules. Eventually, the combined forces of all of the air molecules negate the acceleration of the bowling ball. At this point the bowling ball neither accelerates nor decelerates, it reaches an equilibrium. It will keep falling at a constant speed: its terminal velocity. If it were to somehow fall faster than its terminal velocity, the extra air molecules that hit it would actually slow it down until its terminal velocity was once again reached.An object's velocity, then, is determined both by its weight and its shape relative to the ground. If an object is small, like a bowling ball, it does not pass through many air molecules per second, and must travel faster to hit enough air molecules per second to reach terminal velocity. If an object's surface area is large, like a parachute, it does not need to be traveling as fast in order to hit enough air molecules per second. yep your right agree subscribe
Write an algebraic expression that repressents the cost of bowling N games if the charge is 2.50 a game and 3.25 to rent bowling shoes?
N2.5 + 3.25 is the expression.
What unit would be appropriate to measure a bowling lane?
feet
What is the acceleration of a bowling ball when at rest at the end of the bowling lane?
The acceleration of a bowling ball at rest at the end of the bowling lane is 0 m/s^2. Since the ball is not changing its velocity, it is not experiencing any acceleration.
How much force N is needed to knock over a bowling pin?
It typically takes about 110-130 Newtons of force to knock over a standard 15-inch-tall bowling pin. This force can vary depending on factors such as the weight of the bowling ball and the angle at which it strikes the pin.
How much force is needed to accelerate at 25 kg bowling ball at?
The force required to accelerate a 25 kg bowling ball can be calculated using the equation F = ma, where F is the force, m is the mass of the bowling ball, and a is the acceleration. If the acceleration is given, you can plug in the numbers to find the force needed.
Where what a bowling ball and a napkin fall with the same acceleration?
In a vacuum, both a bowling ball and a napkin would fall with the same acceleration due to gravity, which is approximately 9.81 m/s^2. This is because in the absence of air resistance, all objects experience the same acceleration regardless of their mass.
Were would a bowling ball and a napkin fall with the same acceleration?
Both the bowling ball and the napkin would fall at the same rate of acceleration due to gravity, assuming no external forces are acting on them. This is because all objects experience the same acceleration due to gravity, regardless of their size, mass, or shape.
What are some real life examples of Newton's second law of motion?
The second law of motion states that the acceleration of the an object depends on the mass of the object and the size of the force acting on it a good example is bowling because the acceleration of the bowling ball hitting the pins are hitting the shape and the size of it. And the force acting on it is the bowling ball and bowling pin that is an example of the second law of motion.
Does a bowling ball have more force than a feather?
Well according to the equation Force = Mass x Acceleration. A bowling ball has more mass than a feather but it all depends on how much acceleration each is undergoing. Potentially a feather can have more force (if the bowling ball has an acceleration of zero, then there is no force being produced, and if the feather is accelerating at any speed greater than zero, thentechnicallyit has more force)
What is the weight in newtons of a 9.5 kg bowling ball?
The weight of a 9.5 kg bowling ball can be calculated using the formula: weight = mass * acceleration due to gravity. The acceleration due to gravity is approximately 9.81 m/s^2. Therefore, the weight of a 9.5 kg bowling ball is about 93.95 Newtons.
How much force it needed to accelerate a 25 kg bowling ball at?
The force needed to accelerate a 25 kg bowling ball would depend on the desired acceleration. Newton's second law states that force equals mass multiplied by acceleration (F = ma). If you specify the acceleration, the force required can be calculated using this formula.
Where would a bowling bowl and a napkin fall with the same acceleration?
In a vacuum chamber. C. On the moon.
Is the weight of an object dependent on mass?
No, look at a the the size of a beachball and the size of a Bowling ball. Answer2: Yes. The weight of an object is dependent on mass. Weight = mass times gravity acceleration g, W = mg.
What is the acceleration of a 6.4 kilogram bowling ball if a force of 12 N is applied to it?
12/6.4=1.9m/sec2
