I want to be a soccer player but my parents are telling me to do engineering what shoould I do?
First, its football not soccer.Second, its not an exclusive field, nobody ever said that you can never be a footballer if you become or start studying Engineering.I first kicked the ball when I was mid-way in my Engineering, by the time I completed- I wouldn't say I was good, but for someone who started the game only 2 years I was decent enough to play in my college league (no big deal though). Assuming, by your passion, that you are already good, your education will not be a burden if you stick to it, your University will give you chances, its up to you how you take it. Because if you really that good a couple of years in University competition you can decide which direction you need your life to go, try local clubs, keep playing don't let your education get in your way in terms of your passion, and don't let football a problem for your future, try becoming a graduate. And, let your game do the talking, find chances to exhibit. Good luck! I hope to hear your name as a footballer a few years from now.
A soccer ball is kicked with the initial speed of 10.9m/s . After 0.770s it is at its highest point. What was?
A soccer ball is kicked with the initial speed of 10.9m/s . After 0.770s it is at its highest point. What was its initial direction of motion? The answer should be theta in degrees
How do you deflate a soccer ball?
You can use the same pin to deflate It. But now, You have to insert the pin and when it reaches half it's original length, stop and push it in any direction away from the center.This essentially will make the hole grow bigger temporarily and help air to escape out.This is the one thing I could think of. Or you could use any mechanism that will open up the center hole temporarily.Hope this helps!Good luck.
Is it possible to major in Engineering AND play a sport in college?
It depends how disciplined you are. It is quite doable to play a varsity sport and complete an engineering degree, but its not possible to do that and go to all the parties and social events one often associates with college. If you don't think you have the self-discipline to do both, consider intra-mural sports. Its not nearly as competitive, but you're not practicing all the time either.
Erica kicks a soccer ball 12 m/s at horizontally from the edge of the roof of a building which is 30.0m high.?
The vetical distance is 30m, The vertical velocity is zero, so the ball falls under the influence of "g". distance = ½at² so t = √(2d/a) = √60m/9.81m/s²) = = √(6.1162) = 2.473 seconds Vertical velocity = acceleration × time V = 9.81m/s² × 2.473seconds = 24.5m/s Horizontal Velocity is still 12m/s Total velocity = √[(24.5m/s)²+(12m/s)²]
Can you play basketball with a soccer ball?
If you want to burn cash on a nice piece of sports equipment for a completely different sport, then yes. Similar to how you can play badminton with a tennis racquet. You just might break your wrist in the process, but hey, that's fine. Non-sarcastic answer: yes you can, but please don't. It's an unwise decision. Plus you just fired me up.
What is a use of simulation in mechanical engineering?
Exponent uses modeling and simulation to assist in design and failure analysis by evaluating the effects of loads on systems or products. The team comprises an interdisciplinary staff with experience in applying its integrated capabilities to a breadth of engineering issues. Our projects range from medical devices to satellites to downhole tools for the oil and gas industry. Exponent utilizes the most advanced software available for finite element analysis (Simulia Abaqus, ANSYS, and LS-Dyna) and fracture mechanics (FRANC3D and NASCRAC), and maintains a high performance computing cluster for executing simulations. The team can tackle any modeling problem, no matter the size of the assembly or the complexity of the materials involved. Additionally, Exponent’s laboratory facilities enable our team to obtain experimental results to supplement and validate our analytical models.Servicesservices include:Finite element analysisFracture and fatigue analysisVibration and rotating equipment evaluationMaterial constitutive modeling, testing, and evaluationCoupled structural, thermal, and fluid dynamics analysisFluid/structure interaction analysisFigure 1. Damage to an I-beam due to detonation of explosives during demolition.Figure 2. Shearing of a large diameter drill collar with a BOP shear ram.Figure 3. Analysis of new hydroelectric rotors to assess compliance with specifications.Figure 4. Impact of soccer ball on fire sprinkler guard.Figure 5. Braided wire nitinol neurovascular aneurysm device in its initial shape, crimped onto a catheter, and then deployed into a bifurcation aneurysm
A soccer ball is kicked with an initial speed of 10.4m/s in a direction 20.0 degrees above the horizontal.?
Identifying the vertical and horizontal components is the real secret to solving projectile motion problems. The vertical component involves using the equations below: v = u + at …….. OR ……. v(y) = u(y) + at v² = u² + 2as ….. OR …… v(y)² = u(y)² + 2as s = ut + ½at² ….. OR …… s(y) = u(y)t + ½at² (Note: all the equations above contain an acceleration term which will be a = g = -9.8 m/s²) The horizontal component involves this equation: v = s / t …. OR …. v(x) = s(x) / t (NB: no acceleration; just constant velocity) One last tip: positive (+) = upward negative (-) = downward --------------------------------------... Solution: Vertical component: v(y) = u(y) + at v(y) = 10.4*sin20° + (-9.8*0.35) v(y) = 3.56 – 3.43 = 0.13 m/s (moving up) Horizontal velocity: v(x) = 10.4 m/s (horizontal) The actual velocity is calculated by vectorially combining both the vertical and horizontal components, using geometry: v² = v(x)² + v(y)² v = √ (0.13² + 10.4²) = √ (0.017 + 108.2) v = 10.403 m/s Direction: Tan Φ = 0.13 / 10.4 Φ = 0.72° from horizontal, heading upward