The gyro moves at a right angle to the applied force. This is very counter intuitive and is the basis of an inertial guidance system used in aircraft where 3 gyro's spin in three axes.
It's gonna be bruised.
increases
it might explode if you put it in a smaller space.
Output force is the force you put out of an object.
Input force is the force you put in to a machine. Output force is a force exerted by a machine.
It's gonna be bruised.
Anything that touches something else puts pressure on the point of contact. In some cases, such as tapping a finger on paper or a gyroscope spinning on a flat surface, that pressure is light enough to be negligible.
Only the fourth generation iPod Touch has a gyroscope. You can not have one put in.
Using a gyroscope in a vehicle has been among the favorite topics of science fiction writers for a long time, primarily because writers aren't necessarily competent engineers. What would be the advantage of a gyroscope? There would be the possibility of recapturing some of the kinetic energy as the vehicle slows, especially if you could find a way to put that energy into the spinning gyroscope. However, the extra mass of any gyroscope that would be able to store that much kinetic energy, would also make the vehicle far too heavy for practical operation. If something like that were practical, automotive engineers would have jumped on it; but if you believe that there is a practical use of gyroscopes in automobiles, perhaps you could develop such a vehicle and make yourself rich.
it might explode if you put it in a smaller space.
increases
when we put some salt in coca cola,it pushes out with some force not grater .as a mint in coca cola
The fundamental idea behind the working of a gyroscope is that of conservation of angular momentum. But to understand this idea more fully, it may help to explain a few things, so let's dive in by talking about a wheel and axle and how its mounted. If a wheel or disc spins about a center on a axle, that spinning wheel carries with it some kinetic energy. The wheel has mass, it took energy to set it spinning, and it is now spinning, hence the energy of its spin (momentum). If we then mount the axle in a ring, we can hold the ring and the wheel will spin on the axle. Now we'll mount the ring with the spinning wheel in it. When we look at the ring with the spinning wheel in it, we can find two points on our ring that are in the plane of rotation of the wheel. We then put two small "stubs" out from there and mount our first ring in another ring. The mount will allow us to hold the outer ring and allow the inner ring to move independently. Lastly, we take a third ring and mount the whole thing inside that one. But we need to be sure to pick two points on the plane of rotation of the wheel, but 90 degrees from the points where the innermost ring mounts to the second ring. We have set up gimbals so the outer most ring can be mounted to an object and the inner rings will allow the axle of the spinning wheel to always point in the same direction. The use of very low friction components in our mountings and the application of electromagnetic pulses to keep the gyroscope spinning will insure things keep working. And by using sensors to keep track of the orientation of the rings, we can use this device to keep track of movement. The Wikipedia link below will allow an investigator to jump to the gyroscope article posted there. It is extremely helpful because the moving diagrams there will allow inspection of a gyroscope in action. With the outermost frame mounted and the gimbals operating properly, the axle, which is the axis of rotation of the wheel, will always point in the same direction regardless of the orientation of whatever the frame is mounted to.
ummmmmmmmmm yea i dont know thats why i came here! Well you know what people, no one really cares for what you put. We need the right answer!!!
You cannot physically put a clutch disk in backwards unless you force it together. If you do this you will destroy the clutch disc and possibly other clutch components.
When camphor hits water, it will begin to spin around in circular motions. This is because the camphor has rough edges, and the water is pushing on it on all sides. When you place the tip of your finger on the surface of the water though, the oil on your finger spreads across the water (pushing the camphor away from your finger)and gets under the camphor to stop it from spinning (the oil blocks the contact of the water and camphor). Once removed, the camphor will start to spin again. After a time has passed, the camphor will stop spinning all together and most will dissolve into the water itself.
spinning is the process of spreading a thin layer of polymer on the surface of a wafer by spinning the wafer at high speed. It is used in MEMS processes because it is an inexpansive method to put photoresist on silicon wafer.