When parachute strings are longer, there is more surface area of the strings exposed to the air. This increases the overall air resistance experienced by the parachute system as a whole, making it slower to fall.
Bigger parachutes have more surface area, which creates more air resistance. This air resistance slows down the descent of the parachute, causing it to take longer to reach the ground compared to a smaller parachute with less surface area.
The larger surface area of the parachute creates more air resistance, slowing down its descent. This increased drag counteracts the force of gravity, causing the parachute to take longer to reach the ground.
The larger the size of the parachute the more air resistance is caused because its larger surface traps more air. Becuase there is more air resistance the larger the parachute the slower it travels to the ground. The smaller the parachute the faster it falls to the ground for the opposite reason.
A larger parachute will experience more air resistance, which slows down its descent and results in a longer landing time compared to a smaller parachute. This is because the larger surface area of the parachute allows for more air to be captured and creates a greater drag force, which counters the force of gravity pulling the parachute downwards.
The size of the parachute affects air resistance because a larger parachute will have more surface area interacting with the air, creating more drag. This drag helps to slow down the descent of the object attached to the parachute. Conversely, a smaller parachute will generate less air resistance and may result in a faster descent.
The 'best' length for a parachute string depends on what the parachute is for and the rest of the design. If a parachute's strings are too short, the whole parachute could collapse. If the parachute's strings are too long, there may be some wobbling and bungeeing about, more twisting of the strings, etc. Parachutes for heavy things (like spacecraft) tend to have longer strings than parachutes for people, since they're less affected by this instability.
Bigger parachutes have more surface area, which creates more air resistance. This air resistance slows down the descent of the parachute, causing it to take longer to reach the ground compared to a smaller parachute with less surface area.
The larger surface area of the parachute creates more air resistance, slowing down its descent. This increased drag counteracts the force of gravity, causing the parachute to take longer to reach the ground.
The larger the size of the parachute the more air resistance is caused because its larger surface traps more air. Becuase there is more air resistance the larger the parachute the slower it travels to the ground. The smaller the parachute the faster it falls to the ground for the opposite reason.
A larger parachute will experience more air resistance, which slows down its descent and results in a longer landing time compared to a smaller parachute. This is because the larger surface area of the parachute allows for more air to be captured and creates a greater drag force, which counters the force of gravity pulling the parachute downwards.
The size of the parachute affects air resistance because a larger parachute will have more surface area interacting with the air, creating more drag. This drag helps to slow down the descent of the object attached to the parachute. Conversely, a smaller parachute will generate less air resistance and may result in a faster descent.
The larger surface area of a big parachute creates more drag or air resistance compared to a smaller parachute. This increased drag helps to slow down the fall more effectively. Additionally, the shape and design of a big parachute are optimized to catch more air, further enhancing its braking effect.
A parachute creates air resistance as it falls, slowing down its descent. The increased surface area of the parachute allows for more air resistance, counteracting the force of gravity. A stone, on the other hand, has a smaller surface area and experiences less air resistance, leading to a faster descent.
A larger parachute creates more air resistance due to its increased surface area, which helps to slow down the descent. This is because the drag force acting on the parachute is proportional to its size. Additionally, a larger parachute can provide more stability and control during descent.
Yes, the area of a parachute directly affects how fast it falls. A larger parachute will create more air resistance, slowing down its descent, while a smaller parachute will fall faster due to less air resistance.
if the parachute is wider there will be more air resistance which slows things down and if there are holes the air can pass through which decreases air resistance. so the wider it is the slower it is.the lighter it is the slower it is
A parachute jumper slows down due to air resistance pushing against the open parachute. As the parachute increases in surface area, it creates more drag, which counteracts the force of gravity pulling the jumper down. This results in a gradual decrease in speed until the jumper reaches a safe landing velocity.