#terminalvelocity #ngscience @NGScience #skydiving https://ngscience.com When an object or person falls from a great height, they are pulled towards the surface of the Earth by the force of gravity. As the object or person falls, they accelerate, meaning they move faster and faster towards the ground. However, the air resistance or drag force pushes against them, slowing them down. At some point, the drag force becomes equal to the force of gravity, and the object or person stops accelerating. This is called terminal velocity, which can be different for different objects depending on their shape, size, and mass. Terminal velocity for a human falling through the air is around 120 miles per hour or about 193 kilometers per hour, which is far too fast to safely reach the ground. This is where a parachute comes in! A parachute increases air resistance due to its shape and size, creating a larger surface area for the air to push against. This slows down the person or object's descent, allowing them to land safely on the ground. Understanding the dynamics of free fall and the crucial role of a parachute in slowing descent is a fundamental concept in physics, with practical applications in activities like skydiving. This exploration delves into the forces at play during free fall, the phenomenon of terminal velocity, and how a parachute effectively reduces speed for a safe landing, offering a comprehensive look at the principles governing these processes. The Forces in Free Fall When an object or person falls from a height, two primary forces act upon them: gravity and air resistance. Gravity, a constant force, pulls the object towards the Earth, causing it to accelerate. This acceleration means that, with each passing second, the object's speed increases as it continues to fall, a principle encapsulated in Newton's second law of motion. However, as the object accelerates, it encounters air resistance or drag force, which increases with the square of the velocity, pushing up against the object and opposing the force of gravity. Understanding Terminal Velocity The concept of terminal velocity arises when the upward force of air resistance equals the downward force of gravity, causing the net force on the object to be zero. At this point, the object ceases to accelerate and continues to fall at a constant speed. Terminal velocity is determined by various factors, including the object's mass, surface area, and shape, as well as the density of the air it falls through. For humans, terminal velocity is approximately 120 miles per hour (193 kilometers per hour) when falling with limbs extended, creating a balance between gravity and air resistance. The Role of a Parachute A parachute drastically increases the surface area exposed to air resistance, significantly slowing the descent of a person or object. By deploying a parachute, a skydiver increases drag force in a controlled manner, allowing for a gradual deceleration and a safe landing speed. The design of the parachute, including its size, shape, and material, is optimized to maximize air resistance and ensure stability during descent. The Physics of Parachutes The efficacy of a parachute can be explained through principles of physics and fluid dynamics. Upon deployment, the parachute creates a large surface area in contact with the air. According to Stokes' law, the drag force experienced by an object in a fluid (in this case, air) is directly proportional to the object's velocity and its surface area. Therefore, the parachute effectively increases the drag force, reducing the skydiver's velocity to a safe landing speed. Practical Applications and Safety Measures The use of parachutes is not limited to skydiving but extends to various fields, including space exploration, where parachutes are used to safely land spacecraft on Earth or other planets. The design and testing of parachutes involve rigorous engineering and physics calculations to ensure they can withstand the forces experienced during deployment and descent. Safety measures are paramount in activities involving parachutes. This includes proper packing of the parachute, regular maintenance checks, and ensuring that skydivers are adequately trained to handle potential malfunctions. Backup parachutes are also a critical safety feature, providing an additional layer of security in case of primary parachute failure. Experimenting with Homemade Parachutes Designing and testing homemade parachutes offer a practical understanding of the principles discussed. By using simple materials such as plastic bags, strings, and small objects to serve as the payload, one can create a basic parachute model. Timing the descent of these parachutes from a fixed height can provide insights into how changes in design affect the rate of fall. Variables such as the size of the parachute, the weight of the payload, and the material's air permeability can be adjusted to observe their impact on the parachute's performance.

• published: 12 May 2023
• views: 104191