One of AstroCamp’s best activities is our ropes course! From zipline to skycoaster, we encourage kids to push themselves to overcome the challenge. But there’s a lot of unseen work that goes into setting up these activities! One of the most important jobs is getting all the knots tied!
We use an assortment of different knots on our ropes courses. If you want a step-by-step instruction of how to tie a few of them, check out the video above!
The “Figure-8” and “Figure-8 on a Bight” knots feature heavily on the ropes course. They’re easy and strong knots, and feature heavily in rock climbing. The allow us to connect carabiners to the participants. The Figure-8 on a Bight is usually accompanied by some sort of stopper knot to prevent the line from slipping. If you’ve ever been attached to a rope at AstroCamp, it’s most likely been via this knot!
The third knot we show in the video is the “Alpine Butterfly.” It’s a unique knot in that it can be tied at any point on the rope without needing to access either end. It creates a fixed loop, where a carabiner or another rope can be attached. We use this knot on the skycoaster to retrieve the line after you’ve pulled the release cord. It’s also how we attach you to the haul rope that you use to get the skycoaster participant up into the air in the first place!
There are quite a few other knots that we use on the ropes course, but these are three of the most common. With just a small length of rope, you can practice them and become a ropes master!
All you need for this at-home science is a glass, a plate, a candle, water, a match, and a bit of caution, because we are dealing with fire.
Step 1: Pour the water on the plate
Step 2: Place the candle on the center of the plate
Step 3: Light the candle (or have a guardian light it for you)
Step 4: Place the glass down over the candle, step back and watch science happen!
This experiment is all about maintaining an equilibrium of air pressures inside and outside the glass. We usually experience air pressure as the force from the atmosphere pushing down on us. Here at AstroCamp we feel about twelve PSI, or pounds per square inch, of force which is the same amount of force that the water on the plate initially feels.
The flame heats up the air on the inside, creating a higher pressure than the air on the outside. Hotter air has a higher energy and therefore exerts more air pressure. The higher pressure pushes the water down and out of the glass. You should be able to see air bubbles in the water just outside of the glass from the air forcing the water out.
Fire needs oxygen in order to continue the combustion process in the glass, but because we trapped air in the there is only a finite amount. When the flame uses up all of the oxygen it goes out, which allows the air to cool. Cold air doesn’t have as much pressure as hot air and has less pressure than the air outside of the glass. Therefore the air on the outside of the glass pushes with greater force on the water than the air on the inside so the water is able to get sucked back up into the glass! When the water level evens out that is when you know you have reached an equilibrium of air pressures again.
We would like to thank you for visiting our blog. AstroCamp is a hands-on physical science program with an emphasis on astronomy and space exploration. Our classes and activities are designed to inspire students toward future success in their academic and personal pursuits. This blog is intended to provide you with up-to-date news and information about our camp programs, as well as current science and astronomical happenings. This blog has been created by our staff who have at least a Bachelors Degree in Physics or Astronomy, however it is not uncommon for them to have a Masters Degree or PhD. We encourage you to also follow us on Facebook, Instagram, Google+, Twitter, and Vine to see even more of our interesting science, space and astronomy information. Feel free to leave comments, questions, or share our blog with others. Please visit www.astrocampschool.org for additional information. Happy Reading!