Unconventional Switch - Energy Drinks

 

                Unconventional Switch: Energy Drinks

 For our switch, we decided to base it on one of our member's love for caffeinated beverages. Power is drawn from a nine volt battery into a breadboard. Two monster energy drinks are then connected with alligator clips to the breadboard, and a physical connection between the cans makes the green LED turn on. While this concept might seemingly have no practical applicability in the real world, a switch like this could perhaps be used in a vending machine or a similar device, as it can detect when two cans are in contact with each other; however, it's still more of a creative design.

             

 

   
    

Unconventional Switch: The Chopstick Chop-Switch

By Electronics Team 10: Gary Hazelgren & Briah Bellamy

    For our unconventional switch, we wanted to use a concept with an object that could test other objects of their conductivity rather than just using one's own for power. Instead of pulling out the old electronic conductivity (EC) meter, what if we could, for example, use chopsticks to test it? Our design uses two chopsticks with wrapped on one end in aluminum foil, one 9V battery, one breadboard, one green LED, one 100 Ohm resistor, four male-to-female alligator clips.

    The chopsticks function practically like an analog EC meter, using their touch to measure how conductive various materials are: The LED light will light up if an object the chopstick touches is conductive enough for an electrical current to go through, and will stay off otherwise, making it an interesting way to learn the electrical properties of different things!

Team 18 - Unconventional Switch (No Phone Distractions!)

As soon as it came time to start brainstorming ideas for what unconventional switch we should make, our first ideas kept circling back into something that could be useful, help someone be productive or encourage them to stay focused on a task.

We know how easy it is to get distracted by all the notifications and colorful apps on our phones so we wanted to make a switch to help combat that. For our switch, you set it on your desk or workstation area, and then set your phone on top of the pad covered in tinfoil. When the phone is set on the pad, a red LED light turns on, and it sends a signal to pin A2 on the Circuit Playground. Then, a delay sends a signal to pin A1, which is connected to the green LED light. The goal of this switch is to help the user stay focused on their work, encouraging them to not pick up their phone as long as the green LED is off. After about 30 minutes, the green LED light will turn on, which lets the user know they are allowed to take a break and check their phone if they wish. But, the user will need to be careful with getting distracted for too long. Our switch aims to help prevent that, and keep the user focused on their task and getting work done.

Unconventional Switch, The Backpack Alarm

For our switch we used the zipper of a backpack. The idea of the device would be an anti-theft device. When 2 zippers on the backpack are connected the device would remain off. However, if the backpack were to be opened the 2 zippers would break the circuit sounding the alarm or lighting a light to alert the owner of the backpack that someone has unzipped it. When the zippers are closed the 2 zippers would barely touch so all it would take to alert the owner of the backpack is a slight unzipping of the backpack. You could also design a switch to the arm and disarm the device so that the real owner of the device would now sound their own alarm.

Unconventional Switch: There's No Place Light Home

The switch here uses 5V power using the Adafruit Circuit playground limiting the voltage coming from a mini-USB cable. The “switch” consists of two shoes with foil wrapped around the heels. When the heels touch, they LEDs on the shoes light up. This device provides excellent feedback for all those people who feel stuck in the world of Oz, or any other realm that can be exited via clicking heels. To encourage safety and the longevity of the product, we have limited the lights by adding a 100 Ohm resistor to prevent the lights from glowing too brightly and burning out.  After all, who knows when someone’s friend is prone to burning?
Note: Product may put user at increased risk of flying monkey attacks.

 

They say that necessity is the mother of invention, and our group’s switch embodies that idea. We had an excellent idea where we’d draw a schematic of our switch with a conductive pencil, then have that schematic connect the wires to make the LED turn on. Unfortunately, we lost the pencil we were going to use, so we had to improvise. Luckily for us, we had the perfect substitute: a banana.

Our switch works as follows: We have the battery, connected to a resistor, connected to one set of diode that we poked through a notebook, unconnected to the next set, which is also poked through said notebook, which is plugged into a breadboard, which is connected to an LED, which is then connected back to ground. Then, we place the banana on top of the two diodes, which completes the circuit and lights up the LED. Then, to turn off the LED, you simply pick up the banana.

While our switch might not have been what we initially planned, I think we did well. We might have slipped on a metaphorical banana peel when we lost the pencil, but luckily all we needed was that banana.

Electronics Team 22 Unconventional Switch - Magnets

 

For our original switch concept we wanted to start with trying to decide on a material that was first and foremost conductive and could easily be separated and connected again so we decided on the idea of using two circular magnets. From there we tried to see if there was a higher abstract representation that we could build out of the idea of two circular magnets coming together. We worked through a few different explorations about things coming together and landed on the idea of eyes being over the magnets that come together when the magnets are connected. This idea allows us to make use of the circular shape of the magnets to help sell the imagery of eyes with the physical magnets acting as a sort of frame for eyes to peek through. When the eyes are together they form a connected vision with the magnets completing the circuit. Once this circuit/connected vision is active and “seeing” the LED lights up to reflect that idea.