Tag Archives: Electricity

What’s a Potentiometer? All About our Knob Dimmer DIY Kit

A potentiometer is a type of resistor. The word itself derives from the phrase “voltage potential,” and “potential” is used to refer to “strength” (Academickids.com). Resistors control the flow of the electric current in a circuit. Think of a kink in a garden hose that stops the water from flowing. 

Where can we find resistors in our daily life?

Resistors are used in all sorts of common household appliances, like light dimmers (which we’ll be making in this kit!) and also used to adjust volume on items such as televisions and radios. 

Light dimmers are resistors that let you control the amount of energy flowing to your lights. Adding more resistance reduces the brightness. We can also set up a potentiometer as a knob turning left and right. 

Making our Knob Dimmer DIY Kit

The Knob Dimmer DIY Kit is a project in the Electronics and Circuitry series—a group of projects that encourage hands-on learning in accordance with NGSS Standards for Energy and Energy Transfer. Through these projects students can explore scientific ideas to design, test and refine a device that converts energy from one form to another (4-PS3-4).

Let’s take a look at how we make a circuit and our own DIY light dimmer using the kit. We’re going to be using a breadboard because they’re the perfect vehicles of electronic experimentation! For more on breadboards, head to our recent blog post here

First, we insert the jumper wires and the LED into our breadboard. Then, it’s time to insert the switch! Finally, to test our project, we send current to the potentiometer. 

 

Turn the knob in either direction to direct the flow of the current through either color LED on one side or the other. We can compare the circuits and remember when we decrease resistance, we allow more electricity to flow.

What have we made? What can we do with it?

Now you and your students have just made a circuit incorporating a potentiometer…and also a light dimmer miniature exposé! Next comes the best part—encourage your students to take the circuit back apart and start experimenting. Have you already put together our BreadBoard Basics DIY Kit? Try combining the cumulative materials of both into an even more advanced circuit.  

Did you or your student make an interesting new project with a multi-path circuit using our DIY Kit components? Upload a snap of your project on any social media and tag us for a chance to be featured on our page. Time to crank up the imagination and creativity!

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How Does a Breadboard Encourage Experimentation? Why Is That Important for Learning? All About Our Breadboard Basics DIY Kit

Curiosity and the urge to solve problems are the emotional hallmarks of our species.

—Carl Sagan

A curious mind thrives on the art of play and experimentation. One of the ways that we can encourage experimentation is through engineering, which is the “practical application of scientific knowledge to solve everyday problems.” (Ed.gov

Engineering relies on the art of testing and prototyping, which is an early sample, model, or release of a product built to test a concept or process. (Wiki) A prototype is like a first-draft where students can test out what works and what doesn’t. 

What is a breadboard? How does it encourage exploration?

A breadboard allows the mind to harness the desire to explore, test, and prototype without the burden of soldering. Students can test out different circuit paths without having to make permanent wire-splices, which makes it that much easier to have fun with problem-solving and building! 

In the kit, we use the breadboard to make and test out experiments. The breadboard has pins that are connected using conductive metal. Each row is a team of pins that share electricity and we send electric current using jumper wires. 

A battery has two terminals (positive and negative) that fit into the breadboard pins. Then, we insert the LED terminals into the breadboard and use that to visually show us our “test results”. 

We use the conductive metal tip of brass fasteners and the jumper wires to create two closed circuits. This is called a multi-path circuit. In order for the LED to light, its circuit must make a complete circular path back to the battery. 

From here, students can begin to take on more and more complex projects involving breadboards, such as Curious DIY Kits: Light Sensitivity, Knob Dimmer and Wireless Electricity. 

How does exploration create an environment for learning?

In our last blog post, we talked all about how curiosity leads to deeper learning. When we experiment, we foster imagination. The first step to learning is to admit that we don’t know something. Then, the fun begins when we start to discover how and why something works. Like Anatole France said, “The whole art of teaching is only the art of awakening the natural curiosity of young minds for the purpose of satisfying it afterwards.” With our Breadboard Basics DIY Kit, students are set up to tinker and explore….and hopefully discover!