Motor Design Blog

In the creation of our motors, we sculpted each piece a certain way to do a certain job. This blog will explain how each part worked as a whole.
The battery provided power to the entire motor, and was also the motor's base. It created the current so that the motor could operate. The arms, created out of two paperclips, held the coil up, as well as giving the current an area to flow through. If the arms were made of a non-conducting material, such as plastic or glass, the coil would not have received current, and therefore would not have worked. The rubber band held the arms to the battery. The coil was a copper wire, wrapped around my fingers several times, then scraped at the ends on one face of the wire. This spun, which would have powered a fan or wheels if it were attached to one. The magnet provided the magnetic field necessary to create a spin in the coil.
The motor turns how it does due to several factors. Without any one of these, the motor would not have spun. The magnetic field was up, and the current was straight ahead. The right-hand rule says that if these are true, then the force is to the right. The wire was only scraped on one side. This caused the wire to only receive current when it was positioned at certain positions. Because current-carrying objects fluctuate when exposed to magnets, and the coil was only carrying current at specific times and positions, the coil was only spun when exposed to the current, despite being in constant contact with the magnet's magnetic field.
This motor, if scaled up significantly, could be used to power car wheels, fans, or anything else that needs to spin. As it is, it would not provide enough power to make up for its own weight. With a more powerful and/or efficient energy source, however, the motor could power any spinning thing.

Unit Reflection - Electric Charge and Current

In this unit, we studied things types of current, how current travels, and how current powers things. Specifically, we studied Coulomb's Law, electric potential, Ohm's Law, types of circuits, different types of charge, and electrical resistance.

We studied Coulomb's Law in order to determine the charge of objects. Coulomb's Law states that the force of attraction or repulsion between two charged particles equals the constant k times the charge of the first particle (q1) times the charge of the second particle (q2), divided by the square of the radius between the two particle's centers.

If two particles each have a charge of 3 coulombs, and the radius of a circle placed in between them is 2, then they will repulse each other with an initial force of 3*3k/2^2=9k/4=2.25k newtons, with the force deceasing as the radius of the circle between them increases. K here is a number derived using calculations involving the speed of light and various Greek letters, and will not be discussed here.

Electric potential is the electric potential energy of an object divided by the charge of the electric field the object is in. Electric potential is measured in volts. Mainly, we used electric potential to determine the current of an object using Ohm's Law.

Ohm's Law is a formula that states that the current that flows through an object equals the voltage of the object, divided by the object's resistance. It is usually represented as I=V/R, where R is usually replaced with the Greek letter omega.

This is an omega.

Ohm's Law allows us to determine how much current is flowing through an object, which allows us to determine whether an appliance, such as a hairdryer, will operate sub-optimally, at full power, or overload and malfunction.

There are two types of circuits: parallel and series.

In the series connection, each object that draws power is connected in succession, while in the parallel circuit, each lightbulb is connected individually to the power source. In a series connection, each light must draw power from the same pool as the other two, which increases the resistance. This means that one must have a much higher electric potential to get full use from each light, as Ohm's Law states that as resistance increases, voltage must increase to give the same current. This essentially is adding traffic lights to the wire, slowing the current. The parallel circuit has multiple wires, allowing each light to light independently of the others. This decreases the resistance without decreasing the voltage, which Ohm's Law states will increase the current. This is like adding more lanes for cars on a road, allowing more cars to pass through the same road. Additionally, because all the bulbs in a series circuit are connected, if ones goes out, they all go out. This is not true for parallel circuits, where bulbs will remain independently lit.

There are several different types of charging an object. One way is friction charging. This involves rubbing an object against another object, causing one to take electrons from the other. This causes the giving object to become positive, and the taking object to become negative.

The balloon steals electrons from the woman's hair, causing it to become positively charged.

Another way is induction. An already-charged object is held close to an uncharged object, causing the uncharged object to polarize, meaning it becomes positive on one side and negative on the other. Capacitors charge and clouds create lightning this way.

Lightning, how induced charge between the earth and the clouds is dissipated.

We also covered electrical resistance. Resistance is measured in ohms. The symbol for an ohm is the omega, seen above. The resistance of an object is calculated by dividing the voltage of an object by the current flowing through the object. The result is the amount, in ohms, of resistance inherent in that object.