Sixth meeting (Tuesday, February 23)

Done!!!

Completed Machine

Calculating...

Weights

Final touches...

Fulcrum

    We brought our completed nifty lifting machine to school, and we started experimenting with how much input force it required to lift the output force, 600g, up 5 cm to find the actual mechanical advantage. We carefully placed colored pencils in the input force can, and as a result, we found that 103g was needed to complete work. These are the calculations we did:

Actual Mechanical Advantage = Output force divided by Input force
600g (Output force) divided by 50g (Input force) = 12

Actual Mechanical Advantage of our nifty lifting machine: 12

    Next, we wanted to find the ideal mechanical advantage of our machine. We measured the distance from the fulcrum to the input and output force for our lever. These are the calculations we did:

-Ideal Mechanical Advantage = the product of the mechanical advantages of every simple machine

-Mechanical Advantage of a block and tackle pulley = 3

-Mechanical Advantage of a lever = distance from fulcrum to input force divided by distance from fulcrum to output force
-Distance from fulcrum to input force- 83 cm
-Distance from fulcrum to output force- 18 cm
-83 divided by 18 = about 4.6

3(Mechanical advantage of block and tackle pulley) x 4.6  (mechanical advantage of lever) = 13.8

Ideal Mechanical Advantage of our nifty lifting machine: 13.8

    If we compare the actual mechanical advantage of 12 and the ideal mechanical advantage of 13.8, we can see how much effect friction has on our machine. A way to show this is through efficiency. To calculate efficiency ;

Efficiency = actual mechanical advantage divided by ideal mechanical advantage x 100

12 divided by 13.8 x 100 = about 87%

      The efficiency of a machine shows how much friction is lost, and we can see that 13% of the efficiency is lost due to friction.
      We are extremely satisfied with the outcome of our machine and our high mechanical advantages, and after four different designs, we are finally done with our machine. Yaaaaaay!!!!

Fifth meeting (Monday, February 7)

Before we began

4th & Final Design: lever and pulley #2

Constructed Machine

Working on the new design

Working...

     On class on Friday, we learned the two main types of simple machines; the lever and the inclined plane. We learned how different simple machines are variations of the lever and inclined plane, and we got one crucial fact from the lesson; the inclined plane causes the most friction, and lever causes the least friction. This was the reason why our inclined plane-and-pulley design wasn’t working, so we decided to go back to our old design of the lever-and-pulley.
    The only hurdle we faced was that there was no place to put the fulcrum. As we were digging around, looking for materials to use for our flexible fulcrum, we found two long pieces of wood. We thought that if we drilled a hole in each one, criss-crossed the two pieces of wood, and stuck something like a pin the overlapped hole, it could act as a flexible fulcrum. Excitedly, we completely dismantled and redesigned the machine by going back to our old plan, just with a different fulcrum. We quickly set up an inverted block and tackle pulley with the output force going downward and drilled holes for the fulcrum screwdriver to go through. We drilled two more holes on one piece of wood and put mini screwdrivers through them so the input weight and the string attached to the lever could hang off of it. It was perfect; with just little input force, the 600g weight rose over 5 cm.
    The main difference between this machine and the original lever-and-pulley machine was that the fulcrum was in different spots. By putting the fulcrum on the floor, it greatly improved our design.
    We learned the importance of perseverance because this was our fourth design, and we were glad that we hadn’t given up. Next meeting, which is going to be during science class, we plan to measure the exact amount of weight that is required to lift the 600g weight up 5 cm, and we also plan on doing calculations to find the ideal and actual mechanical advantage of our nifty lifting machine.

Fourth Meeting (Saturday, February 5)

Weighing the weights

Lever-and-Pulley Design

Setting up the Inclined plane-and-pulley design

3rd design: Inclined Plane-and-Pulley

Done with the inclined plane-and-pulley!

Inclined plane and pulley design

Our workspace

  
     Today we met at Ashley’s house, and we ended up experimenting with two different designs.
     First, we started making the new lever-and-pulley nifty lifting machine. We ran into a problem right away; there was no place to put the fulcrum. The only solution we thought of was connecting two wire ties and  making it hang off the top of the frame and putting the paper towel roll through the loop so it could act as the fulcrum. We taped the wire tie loop to the roll to stabilize the fulcrum. We used the textbook as a guide and attempted to create the most efficient lever we could possibly make, which was a first class lever. We read that the closer the fulcrum is to the output force, the greater mechanical advantage it has, so we followed this and tried to set up a first class lever. Unfortunately for us, although we spent ages trying to secure the wire tie onto the roll, we discovered a fatal flaw; we accidentally taped the wire tie near the input force, not the output, which would require more force than necessary.
    After we pried the fulcrum off and put it in its correct place, our lever was done. We hung the 600g weight off of one side of the roll, and on the other, we attached a string that was wrapped around a block and tackle pulley. The input weight was attached to the block and tackle pulley.  As we inserted weight into the input can, our machine was not moving at all. After much inspection, we found two problems with this design; first, the fulcrum was not flexible, which didn’t allow the lever to work, and second, the block and tackle pulley’s outputted force upward, not down, which meant that no downward input force could be applied to move the lever.     As a solution, we found that we could make an inverted block and tackle pulley to change the direction of the input force, but we didn’t bother experimenting with this because there was no way that we could think of that could create a flexible fulcrum for the lever.
    After that design, we decided to use a different combination of simple machines for our project; the inclined plane and the pulley. We decided to use a block and tackle pulley for a mechanical advantage of three, and a long inclined plane to increase distance and to decrease the amount of force needed. We were sure that this new design could help us make an efficient nifty lifting machine, so we started making a design and gathering materials.
    We set up the inclined plane with cardboard and a paper towel roll underneath the cardboard for support and made a block and tackle pulley. We tried to use the upward force that the block and tackle pulley exerted to try and lift the 600g can up the inclined plane by attaching weight to the pulley itself.
    We anxiously put weights in the input can, but nothing was happening. The weight was creeping up the inclined plane, but soon, our input weight became greater than 600g. When the input force is greater than the output force, there is no mechanical advantage, which does not meet the requirement of our assignment.
    We wondered why this was happening, because if we pushed down on the input can and let go, it was enough force for the weight to go up 5 cm. We figured out that this was happening because of friction. The friction stopped the weight from going up 5 cm like it was supposed to. We attempted to put plastic, matchbox cars, snowboard wax, and lip balm beneath the input can to reduce friction, but it still required too much friction. This machine was not successful because of too much friction. However, we thought that this machine could create positive results, so we decided to stick to this plan and replace the string with metal wire to reduce friction and think of other ways that could also reduce friction that was being caused by the inclined plane.
    This meeting taught us how different a design on paper and an actual machine is. There was so much friction, and we learned that it can hurt our machine because lots of energy is being wasted. Next meeting, we are going to stick to the inclined plane-and-pulley design and try and think of more ways to reduce friction.

Third Meeting (Friday, February 4)

Us working

    This meeting was short, but it was a time when we decided our future meetings and plans for the machine.
    We decided to stick to the schedule and try and build the lever - and- pulley nifty lifting machine. We also gathered new materials and thought of what items could act as the lever and fulcrum. We planned to bring tubes to act as the lever, wire ties to act as the fulcrum, and strong tape for next time.
    We learned through this meeting that sometimes, its important to plan to be prepared to actually construct the machine.

Second Meeting (Monday, January 31)

1st design: Wheel and axle and Pulley

 

What we constructed

2nd design: Lever and Pulley

    This second meeting was all about setting the machine up. We tried to construct the machine according to our plan, but we quickly ran into many problems.
    The wheel and axle was not secured to the frame (it hung by a single piece of string), so it kept tilting to one way or the other. Because of this, we couldn't hang the 600g weight off of it. Also, we found out that the block and tackle pulley had only one end of the string coming out of it, which was unexpected; we couldn't build our machine without the two ends coming out because we needed a place to put our input weight, so we had to improvise.
    After experimenting and running several trials, we found out that the block and tackle pulley had to be flipped to be upside down. This made our plan run smoother than before, but the problem with the wheel and axle still existed, because the 600g weight was unbalanced and we couldn't think of anything that would hold it up in mid-air. Above is a picture of the failed attempt and design.
    There were too many problems with this design, so we decided to change it. Our new plan was to use a lever and a pulley. Attached is a picture of the modified design. We plan to use hang the input weight off of the block and tackle pulley which will weigh down one end of the lever, which would bring the 600g weight that is connected to the other end of the lever, upward.
    Although we set up our original plan fairly well, we found out that actually building the machine and seeing it work is different from seeing the design on paper. Next time, we plan to create the new design and see what happens.

First Meeting (Friday, January 28)

Wheel & Axle-and-Pulley Design

Today, we met in the cafeteria to start working on our nifty lifting project. It was a brief meeting, but we accomplished a lot.
During class, we decided to use a wheel and axle-and-pulley design for our machine. Attached above is a design of our machine.
When weight is added to the input can, it moves the pulley which spins the wheel, which turns the axle, lifting the 600g output can. We looked at our design and tried to decide what materials were needed to construct our machine.
We found out that we need a screwdriver for the wheel and axle, two pulleys, string, two identical cans, marbles to act as weights, two hooks, and a frame to hang our machine on. We realized that we have all of the materials needed for our Nifty Lifting Machine available at our homes.
Next meeting, we plan on bringing the materials to actually start constructing the machine.

Us working on the blog