VECTOR ADDITION Exp

VECTOR ADDITION Exp. #4

(Alward/Harlow web File: “vector.doc” 1-25-04)

Name: ______Partners: ______Section No. ______

(Note to instructor: In PHYS 23 when this lab is paired with Experiment 1, time may require that Part IV be skipped.)

Equipment: Force table 3 x 50 gram (Beck) weight hangers 1 x 20 g 2 x 50 g

1 x 100 g 1 x 200 g Scissors Ruler Protractor Washer 3 pulleys

Retaining pin 3 x 50 cm lengths of string

I. PURPOSE

The primary purpose of this exercise is to learn how to add vectors using the graphical method of tail-to-head addition and the more exact method of addition of components. A secondary purpose of this exercise is to introduce the idea of forces as vectors. In addition to the investigating the basic techniques of vector addition, the student will verify that the vector sum of all external forces acting on an object is zero if the object is not accelerating.

Three strings attached to a small ring and passing over pulleys will support three different hanging masses. The weights of these masses are the forces acting on the ring. Each weight is equal to the mass, m, multiplied by the acceleration due to gravity, g. In the Standard International system of units weight (force) is measured in Newtons.

II. PROCEDURE

1. Attach three strings to a central ring, and pass each string over a different pulley positioned at the perimeter of the circular force table. While adjusting the positions and weights, place a short metal rod or pin in the center hole to prevent the masses from falling. At the ends of the three strings place weight hangers and weights. Place the masses shown in the table at the end of the strings. Note: the values shown include the 50-gram mass of the hanger.

2. Calculate the weight of the each of the masses: the weight, in Newtons (N), is given by m times g, where m is in kilograms and g = 9.8 m/s2. (Note: kg- m/s2 = N). Places these weights F1, F2, and F3 in the table on the next page.

3. In this lab, all angles are measured counter-clockwise from the x-axis. Place one of the pulleys at the zero degrees mark; this will be Pulley 1. Pulley 2 should be somewhere between 80-180 degrees, and Pulley 3 is somewhere in the third quadrant, between 180 and 270 degrees. Adjust the positions of Pulleys 2 and 3 until the ring remains motionless at the center of the force table, not contacting the central pin.

1

m1 = 0.120 kg / m2 = 0.200 kg / m3 = 0.250 kg
F1 = N / F2 = N / F3 = N
1 = 0 degrees / 2 = / 3 =
F1x = N / F2x = N / F3x = N
F1y = N / F2y = N / F3y = N
Sx = N / Sy = N / S = N
Average Force = N / Percent Difference: %

Note: It is very important to reposition the strings grip on the washer each time you move the pulleys: the strings must not approach the washer tangentially; they must be perpendicular to the washer and point toward the exact center of the washer, otherwise the angular measurements will be false. Check the strings often; check them now.

Test equilibrium by removing the pin and deflecting the ring by one or two inches in different directions; if the ring returns each time to the center position, then equilibrium has been achieved and the sum of the three forces is zero. If the ring returns to a position which is not at the center, test the pulleys for excessive friction in the bearings. If necessary, adjust the positions of Pulleys 2 and 3.
4. On the diagram at the right, sketch arrows for the forces F1 and F2, and label the angles 1, 2, 3, of the three vectors. /

III. ADDITION OF VECTORS USING THE METHOD OF COMPONENTS

The sum of the three forces is called S:

S = F1 + F2 + F3 (1)

However, since the ring is not accelerating, the net force--the "sum"--is zero. Thus,

F1 + F2 + F3= 0 (2)

The sum of the x-components of the forces is also zero, and the sum of the y-components is zero:

F1x + F2x + F3x = 0 (3)

F1y + F2y + F3y = 0 (4)

The actual measured sums above won't be zero, however, because of measurement or other experimental error.

Calculate the components

The x-components F1x, F2x, and F3x are found by multiplying the force magnitudes F1, F2, and F3 by the corresponding cosines of the angular positions. Do this now and record the x-components in the table. The y-components F1y, F2y, and F3y are found by multiplying the force magnitudes F1, F2, and F3, by the corresponding sines of the angular positions. Do this now and record the y-components in the table.

Calculating the sum of the forces

Although the actual total force on the ring is zero because the ring is not accelerating, the calculated value of the total force may not be zero because of inaccuracies in measurement.

The calculated value of the total force can be found using the Pythagorean Theorem:

S2 = Sx2 + Sy2 (5)

This may be re-written as

S = [Sx2 + Sy2]1/2 (6)

Calculate S now by first obtaining

Sx = F1x + F2x + F3x (7)

and

Sy = F1y + F2y + F3y (8)

Place these values in the table and then calculate S using Equation 6.

Ideally, S will be zero; it won't actually be zero, but it should be small. How small? By itself, the smallness of the value S cannot give a measure of how accurately this exercise was performed. For example, if each force had been several hundred newtons, but the measured sum is only 3 newtons, then S is small enough in comparison to the typical force that we could claim that S is approximately "zero", as expected. Thus, we need to compare the S value to a number which is representative of the size of the individual forces:

Add the three force magnitudes and divide by three to obtain the average force; record this average in the table. Compare the value S to the average by dividing S by the average, and then multiplying by 100 to get the percentage error.

IV. GRAPHICAL ADDITION OF VECTORS

Use broken lines to draw on the next page the three forces F1, F2, and F3 to scale, tails together, just as they were on the force table, and pointing in the proper directions. Use the scale 1 cm = 0.20 N. Place vector F1 along the positive x-axis. Label each arrow (F1, F2, F3) and show the magnitude in newtons, the angular position in degrees, and the length in cm alongside each arrows.

After the three forces have been drawn, usesolid lines to add them tail-to-head following this procedure: Leave F1 where it is and draw a second vector just like F2 with the tail of this re-positioned F2 connected to the head of F1. Before you do this, it will be necessary for you to determine the angle between the vectors F1 and F2 (this angle is just 2 -1).

Use a protractor to reproduce this angle when you connect F2 to F1 . Repeat this procedure to connect a re-positioned F3 to the re-positioned F2.

The sum of the three vectors is the arrow which can now be drawn from the tail of F1 to head of the re-positioned F3. If you are very lucky and this exercise has worked perfectly, the length of this arrow will be negligibly small and it will not be necessary for you to attempt to draw this sum vector. If possible, draw the sum vector and label it S; if S is drawable, measure its length and convert to units of Newtons and write the value beside the S vector.

Tail-to-Head Addition of Force Vectors

The cross "+" below indicates the position of the ring and the point of coincidence of the tails of the vectors.

+......

(draw F1 along here)

1