Toricelli's Law Lab Report

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There are three types of pressure and they are: Total Pressure, Static Pressure, and Dynamic Pressure. All three pressures can be represented in this equation:

Ptotal = Pstatic + Pdynamic

Total pressure is the sum of static and dynamic pressure. Static pressure represents when a fluid is at rest. Dynamic pressure represents the kinetic energy of the moving fluid.

Bernoulli’s equation is represented as:[pic 5]

The variables P1, v1, and h1, represent the pressure, speed, and the height of the fluid at point 1. In addition, P2, v2, and h2, represent the pressure, speed, and the height of the fluid at point 2. The ‘p’ in 1/2​​ρv​^2 represents the density of the fluid.

Deriving Torricelli’s Equation from Bernoulli's Equation:

- P1 + 1/2pv1² + pgh1 = P2 + 1/2pv2² + pgh2

- P1 + 1/2p(0)² + pgh1 = P2 + 1/2pv2² + pg(0)

- P1 + pgh1 = P2 + 1/2pv2²

- Patm + pgh1 = Patm + 1/2pv2²

- Gh = 1/2pv2²

- V2² = 2gh

- V2 = √2gh

Steps of Derivation Explained

- Write Bernoulli's equation down.

- Assume that the velocity is 0 at location 2 at the top of the fluid, meaning there is no kinetic energy present. Also assume that there is no gravitational potential energy at location 1 since it is at a height of 0.

- Write the remaining components cancelling the kinetic energy from the left side and the gravitational potential energy on the right side.

- The pressure at both locations is equal to the atmospheric pressure since at both points, the fluid is exposed to the bare atmosphere.

- Cancel out the atmospheric pressures at both sides as well as the density.

- Simplify to get V2² by itself with everything else on the other side of the equation.

- Square root both sides of the equation with the resulting final equation which is Torricelli’s equation.

Theoretical Result

In this experiment, we will be calculating for the flow rate and the height since calculating for velocity will produce inaccurate results according to our means of performing the experiment. We will still apply the flow rate to velocity conversion factor in order to further validate our data and theory in the end. This is further explained in the Analysis section of the report. Furthermore, the relationship between the flow rate and the height should also theoretically produce a square root relationship because both flow rate and velocity describes the motion of a fluid but in different units, and they are directly correlated to each other. The relationship is interrelated. The flow rate of a fluid is the volume of the fluid that goes through a surface per unit time. On the other hand, the velocity is how far the fluid travels per unit time and can be found dividing the flow rate by the cross sectional area of the bottle.

Hypothesis

If water leaks out the hole at the bottom of the bottle, it will leak at a rate that is proportional to the square root relationship of the depth of the water as if the water were to be in free fall from that height of h.

Observations and Analysis

Circumference of Two Litre Bottle

Volume of Water Below Hole

0.34 m

426 mL

Volume Lost over 5 seconds (±1 mL)

Volume of Water (mL)

Trial 1

Trial 2

Trial 3

Average Volume Loss (mL)

Error in Measuring Volume of Water (mL)

600

47 mL

49 mL

46 mL

47.0

6

700

61 mL

60 mL

63 mL

61.5

7

800

70 mL

71 mL

69 mL

70.0

8

900

73 mL

73 mL

73 mL

73.0

9

1000

76 mL

77 mL

75 mL

76.0

10

1100

80 mL

82 mL

80 mL

80.5

11

1200

82 mL

84 mL

83 mL

83.0

12

1300

86 mL

85 mL

87 mL

86.0

13

1400