Answer:
A) SV = 70 mL
B) H.R = 49.8 bpm
C) H.R = 49.8 bpm
D) P_e = 0.4 s
E) v¯ = 38.68 cm/s
F) Re ≈ 3265
G) turbulent flow.
H) KE = 0.01105 J
I) Diastolic and Systolic pressure are not given so work can't be found
Explanation:
We are given;
Radius of aorta; r = 1.2 cm
Diastolic volume; DV = 120 mL
Systolic volume; SysV = 50 mL
Period that cycle lasts; t_cycl = 1.2 s
the aortic valve opens at; t_ao = 0.5 s aortic valve closes at; t_ac = 0.9 s
Density; ρ = 1.055 g/mL = 1.055 g/cm³
viscosity; μ = 3 × 10^(-3) Pa.s = 0.03 g/cm-s
A) Formula for stroke volume is;
SV = DV - SysV
SV = 120 - 50
SV = 70 mL
B) formula for heart rate is;
H.R = 1/t_cycl
H.R = 1/1.2
H.R = 0.83 beats per seconds
Converting to beats per minutes gives;
H.R = 0.83 × 60
H.R = 49.8 bpm
C) Formula for cardiac output is;
cardiac output = SV × HR
Let's convert SV to L to get;
SV = 0.07 L
Thus;
Cardiac output = 0.07 × 49.8
Cardiac output = 3.49 L/min
D) Period of ejection = t_ac - t_ao
Period of ejection = 0.9 - 0.5
Period of ejection; P_e = 0.4 s
E) average velocity; v¯ = SV/(A × P_e)
A = πr²
A = π × 1.2² cm²
SV = 70 mL = 70 cm³
Thus;
v¯ = 70/(π × 1.2² × 0.4)
v¯ = 38.68 cm/s
F) Reynolds number is calculated from;
Re = ρv¯D/μ
r = 1.2 and so diamter; D = 2r = 2 × 1.2 = 2.4 cm
Thus;
Re = 1.055 × 38.68 × 2.4/(0.03)
Re ≈ 3265
G) Reynolds number is greater than 2000 and thus it is a turbulent flow.
H) Formula for kinetic energy is;
KE = ½mv²
We know that; mass = volume × density
Thus; mass = 1.055 × 70 g
KE = ½ × 1.055 × 70 × 38.68²
KE = 110,490.12 g.cm²/s²
Converting to Joules gives;
KE = 0.01105 J
I) work volume relationship is given by;
W = ∫PdV
But we are not given the Diastolic and Systolic pressure, so it's not possible to calculate the work
