Answer to Question #238191 in Classical Mechanics for snow

"\\Delta x = 2.1cm = 2.1*10^{-2}m"

"\\text {for the body with an elastic band under normal conditions}"

"\\text{according to Hooke's law}"

"F = k\\Delta x"

"P = F = mg"

"\\Delta x= \\frac{mg}{k}=2.1*10^{-2}m"

"a)"

"\\text{for an body in an elevator:}"

"\\Delta x_1 = 3.5cm = 3.5*10^{-2}m"

"F_1 = k\\Delta x"

"P_1 = F_1 = m(g-a)"

"\\Delta x_1= \\frac{m(g-a)}{k}=3.5*10^{-2}m"

"\\frac{\\Delta x_1}{\\Delta x}=\\frac{3.5*10^{-2}}{2.1*10^{-2}}\\approx1.67"

"\\frac{\\Delta x_1}{\\Delta x}= \\frac{\\frac{m(g-a)}{k}}{\\frac{mg}{k}}=\\frac{g-a}{g}=1-\\frac{a}{g}"

"a = -0.67*g = -0.67*9.8= -6.57 \\frac{m}{s^2}"

"\\text{Acceleration minus sign means acceleration is directed }"

"\\text{upwards opposite to gravity}"

"\\text{Answer: }a = -6.57 \\frac{m}{s^2}"

"b)"

"\\text{From expression (1)}"

"1-\\frac{a}{g}= 1.67"

"1-\\frac{a}{g} = \\frac{g-a}{g} = \\frac{m_p(g-a)}{m_pg} =\\frac{P_1}{P}"

"m_p -\\text {mass of pacient}"

"\\frac{P_1}{P} = 1.67"

"\\text{Answer:}"

"\\text{According to the scales, your weight has increased by a factor of } 1.67"