A) Amonton's law expresses the relationship between pressure and temperature. Use Charless law and Boyles law to derive the proportionality relationship between P and T.
B) If a car tire is filled to a pressure of 31.5 lbs/in2 (psi)
measured at 72 ∘F, what will be the tire pressure if the tires heat
up to 117 ∘F during driving?
The tire pressure will be 51.19 psi
The details calculation are in the paper......
You must use the temperature in Kelvins! the answer to b is 34,7 psi
A) Amonton's law expresses the relationship between pressure and temperature. Use Charless law and Boyles law...
On a cool morning, when the temperature is 16 ∘ C , you measure the pressure in your car tires to be 20 psi . After driving 50 mi on the freeway, the temperature of your tires is 55 ∘ C . What pressure will your tire gauge now show? Neglect the change of tires volume.
On a cool morning, when the temperature is 14°C, you measure the pressure in your car tires to be 26.8 psi. After driving 27 mi on the freeway, the temperature of your tires is 46°C. What pressure will your tire gauge now show?
when the temperature of an automobile tire is 20 degrees c, the pressure in the tire reads 29 psi on a tire gauge. (the gauge measures the difference between the pressures inside and outside the tire.) what is rhe pressure when the tire heats up to 39 degrees c while driving? you may assume that the volume of the tire remains the same and that the atomspheric pressure is a steady 14 psi.
11) The formula C = -32) expresses the relationship between Fahrenheit temperature, F, and Celsius temperature, C. Use the formula to convert 50°F to it equivalent temperature on the Celsius scale, rounded to the nearest degree A) 28°C B) -4°C C) 32°C D) 10°C I
please answer the questions too. Pressure - Temperature Relationship Data and Calculations for Temperature Pressure Relationship Pressure (kPa) Temperature (°C) Temperature (K) Calculated Constant, k (P/T) Calculated constant, k (PT) 100.88 26.0 105.13 60.1 106.33 75.5 108.40 83.5 110.38 95.0 Processing the data 1. A way to determine if a relationship is inverse or direct is to find a proportionality constant, k, from the data. If this relationship is direct, the k will be a constant fork - PT. If...
Describe the relationship between pressure and volume in Boyle's Law. Explain this relationship on a molecular level. Describe the relationship between temperature and volume in Charle's Law. Explain this relationship on a molecular level.
Combined Gas Relationship Since the Ideal Gas Law produces a constant (R), it can be used to look at a gas sample in which initial and final conditions have changed. The combined gas relationship is as follows P.V R=P.V2 n, T n2 T2 where P, Vi,and T, and n, are the initial pressure, volume, temperature, and number of moles of gas. The final conditions are represented by P, V2, T2 and n2. If any of the conditions in the initial...
The speedometer readings in passenger cars are based on angular speed of the car's tire axle. Because car's tires are filled with air [typically to the pressure of about 30 psi (pounds-square-inch)], the actual tire radius can be a bit different depending on the air temperature. You want to understand the impact of the air temperature on the tire radius and thus on the accuracy of the speedometer reading based on the ideal gas law. To simplify the calculation, you...
please answer question 5. Pressure - Temperature Relationship Calculated constant, k (P.1) Data and Calculations for Temperature Pressure Relationship Pressure Temperature Temperature Calculated (kPa) (°C) (K) Constant, (P/T) 100.88 26.0 299.15 0.33122 105.13 60.1 333.25 0.31547 106.33 75.5 348.65 10.30498 108.40 83.5 35b.bs 0.30394 110.38 95.0 318.15 0.29982 30178.252 350 34 573 37071.955 138660.86 40636.97 Processing the data 1. A way to determine if a relationship is inverse or direct is to find a proportionality constant, k, from the data....
The ideal gas law (PV=nRT) describes the relationship among pressure P, volume V, temperature T, and molar amount n. Fix n and V When n and V are fixed, the equation can be rearranged to take the following form where k is a constant: PT=nRV=k or (PT)initial=(PT)final This demonstrates that for a container of gas held at constant volume, the pressure and temperature are directly proportional.The relationship is also called Gay-Lussac's law after the French chemist Joseph-Louis Gay-Lussac, one of...