You are an engineer in a manufacturing plant. Your company will procure an important equipment that will contain and heat 100 moles of ammonia gas. The initial condition of the ammonia gas will be at 15 atm and 300 liters. The ammonia gas will then be heated until it expands to 500 liters while maintaining the 15 atm pressure. For this, a meeting with the accounting department is to be facilitated to talk about the cost of the said equipment. A teammate of yours, an engineer and a previous classmate of yours, made his/her computations regarding the cost. You've found out that his/her computations are "ideal" that: (1) he/she used specific heat capacities intended only for 25 ⁰C and 100 kpa conditions and (2) he/she used ideal gas law. From your extensive training in engineering school, you know that (1) specific heat capacity varies with temperature and (2) instead of using ideal gas law, it is more realistic to use "real gas law" such as Van Der Waals equation (see presented formula). According to a research made by the RnD (Research and Development) department of your company, for every positive increase in the change of entropy in the process (of the equipment to be procured), the cost accounts for 300.00 Php. Thus, 1 J/K increase in entropy in the process of the said equipment corresponds to 300.00 Php; and 2 J/K increase corresponds to 600.00 Php. Save your workmate from his/her impending trouble by showing him/her the difference between the cost he/she computed (ideal) and yours (realistic) in Php. Should your workmate present his/her computations, the accounting department will process the release of the financing of the equipment (which could take some time - profitability reviews, signatories of various bosses, etc.). Once the money is released, it would be a lot trouble if what he/she requested is way below what it is supposed to be. For the Van Der Waal's equation: P = atm n = mol V = L T = K For ammonia with respect to the Van Der Waal's equation: a = 4.225 L²/mol² b = 0.03713 L/mol Formula to convert Celsius to Kelvin is given by: K = ⁰C +273.15

You are an engineer in a manufacturing plant. Your company will procure an important equipment that will contain and heat 100 moles of ammonia gas. The initial condition of the ammonia gas will be at 15 atm and 300 liters. The ammonia gas will then be heated until it expands to 500 liters while maintaining the 15 atm pressure. For this, a meeting with the accounting department is to be facilitated to talk about the cost of the said equipment. A teammate of yours, an engineer and a previous classmate of yours, made his/her computations regarding the cost. You've found out that his/her computations are "ideal" that: (1) he/she used specific heat capacities intended only for 25 ⁰C and 100 kpa conditions and (2) he/she used ideal gas law. From your extensive training in engineering school, you know that (1) specific heat capacity varies with temperature and (2) instead of using ideal gas law, it is more realistic to use "real gas law" such as Van Der Waals equation (see presented formula). According to a research made by the RnD (Research and Development) department of your company, for every positive increase in the change of entropy in the process (of the equipment to be procured), the cost accounts for 300.00 Php. Thus, 1 J/K increase in entropy in the process of the said equipment corresponds to 300.00 Php; and 2 J/K increase corresponds to 600.00 Php. Save your workmate from his/her impending trouble by showing him/her the difference between the cost he/she computed (ideal) and yours (realistic) in Php. Should your workmate present his/her computations, the accounting department will process the release of the financing of the equipment (which could take some time - profitability reviews, signatories of various bosses, etc.). Once the money is released, it would be a lot trouble if what he/she requested is way below what it is supposed to be. For the Van Der Waal's equation: P = atm n = mol V = L T = K For ammonia with respect to the Van Der Waal's equation: a = 4.225 L²/mol² b = 0.03713 L/mol Formula to convert Celsius to Kelvin is given by: K = ⁰C +273.15

Introduction to Chemical Engineering Thermodynamics

8th Edition

ISBN:9781259696527

Author:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart

Publisher:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart

Chapter1: Introduction

Section: Chapter Questions

Problem 1.1P

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You are an engineer in a manufacturing plant. Your company will procure an important equipment that will contain and heat 100 moles of ammonia gas. The initial condition of the ammonia gas will be at 15 atm and 300 liters. The ammonia gas will then be heated until it expands to 500 liters while maintaining the 15 atm pressure.

For this, a meeting with the accounting department is to be facilitated to talk about the cost of the said equipment.

A teammate of yours, an engineer and a previous classmate of yours, made his/her computations regarding the cost. You've found out that his/her computations are "ideal" that: (1) he/she used specific heat capacities intended only for 25 ⁰C and 100 kpa conditions and (2) he/she used ideal gas law.

From your extensive training in engineering school, you know that (1) specific heat capacity varies with temperature and (2) instead of using ideal gas law, it is more realistic to use "real gas law" such as Van Der Waals equation (see presented formula).

According to a research made by the RnD (Research and Development) department of your company, for every positive increase in the change of entropy in the process (of the equipment to be procured), the cost accounts for 300.00 Php. Thus, 1 J/K increase in entropy in the process of the said equipment corresponds to 300.00 Php; and 2 J/K increase corresponds to 600.00 Php.

Save your workmate from his/her impending trouble by showing him/her the difference between the cost he/she computed (ideal) and yours (realistic) in Php.

Should your workmate present his/her computations, the accounting department will process the release of the financing of the equipment (which could take some time - profitability reviews, signatories of various bosses, etc.). Once the money is released, it would be a lot trouble if what he/she requested is way below what it is supposed to be.

For the Van Der Waal's equation:
P = atm
n = mol
V = L
T = K

For ammonia with respect to the Van Der Waal's equation:
a = 4.225 L²/mol²
b = 0.03713 L/mol

Formula to convert Celsius to Kelvin is given by:
K = ⁰C +273.15

Definition Definition Law that is the combined form of Boyle's Law, Charles's Law, and Avogadro's Law. This law is obeyed by all ideal gas. Boyle's Law states that pressure is inversely proportional to volume. Charles's Law states that volume is in direct relation to temperature. Avogadro's Law shows that volume is in direct relation to the number of moles in the gas. The mathematical equation for the ideal gas law equation has been formulated by taking all the equations into account: PV=nRT Where P = pressure of the ideal gas V = volume of the ideal gas n = amount of ideal gas measured in moles R = universal gas constant and its value is 8.314 J.K-1mol-1 T = temperature

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