/*! This file is auto-generated */ .wp-block-button__link{color:#fff;background-color:#32373c;border-radius:9999px;box-shadow:none;text-decoration:none;padding:calc(.667em + 2px) calc(1.333em + 2px);font-size:1.125em}.wp-block-file__button{background:#32373c;color:#fff;text-decoration:none} Problem 95 A 150 -liter cylinder of carbon ... [FREE SOLUTION] | 91Ó°ÊÓ

91Ó°ÊÓ

Log out

Learning Materials

Features

Discover

Chapter 5: Problem 95

A 150 -liter cylinder of carbon monoxide is stored in a \(30.7-\mathrm{m}^{3}\) room. The pressure gauge on the tank reads 2500 psi when the tank is delivered. Sixty hours later the gauge reads 2245 psi. The Threshold Limit Value Ceiling (TLV-C) molar concentration of CO-that is, the concentration considered unsafe for even instantaneous human exposure-is \(200 \mathrm{ppm}\left(200 \times 10^{-6} \mathrm{mol} \mathrm{CO} / \mathrm{mol} \text { room air). }^{24}\right.\) The temperature of the room is constant at \(27^{\circ} \mathrm{C}\). (a) The decrease in pressure is a source of concern, but it may have resulted from a reduction in the temperature of the tank as it was transported from the loading dock to the air-conditioned laboratory. Without assuming that the gas behaves ideally, show that this is unlikely to be the case. (b) Having determined that the pressure decrease must be due to a leak, estimate the average leak rate (mol CO/h), again without assuming that the gas behaves ideally. (c) Calculate \(t_{\min }(\mathrm{h}),\) the minimum time from delivery at which the average concentration of \(\mathrm{CO}\) in the room could have reached the TLV-C concentration. Explain why the actual time to reach this concentration would be greater. (d) Why could it be disastrous to enter the room at any time without wearing proper personal protective equipment, even at a time \(t

Short Answer

Expert verified
The pressure decrease was likely due to a leak, not a temperature change. The estimated average leak rate was calculated using the change in pressure and volume over time. The minimum time to reach unsafe levels was calculated using the leak rate and the given concentration limit. However, it would be hazardous to enter the room at any time without proper protection due to possible non-uniform gas distribution and other health risks associated with lower level CO exposure.

Step by step solution

01

Calculating the Initial Amount of CO

First, we need to find the initial amount of CO in moles. To do this, we'll use the ideal gas law equation \(PV = nRT\), where P is the pressure, V is the volume, n is the number of moles, R is the gas constant, and T is the temperature. We are given P = 2500 psi, V = 150 liters, and T = 27°C (converted to Kelvin T = 300K). However, since the problem specifically required not assuming ideal gas behavior, we should use van der Waals equation \(P + (n^2 a / V^2) (V - nb) = nRT\), which takes into account the finite size of particles and intermolecular forces. Here, a and b are van der Waals constants specific for CO (a = 1.485 L².atm/mol², b = 0.0391 L/mol).
02

Analyzing the Pressure Decrease

The decrease in pressure could be due to a temperature drop or a gas leak. To disprove the temperature decrease theory, we can calculate the expected final pressure due to a temperature drop from external conditions to room temperature (27°C) using the ideal gas law, since the volume and quantity of gas are constant. If this calculated pressure is larger than the observed final pressure (2245 psi), a leak must have occurred.
03

Calculating the Average Leak Rate

Having concluded that the pressure decrease must be due to a leak, the leak rate (in terms of moles of CO per hour) can be estimated by dividing the total number of moles that leaked (which can be calculated from the final and initial moles of CO) by the time span (60 hours).
04

Finding the Minimum Time to Reach Unsafe Concentration

Calculate the minimum time required for the leaked CO to reach the Threshold Limit Value Ceiling (TLV-C) concentration in the room. The number of moles of CO needed to reach this level can be calculated using the given molar concentration (200 ppm) and the volume of the room (30.7 m³). Then, find the time by dividing this number of moles by the average leak rate.
05

Understanding the Risks

The hazards of entering the room at any time without proper personal protective equipment may include: 1) Even before reaching the TLV-C concentration, the concentration could still be harmful, 2) Leaked gas may not be uniformly distributed and could be higher at the tank's location, and 3) Other risks associated with low-level CO exposure, including impaired motor functions, which may contribute to accidents.

Unlock Step-by-Step Solutions & Ace Your Exams!

  • Full Textbook Solutions

    Get detailed explanations and key concepts

  • Unlimited Al creation

    Al flashcards, explanations, exams and more...

  • Ads-free access

    To over 500 millions flashcards

  • Money-back guarantee

    We refund you if you fail your exam.

Over 30 million students worldwide already upgrade their learning with 91Ó°ÊÓ!

Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Van der Waals Equation
The Van der Waals equation is a thermodynamic equation of state that is an extension of the ideal gas law, generally expressed as \(P + \frac{a}{V_m^2}\)\(V_m - b\) = RT, where \(P\) is the pressure, \(V_m\) is the molar volume, \(R\) is the gas constant, \(T\) is the temperature, and \(a\) and \(b\) are constants that represent the gas's intermolecular forces and molecular size, respectively. Unlike the ideal gas law, which assumes no forces between molecules and that the molecules themselves occupy no volume, the Van der Waals equation accounts for real gas behavior by incorporating these constants.

In the context of chemical process safety, using the Van der Waals equation is crucial for obtaining more accurate results, especially at high pressures and low temperatures where gases do not behave ideally. This accuracy is significant when estimating the amount of a hazardous gas like carbon monoxide (CO) in an environment, where precise calculations are necessary for safety assessments.
Ideal Gas Law
The ideal gas law is a fundamental principle in chemistry and physics that relates the pressure, volume, and temperature of an ideal gas. The equation is defined as \(PV = nRT\), with \(P\) representing pressure, \(V\) volume, \(n\) the number of moles, \(R\) the ideal gas constant, and \(T\) temperature. This law assumes that the gas molecules do not interact with one another and that they occupy no volume. While these assumptions are not valid for all conditions, the ideal gas law provides a good approximation for the behavior of gases under many standard conditions.

However, when dealing with gases at high pressures or low temperatures, deviations from ideal behavior can occur. Hence, in such scenarios, especially when dealing with toxic substances like CO, it is more reliable to use modifications to the ideal gas law, like the Van der Waals equation, for greater accuracy and safety.
Threshold Limit Value (TLV)
Threshold Limit Value (TLV) refers to the level at which it is believed a worker can be exposed day after day for a working lifetime without adverse health effects. Specifically, the TLV-Ceiling (TLV-C) is the concentration that should not be exceeded, even instantaneously. This is critical in managing and assessing chemical exposure risks in workplaces, including labs.

In our example related to carbon monoxide, the TLV-C is 200 ppm (parts per million), indicating the concentration above which humans should not be exposed. Understanding and calculating the TLV-C is essential for safety in potential leak situations because it helps determine when to implement safety measures, such as evacuating an area or using personal protective equipment (PPE). It is an example of how industrial hygiene principles are applied within the field of chemical process safety.
Gas Leak Rate Estimation
Estimating the rate at which a gas leaks is important for evaluating the potential risk posed by the leak, particularly in environments with hazardous gases. The leak rate can be determined by comparing the amount of gas at two different times and accounting for the time elapsed. It's typically expressed as moles per hour. For carbon monoxide, this calculation assists in the safety analysis, providing a timeline for response actions to prevent the buildup of concentrations that exceed the TLV-C.

In our scenario with the pressure decrease in the cylinder, establishing the leak rate helps in calculating how quickly the room's CO concentration could reach unsafe levels. This is vital for planning safety measures and ensuring that individuals are not exposed to dangerous concentrations of CO. It also underscores the need for constant monitoring and quick action in case of a leak to mitigate risks associated with the exposure to harmful gases.

One App. One Place for Learning.

All the tools & learning materials you need for study success - in one app.

Get started for free

Most popular questions from this chapter

The flow of airto a gas-fired boiler fumace is controlled by a computer. The fuel gases used in the fumace are mixtures of methane (A), ethane (B), propane (C), \(n\) -butane (D), and isobutane (E). At periodic intervals the temperature, pressure, and volumetric flow rate of the fuel gas are measured, and voltage signals proportional to the values of these variables are transmitted to the computer. Whenever a new feed gas is used, a sample of the gas is analyzed and the mole fractions of each of the five components are determined and read into the computer. The desired percent excess air is then specified, and the computer calculates the required volumetric flow rate of air and transmits the appropriate signal to affow-control valve in the air line. The linear proportionalities between the input and the output signals and the corresponding process variables may be determined from the following calibration data: (a) Create a spreadsheet or write a program to read in values of \(R_{\mathrm{f}}, R_{T}, R_{P},\) the fuel gas component mole fractions \(x_{\mathrm{A}}, x_{\mathrm{B}}, x_{\mathrm{C}}, x_{\mathrm{D}},\) and \(x_{\mathrm{E}},\) and the percent excess air \(P X,\) and to calculate the required value of \(R_{\Lambda}\) (b) Run your program for the following data. $$\begin{array}{lcccccccc} \hline R_{\mathrm{f}} & R_{\mathrm{T}} & R_{P} & x_{\mathrm{A}} & x_{\mathrm{B}} & x_{\mathrm{C}} & x_{\mathrm{D}} & x_{\mathrm{E}} & P X \\ \hline 7.25 & 23.1 & 7.5 & 0.81 & 0.08 & 0.05 & 0.04 & 0.02 & 15 \% \\ 5.80 & 7.5 & 19.3 & 0.58 & 0.31 & 0.06 & 0.05 & 0.00 & 23 \% \\ 2.45 & 46.5 & 15.8 & 0.00 & 0.00 & 0.65 & 0.25 & 0.10 & 33 \% \\ \hline \end{array}$$

The quantity of sulfuric acid used globally places it among the most plentiful of all commodity chemicals. In the modern chemical industry, synthesis of most sulfuric acid utilizes elemental sulfur as a feedstock. However, an alternative and historically important source of sulfuric acid was the conversion of an ore containing iron pyrites (FeS_) to sulfur oxides by roasting (burning) the ore with air. The following reactions occurred in an oven: $$\begin{array}{c} 2 \mathrm{FeS}_{2}(\mathrm{s})+\frac{11}{2} \mathrm{O}_{2}(\mathrm{g}) \rightarrow \mathrm{Fe}_{2} \mathrm{O}_{3}(\mathrm{s})+4 \mathrm{SO}_{2}(\mathrm{g}) \\ \mathrm{SO}_{2}(\mathrm{g})+\frac{1}{2} \mathrm{O}_{2}(\mathrm{g}) \rightarrow \mathrm{SO}_{3}(\mathrm{g}) \end{array}$$ The gases leaving the oven were fed to a catalytic converter in which most of the remaining \(\mathrm{SO}_{2}\) produced was oxidized to \(\mathrm{SO}_{3}\). Finally, the gas leaving the converter was sent to an absorption column where the \(S O_{3}\) was taken up by water to produce sulfuric acid \(\left(H_{2} S O_{4}\right)\) (a) The ore fed to the oven was 90.0 wt\% \(\mathrm{FeS}_{2}\), and the remaining material may be considered inert. Dry air was fed to the oven in \(30.0 \%\) excess of the amount required to oxidize all of the sulfur in the ore to \(S O_{3}\). Eighty-five percent of the \(\mathrm{FeS}_{2}\) was oxidized, and \(60 \%\) of the \(\mathrm{SO}_{2}\) produced was oxidized to \(S O_{3}\). Leaving the roaster were (i) a gas stream containing \(S O_{2}, S O_{3}, O_{2},\) and \(N_{2}\) and (ii) a solid stream containing unconverted pyrites, ferric oxide \(\left(\mathrm{Fe}_{2} \mathrm{O}_{3}\right),\) and the inert material. Calculate the required feed rate of air in standard cubic meters per \(100 \mathrm{kg}\) of ore fed to the process. Also determine the molar composition and volume (SCM/100 kg ore) of the gas leaving the oven. (b) The gas leaving the oven entered the catalytic converter, which operated at 1.0 atm. Reaction (2) proceeded to equilibrium, at which point the component partial pressures are related by the expression $$K_{\mathrm{P}}(T)=\frac{p_{\mathrm{SO}_{3}}}{p_{\mathrm{SO}_{3}} p_{\mathrm{O}_{2}}^{0.5}}$$ The gases were first heated to \(600^{\circ} \mathrm{C}\) to accelerate the rate of reaction, and then cooled to \(400^{\circ} \mathrm{C}\) to enhance \(S O_{2}\) conversion. The equilibrium constant \(K_{\mathrm{P}}\) at these two temperatures is 9.53 atm \(^{0.5}\) and 397 atm \(^{0.5}\), respectively. Calculate the equilibrium fractional conversions of \(S O_{2}\) at these two temperatures. (c) Estimate the production rate of sulfuric acid in \(\mathrm{kg} / \mathrm{kg}\) ore if all of the \(\mathrm{SO}_{3}\) leaving the converter was transformed to sulfuric acid. What would this value be if all the sulfur in the ore had been converted?

A \(5.0-\mathrm{m}^{3}\) tank is charged with \(75.0 \mathrm{kg}\) of propane gas at \(25^{\circ} \mathrm{C}\). Use the SRK equation of state to estimate the pressure in the tank; then calculate the percentage error that would result from the use of the ideal-gas equation of state for the calculation.

Methanol is synthesized from carbon monoxide and hydrogen in the reaction $$\mathrm{CO}+2 \mathrm{H}_{2} \rightleftharpoons \mathrm{CH}_{3} \mathrm{OH}$$ The fresh feed to the system, which contains only \(\mathrm{CO}\) and \(\mathrm{H}_{2},\) is blended with a recycle stream containing the same species. The combined stream is heated and compressed to a temperature \(T(\mathrm{K})\) and a pressure \(P(\mathrm{kPa})\) and fed to the reactor. The percentage excess hydrogen in this stream is \(H_{\mathrm{xs}}\). The reactor effluent \(-\) also at \(T\) and \(P-\) goes to a scparation unit where essentially all of the methanol produced in the reactor is condensed and removed as product. The unreacted \(\mathrm{CO}\) and \(\mathrm{H}_{2}\) constitute the recycle stream blended with the fresh feed. Provided that the reaction temperature (and hence the rate of reaction) is high enough and the idealgas equation of state is a reasonable approximation at the reactor outlet conditions (a questionable assumption), the ratio $$K_{p c}=\frac{p_{\mathrm{CH}, \mathrm{OH}}}{p_{\mathrm{CO}} p_{\mathrm{H}}^{2}}$$ approaches the equilibrium value, which is given by the expression $$K_{p}(\mathrm{T})=1.390 \times 10^{-4} \exp \left(21.225+\frac{9143.6}{T}-7.492 \ln T+4.076 \times 10^{-3} T-7.161 \times 10^{-8} T^{2}\right)$$ In these equations, \(p_{i}\) is the partial pressure of species \(i\) in kilopascals \(\left(i=\mathrm{CH}_{3} \mathrm{OH}, \mathrm{CO}, \mathrm{H}_{2}\right)\) and \(T\) is in Kelvin. (a) Suppose \(P=5000 \mathrm{kPa}, T=500 \mathrm{K},\) and the percentage excess of hydrogen in the feed to the reactor \(\left(H_{\mathrm{xz}}\right)=5.0 \% .\) Calculate \(\dot{n}_{4}, \dot{n}_{5},\) and \(\dot{n}_{6},\) the component flow rates \((\mathrm{kmol} / \mathrm{h})\) in the reactor effluent. [Suggestion: Use the known value of \(H_{x s}\), atomic balances around the reactor, and the equilibrium relationship, \(K_{p c}=K_{p}(T),\) to write four equations in the four variables \(\dot{n}_{3}\) to \(\dot{n}_{6} ;\) use algebra to eliminate all but \(\dot{n}_{6} ;\) and use Goal Seck or Solver in Excel to solve the remaining nonlinear equation for \(\dot{n}_{6} .\) J Then calculate component fresh feed rates \(\left(\dot{n}_{1} \text { and } \dot{n}_{2}\right)\) and the flow rate (SCMH) of the recycle stream. (b) Prepare a spreadsheet to perform the calculations of Part (a) for the same basis of calculation (100 kmol CO/h fed to the reactor) and different specified values of \(P(\mathrm{kPa}), T(\mathrm{K}),\) and \(H_{\mathrm{xs}}(\%)\) The spreadsheet should have the following columns: A. \(P(\mathrm{kPa})\) B. \(T(\mathrm{K})\) C. \(H_{x s}(\%)\) D. \(K_{p}(T) \times 10^{8} .\) (The given function of \(T\) multiplied by \(10^{8} .\) When \(T=500 \mathrm{K}\), the value in this column should be 91.113.) E. \(K_{p} P^{2}\) F. \(\dot{n}_{3} .\) The rate (kmol/h) at which \(\mathrm{H}_{2}\) enters the reactor. G. \(\dot{n}_{4}\). The rate ( \(\mathrm{kmol} / \mathrm{h}\) ) at which CO leaves the reactor. H. \(\dot{n}_{5}\). The rate (kmol/h) at which \(\mathrm{H}_{2}\) leaves the reactor. I. \(\dot{n}_{6}\). The rate \((\mathrm{kmol} / \mathrm{h})\) at which methanol leaves the reactor. J. \(\dot{n}_{\text {lot. The total molar flow rate }(\mathrm{kmol} / \mathrm{h}) \text { of the reactor effluent. }}\) K. \(K_{p c} \times 10^{8} .\) The ratio \(y_{\mathrm{M}} /\left(y_{\mathrm{CO}} y_{\mathrm{H}_{2}}^{2}\right)\) multiplied by \(10^{8} .\) When the correct solution has been attained, this value should equal the one in Column E. L. \(K_{p} P^{2}-K_{p r} P^{2} .\) Column E-Column K, which equals zero for the correct solution. M. \(\dot{n}_{1}\). The molar flow rate \((\mathrm{kmol} / \mathrm{h})\) of \(\mathrm{CO}\) in the fresh feed. N. \(\dot{n}_{2}\). The molar flow rate \((\mathrm{kmol} / \mathrm{h})\) of \(\mathrm{H}_{2}\) in the fresh feed. O. \(\dot{V}_{\text {rec }}(\text { SCMH })\). The flow rate of the recycle stream in \(\mathrm{m}^{3}(\mathrm{STP}) / \mathrm{h}\). When the correct formulas have been entered, the value in Column I should be varied until the value in Column L equals 0 . Run the program for the following nine conditions (three of which are the same): \(\cdot\) \(T=500 \mathrm{K}, H_{\mathrm{xs}}=5 \%,\) and \(P=1000 \mathrm{kPa}, 5000 \mathrm{kPa},\) and \(10,000 \mathrm{kPa}\) \(\cdot\) \(P=5000 \mathrm{kPa}, H_{x s}=5 \%,\) and \(T=400 \mathrm{K}, 500 \mathrm{K},\) and \(600 \mathrm{K}\) \(\cdot\) \(T=500 \mathrm{K}, P=5000 \mathrm{kPa},\) and \(H_{\mathrm{xs}}=0 \%, 5 \%,\) and \(10 \%\) Summarize the effects of reactor pressure, reactor temperature, and excess hydrogen on the yield of methanol (kmol M produced per \(100 \mathrm{kmol}\) CO fed to the reactor). (c) You should find that the methanol yield increases with increasing pressure and decreasing temperature. What cost is associated with increasing the pressure? (d) Why might the yield be much lower than the calculated value if the temperature is too low? (e) If you actually ran the reaction at the given conditions and analyzed the reactor effluent, why might the spreadsheet values in Columns \(\mathrm{F}-\mathrm{M}\) be significantly different from the measured values of these quantities? (Give several reasons, including assumptions made in obtaining the spreadsheet values.)

An innovative engineer has invented a device to replace the hydraulic jacks found at many service stations. A movable piston with a diameter of \(0.15 \mathrm{m}\) is fitted into a cylinder. Cars are raised by opening a small door near the base of the cylinder, inserting a block of dry ice (solid \(\mathrm{CO}_{2}\) ), closing and sealing the door, and vaporizing the dry ice by applying just enough heat to raise the cylinder contents to ambient temperature \(\left(25^{\circ} \mathrm{C}\right)\). The car is subsequently lowered by opening a valve and venting the cylinder gas. The device is tested by raising a car a vertical distance of \(1.5 \mathrm{m}\). The combined mass of the piston and the car is \(5500 \mathrm{kg}\). Before the piston rises, the cylinder contains \(0.030 \mathrm{m}^{3}\) of \(\mathrm{CO}_{2}\) at ambient temperature and pressure ( 1 atm). Neglect the volume of the dry ice. (a) Calculate the pressure in the cylinder when the piston comes to rest at the desired elevation. (b) How much dry ice (kg) must be placed in the cylinder? Use the SRK equation of state for this calculation. (c) Outline how you would calculate the minimum piston diameter required for any elevation of the car to occur if the calculated amount of dry ice is added. (Just give formulas and describe the procedure you would follow- -no numerical calculations are required.)
See all solutions

Recommended explanations on Chemistry Textbooks

The Earths Atmosphere

Read Explanation

Nuclear Chemistry

Read Explanation

Chemical Reactions

Read Explanation

Chemical Analysis

Read Explanation

Chemistry Branches

Read Explanation

Physical Chemistry

Read Explanation
View all explanations

What do you think about this solution?

We value your feedback to improve our textbook solutions.

Study anywhere. Anytime. Across all devices.