/*! 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 9 One gram-mole of methyl chloride... [FREE SOLUTION] | 91Ó°ÊÓ

91Ó°ÊÓ

Log out

Learning Materials

Features

Discover

Chapter 5: Problem 9

One gram-mole of methyl chloride vapor is contained in a vessel at \(100^{\circ} \mathrm{C}\) and 10 atm. (a) Usc the ideal-gas equation of state to estimate the system volume. (b) Suppose the actual volume of the vessel is 2.8 liters. What percentage error results from assuming ideal-gas bchavior?

Short Answer

Expert verified
The estimated system volume using the ideal-gas equation of state is 3.06 L. The percentage error from assuming ideal-gas behavior, given an actual vessel volume of 2.8 L, is 9.29%.

Step by step solution

01

Calculation of the system volume using the ideal gas equation

Start by using the ideal gas equation of state, \(P*V=n*R*T\), where P=1000 kPa, n=1 mol, R = 0.08206 L.atm.K-1.mol-1 temperature T=100 degree Celsius, must be converted to Kelvin, T(K) = T(℃) + 273.15 = 373.15K. Solve the equation for V: \(V=n*R*T / P = 1 mol * 0.08206 L.atm.K-1.mol-1 * 373.15K / 10 atm = 3.06 L
02

Calculate the percentage error

The known actual volume of the vessel is 2.8 litres. It is necessary to compare this to the ideal volume. The percentage error is given by \((V_{ideal} - V_{actual}) / V_{actual} * 100\% = (3.06L - 2.8L) / 2.8L * 100\% = 9.29\%\)

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.

Chemical Engineering Principles
Chemical engineering is rooted in the manipulation and understanding of chemical reactions and processes to design equipment, systems, and methods for refining raw materials and for mixing, compounding, and processing chemicals to create valuable products. This discipline involves the application of various principles, one of which includes understanding the behavior of gases under different conditions.

A fundamental application of chemical engineering principles can be seen in the calculation of the volume of gases using the ideal gas equation. Engineers often use this equation as a starting point for designing reactors, storage tanks, and other equipment where gases are involved. Realize that assumptions are made regarding the behavior of the gas — for example, ignoring interactions between molecules — and while this simplifies calculations, it can also lead to errors, which must be quantified for practical applications.
Methyl Chloride Properties
Methyl chloride, also known as chloromethane, is a colorless, flammable gas with a slightly sweet odor, and is commonly used as a refrigerant, a solvent, and in the production of silicone polymers.

Its properties are of significant interest in chemical engineering because they determine how the substance can be stored, processed, and utilized. Methyl chloride behaves as an ideal gas under many conditions but has limitations under high-pressure or low-temperature scenarios where deviations from ideal behavior occur. These deviations are essential when designing real-world systems that need to take these non-ideal behaviors into account.
Gas Laws
Gas laws help us understand and predict how gases will behave under varying conditions of temperature, pressure, and volume. The ideal gas law, given as \(PV = nRT\), is a cornerstone of chemical engineering and thermodynamics, combining several simpler laws, such as Boyle's Law and Charles' Law.

The ideal gas law assumes that the gas particles are in constant, random motion and that they do not interact with each other. This law works well at standard conditions but less so when gases are at very high pressures or low temperatures. Understanding when and how to apply this law is crucial for engineers to get accurate results in their calculations.
Percentage Error Calculation
Percentage error calculation assesses the accuracy of an approximation compared to the actual value. It is a critical concept in chemical engineering, particularly when validating the assumption of ideal gas behavior.

The formula \(\frac{{V_{ideal} - V_{actual}}}{{V_{actual}}} \times 100\%\) yields the percentage error between the estimated volume (using the ideal gas law) and the actual volume. This reveals the degree to which the assumptions made (such as ideal gas behavior) hold true in practical scenarios. Being able to calculate and understand percentage error is pivotal for engineers in evaluating the reliability of their designs and processes.

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

Chemicals are stored in a laboratory with volume \(V\left(\mathrm{m}^{3}\right) .\) As a consequence of poor laboratory practices, a hazardous species, A, enters the room air (from inside the room) at a constant rate \(\dot{m}_{\mathrm{A}}(\mathrm{g} \mathrm{A} / \mathrm{h})\) The room is ventilated with clean air flowing at a constant rate \(\dot{V}_{\text {air }}\left(\mathrm{m}^{3} / \mathrm{h}\right) .\) The average concentration of A in the room air builds up until it reaches a steady-state value \(C_{\mathrm{A}, \mathrm{r}}\left(\mathrm{g} \mathrm{A} / \mathrm{m}^{3}\right)\) (a) List at least four situations that could lead to A getting into the room air. (b) Assume that the A is perfectly mixed with the room air and derive the formula $$\dot{m}_{\mathrm{A}}=\dot{V}_{\mathrm{air}} C_{\mathrm{A}}$$ (c) The assumption of perfect mixing is never justificd when the enclosed space is a room (as opposed to, say, a stirred reactor). In practice, the concentration of A varies from one point in the room to another: it is relatively high near the point where A enters the room air and relatively low in regions far from that point, including the ventilator outlet duct. If we say that \(C_{\mathrm{A}, \text { duct }}=k C_{\mathrm{A}}\) where \(k < 1\) is a nonideal mixing factor (generally between 0.1 and \(0.5,\) with the lowest value corresponding to the poorest mixing), then the equation of Part (b) becomes $$\dot{m}_{\mathrm{A}}=k \dot{V}_{\mathrm{air}} C_{\mathrm{A}}$$ Use this equation and the ideal-gas equation of state to derive the following expression for the average mole fraction of \(A\) in the room air: $$y_{\mathrm{A}}=\frac{\dot{m}_{\mathrm{A}}}{k \dot{V}_{\mathrm{air}}} \frac{R T}{M_{\mathrm{A}} P}$$ where \(M_{\mathrm{A}}\) is the molecular weight of \(\mathrm{A}\) (d) The permissible exposure level (PEL) for styrene \((M=104.14\) ) defined by the U.S. Occupational Safcty and Health Administration is 50 ppm (molar basis). \(^{21}\) An open storage tank in a polymerization laboratory contains styrene. The evaporation rate from this tank is estimated to be \(9.0 \mathrm{g} / \mathrm{h}\). Room temperature is \(20^{\circ} \mathrm{C}\). Assuming that the laboratory air is reasonably well mixed (so that \(k=0.5\) ), calculate the minimum ventilation rate \(\left(\mathrm{m}^{3} / \mathrm{h}\right)\) required to keep the average styrene concentration at or below the PEL. Then give several reasons why working in the laboratory might still be hazardous if the calculated minimum ventilation rate is used. (e) Would the hazard level in the situation described in Part (d) increase or decrease if the temperature in the room were to increase? (Increase, decrease, no way to tell.) Explain your answer, citing at least two effects of temperature in your explanation.

A stream of air enters a \(7.50-\mathrm{cm}\) ID pipe with a velocity of \(60.0 \mathrm{m} / \mathrm{s}\) at \(27^{\circ} \mathrm{C}\) and 1.80 bar (gauge). At a point downstream, the air flows through a \(5.00 \mathrm{cm}\) ID pipe at \(60^{\circ} \mathrm{C}\) and 1.53 bar (gauge). What is the average velocity of the gas at this point.

Methanol is produced by reacting carbon monoxide and hydrogen at \(644 \mathrm{K}\) over a \(\mathrm{ZnO}-\mathrm{Cr}_{2} \mathrm{O}_{3}\) catalyst. A mixture of \(\mathrm{CO}\) and \(\mathrm{H}_{2}\) in a ratio \(2 \mathrm{mol} \mathrm{H}_{2} / \mathrm{mol}\) CO is compressed and fed to the catalyst bed at \(644 \mathrm{K}\) and 34.5 MPa absolute. A single-pass conversion of 25\% is obtained. The space velocity, or ratio of the volumetric flow rate of the feed gas to the volume of the catalyst bed, is The product gases are passed through a condenser, in which the methanol is liquefied. (a) You are designing a reactor to produce \(54.5 \mathrm{kmol} \mathrm{CH}_{3} \mathrm{OH} / \mathrm{h}\). Estimate (i) the volumetric flow rate that the compressor must be capable of delivering if no gases are recycled, and (ii) the required volume of the catalyst bed. (Use Kay's rule for pressure-volume calculations.) (b) If (as is done in practice) the gases from the condenser are recycled to the reactor, the compressor is then required to deliver only the fresh feed. What volumetric flow rate must it deliver assuming that the methanol produced is completely recovered in the condenser? (In practice it is not; moreover, a purge stream must be taken off to prevent the buildup of impurities in the system.)

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.)

After being purged with nitrogen, a low-pressure tank used to store flammable liquids is at a total pressure of 0.03 psig. (a) If the purging process is done in the moming when the tank and its contents are at \(55^{\circ} \mathrm{F}\), what will be the pressure in the tank when it is at \(85^{\circ} \mathrm{F}\) in the afternoon? (b) If the maximum design gauge pressure of the tank is 8 inches of water, has the design pressure been exceeded? (c) Speculate on the purpose of purging the tank with nitrogen.
See all solutions

Recommended explanations on Chemistry Textbooks

Inorganic Chemistry

Read Explanation

Nuclear Chemistry

Read Explanation

Organic Chemistry

Read Explanation

Chemical Reactions

Read Explanation

Chemical Analysis

Read Explanation

Chemistry Branches

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.