{"id":4663,"date":"2024-10-03T19:49:34","date_gmt":"2024-10-03T19:49:34","guid":{"rendered":"https:\/\/workhouse.sweetdishy.com\/?p=4663"},"modified":"2024-10-03T19:49:35","modified_gmt":"2024-10-03T19:49:35","slug":"material-balances-in-reacting-systems","status":"publish","type":"post","link":"https:\/\/workhouse.sweetdishy.com\/index.php\/2024\/10\/03\/material-balances-in-reacting-systems\/","title":{"rendered":"Material Balances in Reacting Systems"},"content":{"rendered":"\n<p>Reacting systems are characterized by the disappearance of reactants and appearance of the products. Clearly, molecular species are not conserved in the reaction, and at steady state, the rate of input of a compound participating in the reaction is not equal to the rate of its output. However,\u00a0<em>as long as no nuclear reactions are occurring in the system<\/em>, atomic species are conserved. Therefore, the approach to obtaining the material balance in a reacting system involves formulating independent conservation equations for the atoms of elemental species involved in the reactions [4]. It should also be noted that several inert species that do not participate in the reaction are often present in a reacting system, and the material balance for such species can be expressed in terms of molecular quantities. For example, if a combustion reaction is conducted using air as the oxidant, then the nitrogen (N<sub>2<\/sub>) present in air does not participate in the reaction and is treated as an inert. Similarly, solvents employed for liquid-phase reactions\u2014water for aqueous phase reactions, for example\u2014do not participate in the reaction, and the material balance for these inert solvents may be written in terms of molecular species.<\/p>\n\n\n\n<p>Conducting a material balance on a reacting system requires a knowledge of the balanced chemical equation(s) for the reaction(s). The chemical equation provides the information about the proportions of the different species involved in the reaction\u2014the stoichiometry of the reaction. Let us consider a general reaction involving species A, B, C, and D according to the equation:<\/p>\n\n\n\n<figure class=\"wp-block-image\"><img decoding=\"async\" src=\"https:\/\/learning.oreilly.com\/api\/v2\/epubs\/urn:orm:book:9780134594064\/files\/graphics\/06equ07.jpg\" alt=\"Image\"\/><\/figure>\n\n\n\n<p>where\u00a0<em>a<\/em>,\u00a0<em>b<\/em>,\u00a0<em>c<\/em>\u00a0and\u00a0<em>d<\/em>\u00a0are the stoichiometric coefficients of the species A, B, C, and D, respectively. According to this equation, the ratio of the amount of C formed (molecules or moles) to the amount of A reacting will be equal to\u00a0<em>c<\/em>\/<em>a<\/em>. Similarly, proportional quantities of D are formed and B are reacted, depending on the stoichiometric coefficients\u00a0<em>d<\/em>\u00a0and\u00a0<em>b<\/em>, respectively.\u00a0Example 6.3.1\u00a0illustrates the application of these principles to a simple reacting system involving a single reaction.<\/p>\n\n\n\n<p><a><\/a>Example 6.3.1 Combustion of Natural Gas<\/p>\n\n\n\n<p>Natural gas is burned in a reactor (such as in a typical gas water heater in a home) using air as the oxidant. Calculate the quantities of air needed and the products formed per mole of the natural gas burned in the system.<\/p>\n\n\n\n<p>Solution<\/p>\n\n\n\n<p>Obtaining the material balance for this system requires knowledge of the chemicals present in the natural gas. Natural gas is, in reality, a mixture of gases dominated by methane (CH<sub>4<\/sub>). However, in these calculations, it is assumed that the natural gas is composed entirely of CH<sub>4<\/sub>. This assumption allows us to simplify the system and write a single chemical reaction to represent the combustion. Complete combustion of CH<sub>4<\/sub>&nbsp;results in the formation of carbon dioxide (CO<sub>2<\/sub>) and H<sub>2<\/sub>O according to the following equation:<\/p>\n\n\n\n<p>CH<sub>4<\/sub>&nbsp;+ 2O<sub>2<\/sub>&nbsp;\u2192 CO<sub>2<\/sub>&nbsp;+ 2H<sub>2<\/sub>O<\/p>\n\n\n\n<p>From the equation, the stoichiometric proportions between various species are obtained as follows:<\/p>\n\n\n\n<p>O<sub>2<\/sub>\/CH<sub>4<\/sub>&nbsp;= 2, CO<sub>2<\/sub>\/CH<sub>4<\/sub>&nbsp;= 1, and H<sub>2<\/sub>O\/CH<sub>4<\/sub>&nbsp;= 2<\/p>\n\n\n\n<p>Therefore, two moles of oxygen (O<sub>2<\/sub>) are needed per mole of natural gas, and the 3 moles of product are formed that include 1 mole of CO<sub>2<\/sub>\u00a0and 2 moles of H<sub>2<\/sub>O. Since the O<sub>2<\/sub>\u00a0supplied is obtained from air, the system also contains N<sub>2<\/sub>.<sup>3<\/sup>\u00a0The amount of N<sub>2<\/sub>\u00a0associated with O<sub>2<\/sub>\u00a0is equal to 2 (mol O<sub>2<\/sub>) \u2219 79\/21 (mole ratio of N<sub>2<\/sub>\u00a0to O<sub>2<\/sub>\u00a0in air), that is, 7.52 moles per mole of natural gas. All of this N<sub>2<\/sub>\u00a0passes unreacted through the system and exits with the product gas. The complete material balance for the system is shown in\u00a0Figure 6.4.<\/p>\n\n\n\n<p>3.\u00a0This is a simplifying assumption regarding the composition of air. Obviously, air has many more constituents in addition to O<sub>2<\/sub>\u00a0and N<sub>2<\/sub>. However, unless required by rigorous specifications, the trace constituents are neglected and air is considered as a mixture of N<sub>2<\/sub>\u00a0and O<sub>2<\/sub>\u00a0with the molar ratio of N<sub>2<\/sub>\u00a0to O<sub>2<\/sub>\u00a0being 79\/21 (= 3.76).<\/p>\n\n\n\n<figure class=\"wp-block-image\"><img decoding=\"async\" src=\"https:\/\/learning.oreilly.com\/api\/v2\/epubs\/urn:orm:book:9780134594064\/files\/graphics\/06fig04.jpg\" alt=\"Image\"\/><\/figure>\n\n\n\n<p><a><\/a><strong>Figure 6.4<\/strong>&nbsp;Material balance on a natural gas burner.<\/p>\n\n\n\n<p>It can be seen that all the CH<sub>4<\/sub>&nbsp;and O<sub>2<\/sub>&nbsp;fed to the burner react completely and are not present in the outlet product stream. This is an idealized representation, because an actual operating burner may have some inefficiencies that result in incomplete combustion of CH<sub>4<\/sub>\u2014which will result in some unreacted CH<sub>4<\/sub>&nbsp;being present in the product stream, or more likely, some fraction of the CH<sub>4<\/sub>&nbsp;fed is converted to carbon monoxide (CO) rather than CO<sub>2<\/sub>. In any case, there will be unreacted O<sub>2<\/sub>&nbsp;present in the product stream. Further, excess O<sub>2<\/sub>&nbsp;is typically provided in combustion reactions to accomplish a complete conversion of the fuel. These situations will result in a material balance modified as follows:<\/p>\n\n\n\n<p>Modification 1 Excess Air Supplied<\/p>\n\n\n\n<p>Rework the material balance when the air supplied is 15% in excess of the stoichiometric requirements.<\/p>\n\n\n\n<p>Solution<\/p>\n\n\n\n<p>The stoichiometric O<sub>2<\/sub>&nbsp;requirement is as given by the previous equation:<\/p>\n\n\n\n<p>Stoichiometric O<sub>2<\/sub>&nbsp;requirement: 2 moles\/mole of CH<sub>4<\/sub><\/p>\n\n\n\n<p>Total O<sub>2<\/sub>&nbsp;supplied: 2.30 (= 2 \u00d7 1.15) moles\/mole of CH<sub>4<\/sub><\/p>\n\n\n\n<p>Total N<sub>2<\/sub>&nbsp;fed with O<sub>2<\/sub>: 8.65 (= 2.30 \u00d7 79\/21) moles\/mole CH<sub>4<\/sub><\/p>\n\n\n\n<p>This N<sub>2<\/sub>\u00a0will pass unreacted through the system, ending up in the product stream along with 1 mole of CO<sub>2<\/sub>\u00a0and 2 moles of H<sub>2<\/sub>O formed from CH<sub>4<\/sub>. In addition, the product stream will contain unreacted O<sub>2<\/sub>, the quantity of which is 0.30 moles (2.30 moles fed\u20142 moles reacted according to the equation). The resulting material balance is shown in\u00a0Figure 6.5.<\/p>\n\n\n\n<figure class=\"wp-block-image\"><img decoding=\"async\" src=\"https:\/\/learning.oreilly.com\/api\/v2\/epubs\/urn:orm:book:9780134594064\/files\/graphics\/06fig05.jpg\" alt=\"Image\"\/><\/figure>\n\n\n\n<p><a><\/a><strong>Figure 6.5<\/strong>&nbsp;Material balance on a natural gas burner\u2014excess air.<\/p>\n\n\n\n<p>Modification 2 Excess Air Supplied and Incomplete Combustion of Methane<\/p>\n\n\n\n<p>Rework the material balance when 1% of the CH<sub>4<\/sub>&nbsp;fed does not react in the burner. Further, of the CH<sub>4<\/sub>&nbsp;burned, only 90% undergoes complete combustion. Fifteen percent excess air is supplied.<\/p>\n\n\n\n<p>Solution<\/p>\n\n\n\n<p>The product gas mixture will now contain a total of six components: unreacted CH<sub>4<\/sub>, CO<sub>2<\/sub>, CO, H<sub>2<\/sub>O, N<sub>2<\/sub>, and O<sub>2<\/sub>. The quantity of air fed is that calculated earlier for modification 1. To calculate the quantities of various species formed and O<sub>2<\/sub>&nbsp;reacted and remaining, a balanced chemical equation for incomplete combustion of CH<sub>4<\/sub>&nbsp;(formation of CO, rather than CO<sub>2<\/sub>) is needed:<\/p>\n\n\n\n<p>CH<sub>4<\/sub>&nbsp;+ 1.5O<sub>2<\/sub>&nbsp;\u2192 CO + 2H<sub>2<\/sub>O<\/p>\n\n\n\n<p>From the given information, 1% of CH<sub>4<\/sub>&nbsp;does not burn, so CH<sub>4<\/sub>&nbsp;in the product stream is equal to 0.01 moles; 0.99 moles of CH<sub>4<\/sub>&nbsp;react, 90% according to the equation corresponding to complete combustion and 10% according to that corresponding to incomplete combustion to CO. Therefore,<\/p>\n\n\n\n<p>CO<sub>2<\/sub>&nbsp;formed: 0.99 \u00d7 0.90 = 0.891 moles<\/p>\n\n\n\n<p>CO formed: 0.99 \u00d7 0.10 = 0.099 moles<\/p>\n\n\n\n<p>H<sub>2<\/sub>O formed: 0.99 \u00d7 0.90 \u00d7 2 + 0.99 \u00d7 0.10 \u00d7 2 = 1.98 moles<\/p>\n\n\n\n<p>O<sub>2<\/sub>&nbsp;reacted: 0.99 \u00d7 0.90 \u00d7 2 + 0.99 \u00d7 0.10 \u00d7 3\/2 = 1.9305 moles<\/p>\n\n\n\n<p>Hence, unreacted O<sub>2<\/sub>\u00a0= 2.30 &#8211; 1.9305 = 0.3695 moles.\u00a0Figure 6.6\u00a0shows the resulting material balance.<\/p>\n\n\n\n<figure class=\"wp-block-image\"><img decoding=\"async\" src=\"https:\/\/learning.oreilly.com\/api\/v2\/epubs\/urn:orm:book:9780134594064\/files\/graphics\/06fig06.jpg\" alt=\"Image\"\/><\/figure>\n\n\n\n<p><a><\/a><strong>Figure 6.6<\/strong>&nbsp;Material balance on a natural gas burner\u2014excess air and incomplete combustion.<\/p>\n\n\n\n<p>This solution was obtained through stoichiometric proportions given by the two equations. Atomic species balances are implicit in these proportions. The same solution can be obtained through explicit atomic species balances. For example, the amounts of O<sub>2<\/sub>&nbsp;and N<sub>2<\/sub>&nbsp;in the feed are calculated as before. The amounts of various species in the outlet stream are unknown at this point and are denoted by unknown variables:&nbsp;<em>n<\/em><sub>1<\/sub>&nbsp;(moles of CH<sub>4<\/sub>),&nbsp;<em>n<\/em><sub>2<\/sub>&nbsp;(moles of CO<sub>2<\/sub>),&nbsp;<em>n<\/em><sub>3<\/sub>&nbsp;(moles of CO),&nbsp;<em>n<\/em><sub>4<\/sub>&nbsp;(moles of H<sub>2<\/sub>O),&nbsp;<em>n<\/em><sub>5<\/sub>&nbsp;(moles of O<sub>2<\/sub>), and&nbsp;<em>n<\/em><sub>6<\/sub>&nbsp;(moles of N<sub>2<\/sub>). Balance on each of the atomic species (C, H, O, and N) yield the following four equations:<\/p>\n\n\n\n<figure class=\"wp-block-image\"><img decoding=\"async\" src=\"https:\/\/learning.oreilly.com\/api\/v2\/epubs\/urn:orm:book:9780134594064\/files\/graphics\/e_06equ09.jpg\" alt=\"Image\"\/><\/figure>\n\n\n\n<figure class=\"wp-block-image\"><img decoding=\"async\" src=\"https:\/\/learning.oreilly.com\/api\/v2\/epubs\/urn:orm:book:9780134594064\/files\/graphics\/e_06equ10.jpg\" alt=\"Image\"\/><\/figure>\n\n\n\n<figure class=\"wp-block-image\"><img decoding=\"async\" src=\"https:\/\/learning.oreilly.com\/api\/v2\/epubs\/urn:orm:book:9780134594064\/files\/graphics\/e_06equ11.jpg\" alt=\"Image\"\/><\/figure>\n\n\n\n<figure class=\"wp-block-image\"><img decoding=\"async\" src=\"https:\/\/learning.oreilly.com\/api\/v2\/epubs\/urn:orm:book:9780134594064\/files\/graphics\/e_06equ12.jpg\" alt=\"Image\"\/><\/figure>\n\n\n\n<p>Equation E6.12\u00a0yields the moles of N<sub>2<\/sub>\u00a0in the outlet, n<sub>6<\/sub>, directly as 8.65, leaving three equations (E6.9, E6.10, and E6.11) in five unknowns. This system of equations cannot be solved unless more information provided in the problem statement is used to formulate two additional equations.<sup>4<\/sup>\u00a0The first equation is obtained from the information that only 99% of the CH<sub>4<\/sub>\u00a0is reacted. Since 1% of CH<sub>4<\/sub>\u00a0has not reacted, the following applies:<\/p>\n\n\n\n<p>4.\u00a0The\u00a0<em>degrees of freedom analysis<\/em>, typically covered in the material and energy balances course, discusses in detail the relationship between unknown variables, mass balance equations, and other equations and specifications needed for complete material and energy balance solution for the system. Here, we simply try to formulate as many equations as there are unknown variables.(<em>Continues<\/em>)<\/p>\n\n\n\n<figure class=\"wp-block-image\"><img decoding=\"async\" src=\"https:\/\/learning.oreilly.com\/api\/v2\/epubs\/urn:orm:book:9780134594064\/files\/graphics\/e_06equ13.jpg\" alt=\"Image\"\/><\/figure>\n\n\n\n<p>The second equation is obtained from the information that 90% of the CH<sub>4<\/sub>&nbsp;reacted undergoes complete combustion (it is converted to CO<sub>2<\/sub>), and the remaining 10% undergoes incomplete combustion (it is converted to CO). Therefore, the molar ratio between CO<sub>2<\/sub>&nbsp;to CO must be 9:<\/p>\n\n\n\n<figure class=\"wp-block-image\"><img decoding=\"async\" src=\"https:\/\/learning.oreilly.com\/api\/v2\/epubs\/urn:orm:book:9780134594064\/files\/graphics\/e_06equ14.jpg\" alt=\"Image\"\/><\/figure>\n\n\n\n<p>Equations E6.9,\u00a0E6.10,\u00a0E6.11,\u00a0E6.13, and\u00a0E6.14\u00a0form a system of five equations in five unknowns that are rewritten in matrix form as follows (equation E6.14\u00a0is reformatted as\u00a0<em>n<\/em><sub>2<\/sub>\u00a0&#8211; 9<em>n<\/em><sub>3<\/sub>\u00a0= 0 before entering it into the matrix form):<\/p>\n\n\n\n<figure class=\"wp-block-image\"><img decoding=\"async\" src=\"https:\/\/learning.oreilly.com\/api\/v2\/epubs\/urn:orm:book:9780134594064\/files\/graphics\/e_06equ15.jpg\" alt=\"Image\"\/><\/figure>\n\n\n\n<p>Equation E6.15\u00a0conforms to the matrix form\u00a0<strong>[A][X]<\/strong>\u00a0=\u00a0<strong>[B]<\/strong>\u00a0for simultaneous linear equations, where\u00a0<strong>[A]<\/strong>\u00a0is the matrix of coefficients,\u00a0<strong>[X]<\/strong>\u00a0is the vector of unknown variables, and\u00a0<strong>[B]<\/strong>\u00a0is the vector matrix of values (those on the right) of the equations. Several algorithms are available for obtaining solutions for such systems of equations, as described in\u00a0Chapter 4. One of the common algorithms involves taking the inverse of the matrix of coefficients, and multiplying it by matrix\u00a0<strong>[B]<\/strong>:<\/p>\n\n\n\n<figure class=\"wp-block-image\"><img decoding=\"async\" src=\"https:\/\/learning.oreilly.com\/api\/v2\/epubs\/urn:orm:book:9780134594064\/files\/graphics\/e_06equ16.jpg\" alt=\"Image\"\/><\/figure>\n\n\n\n<p>Several software programs allow execution of mathematical operations involving matrices, such as computation of a matrix inverse and matrix multiplication. The solution techniques using a spreadsheet program and Mathcad follow.<\/p>\n\n\n\n<p>Solution (using a spreadsheet program)<\/p>\n\n\n\n<p>The solution using Excel is shown in\u00a0Figure 6.7. The first step in the solution is entering the matrix of coefficients\u00a0<strong>[A]<\/strong>\u00a0and the vector matrix of values\u00a0<strong>[B]<\/strong>. As seen from\u00a0Figure 6.7,\u00a0<strong>[A]<\/strong>\u00a0forms a 5 \u00d7 5 array occupying cells B5 through F9, while\u00a0<strong>[B]<\/strong>\u00a0is entered in cells H5 through H9. To calculate\u00a0<strong>[A]<\/strong><sup>-1<\/sup>, first a 5 \u00d7 5 space is selected\u2014B12 through F16, as seen previously\u2014and the matrix inverse function is entered by typing =MINVERSE(B5..F9) followed by pressing the keys &lt;Ctrl+Shift+Enter> simultaneously. Excel calculates the inverse of the matrix and populates the cells B12 through F16 automatically. The solution to the material balance problem is then obtained by multiplying the matrices\u00a0<strong>[A]<\/strong><sup>-1<\/sup>\u00a0and\u00a0<strong>[B]<\/strong>. This is accomplished by selecting a 5 \u00d7 1 space (H12\u2013H16), entering the formula =MMULT(B12..B16,H5..H9), and pressing the keys &lt;Ctrl+Shift+Enter> simultaneously. The resultant solution of the problem is seen in the cells H12 through H16, which are the values for the number of moles of CH<sub>4<\/sub>, CO<sub>2<\/sub>, CO, H<sub>2<\/sub>O, and O<sub>2<\/sub>\u20140.01, 0.891, 0.099, 1.98, and 0.3695, respectively.<\/p>\n\n\n\n<figure class=\"wp-block-image\"><img decoding=\"async\" src=\"https:\/\/learning.oreilly.com\/api\/v2\/epubs\/urn:orm:book:9780134594064\/files\/graphics\/06fig07.jpg\" alt=\"Image\"\/><\/figure>\n\n\n\n<p><a><\/a><strong>Figure 6.7<\/strong>&nbsp;Excel solution of [A][X] = [B].<\/p>\n\n\n\n<p>Solution (using Mathcad)<\/p>\n\n\n\n<p>The system of linear equations\u00a0<strong>[A][X]<\/strong>\u00a0=\u00a0<strong>[B]<\/strong>\u00a0can be readily solved in Mathcad using the function lsolve(<strong>[A]<\/strong>,<strong>[B]<\/strong>).<sup>5<\/sup>\u00a0Figure 6.8\u00a0shows the Mathcad solution of the problem.<\/p>\n\n\n\n<p>5.\u00a0The algorithm used in the Mathcad\u00a0<em>lsolve<\/em>\u00a0function is called\u00a0<em>LU decomposition<\/em>, a type of elimination algorithm mentioned in\u00a0Chapter 4, the details of which are beyond the scope of this book.<\/p>\n\n\n\n<figure class=\"wp-block-image\"><img decoding=\"async\" src=\"https:\/\/learning.oreilly.com\/api\/v2\/epubs\/urn:orm:book:9780134594064\/files\/graphics\/06fig08.jpg\" alt=\"Image\"\/><\/figure>\n\n\n\n<p><a><\/a><strong>Figure 6.8<\/strong>&nbsp;Mathcad solution of [A][X] = [B].<\/p>\n\n\n\n<p>The calculation steps are as follows:<\/p>\n\n\n\n<p><strong>1.<\/strong>&nbsp;Enter the matrix coefficients by typing A:, and then either clicking on the matrix icon on the toolbar or pressing the &lt;Ctrl+m&gt; keys simultaneously. This brings up a dialog box; specify the number of rows and columns to be 5 each. This results in the creation of a 5 \u00d7 5 matrix with a placeholder for each matrix element. The values of the coefficients can now be entered by clicking on each placeholder.<\/p>\n\n\n\n<p><strong>2.<\/strong>&nbsp;Enter the matrix&nbsp;<strong>B<\/strong>&nbsp;using the same procedure, that is, by typing B: and pressing &lt;Ctrl+m&gt; or clicking on the matrix icon. The number&nbsp;of columns is 1 and the number of rows 5. Appropriate values are entered for each element.<\/p>\n\n\n\n<p><strong>3.<\/strong>&nbsp;Solve the system by typing X:lsolve(<strong>A<\/strong>,<strong>B<\/strong>).<\/p>\n\n\n\n<p><strong>4.<\/strong>&nbsp;Type X= results to display the solution.<\/p>\n\n\n\n<p>Alternatively, a solution can also be obtained by entering the expression&nbsp;<strong>X<\/strong>:<strong>A<\/strong><sup>-1<\/sup>*<strong>B<\/strong>. The solution is displayed by typing X=. Confirming that an identical solution is obtained is an exercise left to the reader.<\/p>\n\n\n\n<p>As can be seen from\u00a0Figures 6.6,\u00a06.7, and\u00a06.8, all three techniques yield identical solutions. It should be noted that it is not necessary to resort to matrix computations to solve this particular problem. The first equation readily yields the value of\u00a0<em>n<\/em><sub>1<\/sub>, as it involves only this variable. This value can then be substituted in other equations in appropriate sequence to solve other equations. Unfortunately, most practical systems will not yield such a convenient set of equations; however, the matrix computations illustrated here will be useful in arriving at the solution of the material balance problem.<\/p>\n\n\n\n<p>Most practical reacting systems will involve, apart from the desired reaction, several side reactions of the primary reactant of interest. Further, the reactant mixture will inevitably contain several other constituents that undergo multiple reactions as well. The system may have multiple outlet streams in different physical states (gas, liquid, solid). It can be understood that the complexity of the system can increase significantly. Such systems cannot be solved easily through manual calculations using a basic scientific calculator (as for the system previously discussed), necessitating the use of software such as Excel or Mathcad that can rapidly solve systems containing several dozens (and possibly hundreds) of equations and variables.<\/p>\n","protected":false},"excerpt":{"rendered":"<p>Reacting systems are characterized by the disappearance of reactants and appearance of the products. Clearly, molecular species are not conserved in the reaction, and at steady state, the rate of input of a compound participating in the reaction is not equal to the rate of its output. However,\u00a0as long as no nuclear reactions are occurring [&hellip;]<\/p>\n","protected":false},"author":1,"featured_media":4600,"comment_status":"open","ping_status":"open","sticky":false,"template":"","format":"standard","meta":{"footnotes":""},"categories":[562],"tags":[],"class_list":["post-4663","post","type-post","status-publish","format-standard","has-post-thumbnail","hentry","category-material-balance-computations"],"jetpack_featured_media_url":"https:\/\/workhouse.sweetdishy.com\/wp-content\/uploads\/2024\/09\/download-9-2.jpeg","_links":{"self":[{"href":"https:\/\/workhouse.sweetdishy.com\/index.php\/wp-json\/wp\/v2\/posts\/4663","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/workhouse.sweetdishy.com\/index.php\/wp-json\/wp\/v2\/posts"}],"about":[{"href":"https:\/\/workhouse.sweetdishy.com\/index.php\/wp-json\/wp\/v2\/types\/post"}],"author":[{"embeddable":true,"href":"https:\/\/workhouse.sweetdishy.com\/index.php\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/workhouse.sweetdishy.com\/index.php\/wp-json\/wp\/v2\/comments?post=4663"}],"version-history":[{"count":1,"href":"https:\/\/workhouse.sweetdishy.com\/index.php\/wp-json\/wp\/v2\/posts\/4663\/revisions"}],"predecessor-version":[{"id":4664,"href":"https:\/\/workhouse.sweetdishy.com\/index.php\/wp-json\/wp\/v2\/posts\/4663\/revisions\/4664"}],"wp:featuredmedia":[{"embeddable":true,"href":"https:\/\/workhouse.sweetdishy.com\/index.php\/wp-json\/wp\/v2\/media\/4600"}],"wp:attachment":[{"href":"https:\/\/workhouse.sweetdishy.com\/index.php\/wp-json\/wp\/v2\/media?parent=4663"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/workhouse.sweetdishy.com\/index.php\/wp-json\/wp\/v2\/categories?post=4663"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/workhouse.sweetdishy.com\/index.php\/wp-json\/wp\/v2\/tags?post=4663"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}