fixing typos and updating svg figure

idaes_examples/notebooks/docs/flowsheets/temperature_swing_adsorption/temperature_swing_adsorption.ipynb

@@ -230,7 +230,7 @@
    "source": [
     "### 2.2: Fix Specifications of Feed Stream in TSA Unit\n",
     "\n",
-    "The inlet speficications of the TSA unit are fixed to match the exhaust gas stream (stream 8) of <a href=\"https://pubs.acs.org/doi/abs/10.1021/ie5048829\">case B31B in the NETL baseline report</a>, which is a exhaust gas stream after 90% carbon capture by means of a solvent-based capture system."
+    "The inlet specifications of the TSA unit are fixed to match the exhaust gas stream (stream 8) of <a href=\"https://pubs.acs.org/doi/abs/10.1021/ie5048829\">case B31B in the NETL baseline report</a>, which is a exhaust gas stream after 90% carbon capture by means of a solvent-based capture system."
    ]
   },
   {
@@ -383,7 +383,7 @@
    "source": [
     "## Step 3:  Solve the TSA Unit Model\n",
     "\n",
-    "Now, we can simulate the TSA unit model by solving a square problem. For this, we need to set up the solver by using the pyomo component `SolverFactory`. We will be using the solver and solver options defined during the initialization."
+    "Now, we can simulate the TSA unit model by solving a square problem. For this, we need to set up the solver by using the Pyomo component `SolverFactory`. We will be using the solver and solver options defined during the initialization."
    ]
   },
   {

idaes_examples/notebooks/docs/flowsheets/temperature_swing_adsorption/temperature_swing_adsorption_doc.ipynb

@@ -230,7 +230,7 @@
       "source": [
         "### 2.2: Fix Specifications of Feed Stream in TSA Unit\n",
         "\n",
-        "The inlet speficications of the TSA unit are fixed to match the exhaust gas stream (stream 8) of <a href=\"https://pubs.acs.org/doi/abs/10.1021/ie5048829\">case B31B in the NETL baseline report</a>, which is a exhaust gas stream after 90% carbon capture by means of a solvent-based capture system."
+        "The inlet specifications of the TSA unit are fixed to match the exhaust gas stream (stream 8) of <a href=\"https://pubs.acs.org/doi/abs/10.1021/ie5048829\">case B31B in the NETL baseline report</a>, which is a exhaust gas stream after 90% carbon capture by means of a solvent-based capture system."
       ]
     },
     {
@@ -383,7 +383,7 @@
       "source": [
         "## Step 3:  Solve the TSA Unit Model\n",
         "\n",
-        "Now, we can simulate the TSA unit model by solving a square problem. For this, we need to set up the solver by using the pyomo component `SolverFactory`. We will be using the solver and solver options defined during the initialization."
+        "Now, we can simulate the TSA unit model by solving a square problem. For this, we need to set up the solver by using the Pyomo component `SolverFactory`. We will be using the solver and solver options defined during the initialization."
       ]
     },
     {

idaes_examples/notebooks/docs/flowsheets/temperature_swing_adsorption/temperature_swing_adsorption_test.ipynb

@@ -230,7 +230,7 @@
       "source": [
         "### 2.2: Fix Specifications of Feed Stream in TSA Unit\n",
         "\n",
-        "The inlet speficications of the TSA unit are fixed to match the exhaust gas stream (stream 8) of <a href=\"https://pubs.acs.org/doi/abs/10.1021/ie5048829\">case B31B in the NETL baseline report</a>, which is a exhaust gas stream after 90% carbon capture by means of a solvent-based capture system."
+        "The inlet specifications of the TSA unit are fixed to match the exhaust gas stream (stream 8) of <a href=\"https://pubs.acs.org/doi/abs/10.1021/ie5048829\">case B31B in the NETL baseline report</a>, which is a exhaust gas stream after 90% carbon capture by means of a solvent-based capture system."
       ]
     },
     {
@@ -383,7 +383,7 @@
       "source": [
         "## Step 3:  Solve the TSA Unit Model\n",
         "\n",
-        "Now, we can simulate the TSA unit model by solving a square problem. For this, we need to set up the solver by using the pyomo component `SolverFactory`. We will be using the solver and solver options defined during the initialization."
+        "Now, we can simulate the TSA unit model by solving a square problem. For this, we need to set up the solver by using the Pyomo component `SolverFactory`. We will be using the solver and solver options defined during the initialization."
       ]
     },
     {

idaes_examples/notebooks/docs/flowsheets/temperature_swing_adsorption/temperature_swing_adsorption_usr.ipynb

@@ -230,7 +230,7 @@
       "source": [
         "### 2.2: Fix Specifications of Feed Stream in TSA Unit\n",
         "\n",
-        "The inlet speficications of the TSA unit are fixed to match the exhaust gas stream (stream 8) of <a href=\"https://pubs.acs.org/doi/abs/10.1021/ie5048829\">case B31B in the NETL baseline report</a>, which is a exhaust gas stream after 90% carbon capture by means of a solvent-based capture system."
+        "The inlet specifications of the TSA unit are fixed to match the exhaust gas stream (stream 8) of <a href=\"https://pubs.acs.org/doi/abs/10.1021/ie5048829\">case B31B in the NETL baseline report</a>, which is a exhaust gas stream after 90% carbon capture by means of a solvent-based capture system."
       ]
     },
     {
@@ -383,7 +383,7 @@
       "source": [
         "## Step 3:  Solve the TSA Unit Model\n",
         "\n",
-        "Now, we can simulate the TSA unit model by solving a square problem. For this, we need to set up the solver by using the pyomo component `SolverFactory`. We will be using the solver and solver options defined during the initialization."
+        "Now, we can simulate the TSA unit model by solving a square problem. For this, we need to set up the solver by using the Pyomo component `SolverFactory`. We will be using the solver and solver options defined during the initialization."
       ]
     },
     {