Difference between revisions of "Team:NCKU Tainan/Applied Design"

Line 38: Line 38:
 
                                         </div>
 
                                         </div>
 
                                         <p class="pcenter">Fig. 2 Overview of the control system </p>                                   
 
                                         <p class="pcenter">Fig. 2 Overview of the control system </p>                                   
                                         <p class="pcontent">There are many aspects we need to consider. First, we calculate the emission velocity of CO<sub>2</sub> from the factory, as well as the medium exchange rate and the growth rate of our <i>E. coli</i>.
+
                                         <p class="pcontent">There are many aspects we need to consider. First, we calculate the emission velocity of CO<sub>2</sub> from the factory, as well as the medium exchange rate and the growth rate of our <i>E. coli</i>.   </p>
 +
                                        <p class="pcontent">
 
Fig. 1 is a process of whole <i>E. coli</i> carbon utilization that we design for industrial application. We simplify it into three parts which shows in Fig. 2 to explain more clearly. Three switches control three parts, named A, B and C. Basically, the factory replaces the medium twice a day. At one hour before replacing the medium, the user needs to turn on switch C to discharge ninety percent of the medium. When it is time to replace the medium, switch C will be turned off and switch B will be turned on to refill medium. When sufficient medium is added, switch B will be turned off and switch A will be turned on to let CO<sub>2</su>b in. Just like the animation showed on Fig. 1.  
 
Fig. 1 is a process of whole <i>E. coli</i> carbon utilization that we design for industrial application. We simplify it into three parts which shows in Fig. 2 to explain more clearly. Three switches control three parts, named A, B and C. Basically, the factory replaces the medium twice a day. At one hour before replacing the medium, the user needs to turn on switch C to discharge ninety percent of the medium. When it is time to replace the medium, switch C will be turned off and switch B will be turned on to refill medium. When sufficient medium is added, switch B will be turned off and switch A will be turned on to let CO<sub>2</su>b in. Just like the animation showed on Fig. 1.  
  
Line 53: Line 54:
 
                                         </div>
 
                                         </div>
 
                                         <p class="pcenter"> Fig. 3 Diagram of gas preparation system and flow system </p>
 
                                         <p class="pcenter"> Fig. 3 Diagram of gas preparation system and flow system </p>
                                         <p class="pcontent">According to IGCC (Integrate Gasification Combined Cycle) flow diagram, the fuel is first converted to syngas which is a mixture of H<sub>2</sub> and CO. The syngas is then burned in a combined cycle consisting of a gas turbine and a steam turbine with a heat recovery steam generator (HRSG). After CO<sub>2</sub> / H<sub>2</sub> separation, IGCC can reach the demand of CO<sub>2</sub> purity including low SOx and NOx emission fraction of allowable limits of bacteria. Finally, the produced flue gas could enter the pipeline leading to the bioreactor.   
+
                                         <p class="pcontent">According to IGCC (Integrate Gasification Combined Cycle) flow diagram, the fuel is first converted to syngas which is a mixture of H<sub>2</sub> and CO. The syngas is then burned in a combined cycle consisting of a gas turbine and a steam turbine with a heat recovery steam generator (HRSG). After CO<sub>2</sub> / H<sub>2</sub> separation, IGCC can reach the demand of CO<sub>2</sub> purity including low SOx and NOx emission fraction of allowable limits of bacteria. Finally, the produced flue gas could enter the pipeline leading to the bioreactor.  </p>
 +
                                        <p class="pcontent">
 
In <i>E. coli </i>utilization system, the air is pumped in to neutralize the concentration of CO<sub>2</sub>. A controlled valve is used to control flow rate and split distribution. When the switch a is turned on, the switch b will be turned off, and vice versa. As for the CO<sub>2</sub> inlet and outlet, it will maintain an open system of bioreactor. In other words, CO<sub>2</sub> will enter continuously and cause some non-reacted CO<sub>2</sub> emitted.  
 
In <i>E. coli </i>utilization system, the air is pumped in to neutralize the concentration of CO<sub>2</sub>. A controlled valve is used to control flow rate and split distribution. When the switch a is turned on, the switch b will be turned off, and vice versa. As for the CO<sub>2</sub> inlet and outlet, it will maintain an open system of bioreactor. In other words, CO<sub>2</sub> will enter continuously and cause some non-reacted CO<sub>2</sub> emitted.  
 
                                         </p>
 
                                         </p>
Line 59: Line 61:
 
                                             <img class="smallimg" src="https://static.igem.org/mediawiki/2018/f/f4/T--NCKU_Tainan--IGCC.png" alt="medium">
 
                                             <img class="smallimg" src="https://static.igem.org/mediawiki/2018/f/f4/T--NCKU_Tainan--IGCC.png" alt="medium">
 
                                         </div>
 
                                         </div>
                                         <p class="pcenter"> Fig. 4 IGCC process flow diagram. source:
+
                                         <p class="pcenter"> Fig. 4 IGCC process flow diagram. Source: Vattenfall. (2010)
 
Syngas has been treated by sulfur and nitrogen removal, as well as heavy metal removal and cooling tank. Through IGCC process, purified CO<sub>2</sub> in flue gas is allowable for <i>E. coli</i> CO<sub>2</sub> utilizing. </p>
 
Syngas has been treated by sulfur and nitrogen removal, as well as heavy metal removal and cooling tank. Through IGCC process, purified CO<sub>2</sub> in flue gas is allowable for <i>E. coli</i> CO<sub>2</sub> utilizing. </p>
  
Line 68: Line 70:
 
                                         </div>
 
                                         </div>
 
                                         <p class="pcenter"> Fig. 5 Diagram of medium preparation</p>
 
                                         <p class="pcenter"> Fig. 5 Diagram of medium preparation</p>
                                         <p class="pcontent">At this stage, we have two sections to consider, medium storage and medium preparation before replacing time.   
+
                                         <p class="pcontent">At this stage, we have two sections to consider, medium storage and medium preparation before replacing time.</p>  
 +
                                        <p class="pcontent">
 
The medium is composed of M9 salt and xylose. For storage, we will convert it into powder with the required proportion. At one hour before replacing time, pour the powder into the medium tank and turn on the water injection switch. Turn on the stirrer of medium tank to have medium powder and water perfect mixing. The outlet of bioreactor (switch c) will be turned on at the same time, letting ninety percent of the medium in the bioreactor flow out . When the medium have prepared well, turn on the switch a and switch b for replacing medium in bioreactor, while the switch c will be turned off.
 
The medium is composed of M9 salt and xylose. For storage, we will convert it into powder with the required proportion. At one hour before replacing time, pour the powder into the medium tank and turn on the water injection switch. Turn on the stirrer of medium tank to have medium powder and water perfect mixing. The outlet of bioreactor (switch c) will be turned on at the same time, letting ninety percent of the medium in the bioreactor flow out . When the medium have prepared well, turn on the switch a and switch b for replacing medium in bioreactor, while the switch c will be turned off.
 
                                         </p>
 
                                         </p>
 
                                         <p class="pcontent">We also consider the process of raw materials, especially xylose, which is the key source of our pathway. Since xylose is one of the products of agricultural waste degradation, we visited the  <a class="link" href="#gas_and_flow_system">2018 Tainan Biotechnology and Green Energy Expo </a> to consulted with researchers from National Energy Program-Phase II, whose projects was biofuel and biodegradable plastic production via agricultural waste.  They had developed technique that degrade cellulose and semi-cellulose by ion solution.  
 
                                         <p class="pcontent">We also consider the process of raw materials, especially xylose, which is the key source of our pathway. Since xylose is one of the products of agricultural waste degradation, we visited the  <a class="link" href="#gas_and_flow_system">2018 Tainan Biotechnology and Green Energy Expo </a> to consulted with researchers from National Energy Program-Phase II, whose projects was biofuel and biodegradable plastic production via agricultural waste.  They had developed technique that degrade cellulose and semi-cellulose by ion solution.  
 
                                         </p>
 
                                         </p>
Besides, we have opportunity to collaborate with <a class="link" href="#gas_and_flow_system">UESTC-Chian team </a>. They work for degrading straw with synthetic biology and convert the product into bio-fuel. One of the product from straw degradation is xylose. These techniques are eco-friendly and low-energy-require. Therefore, the process development of xylose production will be a low-carbon-emission process.  
+
                                        <p class="pcontent">
 +
Besides, we have opportunity to collaborate with <a class="link" href="#gas_and_flow_system">UESTC-Chian team </a>. They work for degrading straw with synthetic biology and convert the product into bio-fuel. One of the product from straw degradation is xylose. These techniques are eco-friendly and low-energy-require. Therefore, the process development of xylose production will be a low-carbon-emission process.       </p>
 
                                         <h5 class="boldh5" id="downstream">C. Downstream products purification and biosafety</h5>
 
                                         <h5 class="boldh5" id="downstream">C. Downstream products purification and biosafety</h5>
 
                                         <div class="centerimg">
 
                                         <div class="centerimg">
Line 79: Line 83:
 
                                         </div>
 
                                         </div>
 
                                         <p class="pcenter"> Fig. 6 Diagram of downstream process</p>
 
                                         <p class="pcenter"> Fig. 6 Diagram of downstream process</p>
                                         <p class="pcontent">We will discharge 90% of the used medium in the bioreactor one hour before new medium flows in. Which means that we let 10% of the reacted bacteria remain in the bioreactor to maintain a steady cell density condition of in the bioreactor. The effluent medium will be sterilized and filtered in the downstream clean-up tank. At this step, we harvest the bacteria by centrifuging and extracting the by-product such as amino acids, proteins, medicine or bio-fuel. Different extracting process designed depends on different by-product.
+
                                         <p class="pcontent">We will discharge 90% of the used medium in the bioreactor one hour before new medium flows in. Which means that we let 10% of the reacted bacteria remain in the bioreactor to maintain a steady cell density condition of in the bioreactor. The effluent medium will be sterilized and filtered in the downstream clean-up tank. At this step, we harvest the bacteria by centrifuging and extracting the by-product such as amino acids, proteins, medicine or bio-fuel. Different extracting process designed depends on different by-product.</p>
 
+
<p class="pcontent">
 
Besides, we try to reuse the waste heat of factories for sterilizing. The waste water can be recycled as well. Through Removing toxins and adjusting pH value
 
Besides, we try to reuse the waste heat of factories for sterilizing. The waste water can be recycled as well. Through Removing toxins and adjusting pH value
  

Revision as of 02:08, 8 October 2018

Product Design

Follow us

Contact us

igem.ncku.tainan@gmail.com
No.1, Daxue Rd., East Dist., Tainan City 701, Taiwan (R.O.C.)