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| <div class="rightcolumn"><html><img style="border:3px solid #0A92D8" src="https://static.igem.org/mediawiki/2013/5/5b/Ucl_Top_labeled.png" /></html></div> | | <div class="rightcolumn"><html><img style="border:3px solid #0A92D8" src="https://static.igem.org/mediawiki/2013/5/5b/Ucl_Top_labeled.png" /></html></div> |
| <div class="columnclear"></div> | | <div class="columnclear"></div> |
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- | == Prototype Design ==
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- | <div id="protoalbum"></div>
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- | <div class="columnclear" style="margin-bottom:30px"></div>
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- | <div class="column3left">
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- | '''PCR machine'''
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- | The PCR machine design went through several iterations to maximise heat transfer. Our prototype is made of aluminium. Aluminium has a low specific heat capacity and good conductance, which makes it well suited for the PCR machine, in addition to being easy to machine during manufacture. The PCR machine is designed to contain a maximum number of tubes in the heater block with the same footprint as the Peltier that powers the heat transfer. As the number tube holes increase, there is less block material hence less thermal mass to heat and cool which ensures faster heat transitions.
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- | </div>
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- | <div class="column3middle"><html><img src="https://static.igem.org/mediawiki/2013/c/c1/Ucl_Heatblock2.png"/></html></div>
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- | <div class="column3right"><html><img src="https://static.igem.org/mediawiki/2013/1/15/Heatblock.png"/></html></div>
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- | <div class="columnclear" style="margin-bottom:30px"></div>
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- | <div class="column3left"><html><img src="https://static.igem.org/mediawiki/2013/b/b5/Ucl_Centrifuge.png"/></html></div>
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- | <div class="column3middle">
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- | '''Centrifuge'''
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- | The centrifuge is powered by a fan and can reach up to 3000 RPM. A fan is a cost-effective alternative to a brushless motor, while non-brushless motors are noisy. Our hardware are researching the most effective relative centrifugal force for our design.
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- | </div>
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- | <div class="column3right">
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- | '''Gel Electrophoresis and Transilluminator'''
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- | The key element of the gel box is the power supply. As our design is targeted towards a younger audience, we aim to avoid high voltage. While our current prototype reaches 120V, our team are researching a 40V power supply as a safer alternative.
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- | </div>
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- | <div class="columnclear" style="margin-bottom:30px"></div>
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- | <div class="column3left">
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- | '''PCB Design'''
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- | The electronics are designed as an Arduino Duemilanove shield and provide an interface between the micro-controller and the various hardware in the toolbox. The PCB is a two layered PCB designed to control one high power device on a H-bridge (up to 100W), four low power devices (up to 20W) and contains connections for several I2C devices and thermistors.
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- | ''Picture: PCB design for the Arduino shield, front and back''
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- | </div>
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- | <div class="column3middle"><html><img src="https://static.igem.org/mediawiki/2013/c/c1/Ucl_Heatblock2.png"/></html></div>
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- | <div class="column3right"><html><img src="https://static.igem.org/mediawiki/2013/1/15/Heatblock.png"/></html></div>
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- | <div align="center"><html><img src="https://static.igem.org/mediawiki/2013/2/26/Ucl_e_PCB.png" alt="PCB"/></html></div>
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