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=== Next steps ===
=== Next steps ===


Naturally, the next step is to increase the efficiency. This is as much a materials science challenge as it is an engineering challenge, as the efficiency of bulk thermoelectric materials it self is <6%. Hence, we plan to research on more inexpensive materials that show good Seebeck coefficient.  
Naturally, the next step is to increase the efficiency. This is as much a materials science challenge as it is an engineering challenge, as the efficiency of bulk thermoelectric materials it self is <6%. Hence, we plan to research on more inexpensive materials that show good Seebeck coefficient. The cost of making the coolers (or any TEM based machines) will go down drastically when mass-produced, hence, the costs for future machines is expected to go down by at least 40% as per our estimates.  


Another goal that we would like to pursue is the integration of thermoelectricity with photovoltaics, as they would boost efficiency overall when they're working in tandem.  
Another goal that we would like to pursue is the integration of thermoelectricity with photovoltaics, as they would boost overall efficiency when they're working in tandem or as a combination.  


== Conclusions ==
== Conclusions ==
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Thermoelectric materials, like solar cells, convert electricity directly without any moving parts, which is suitable for a static system. Hence finding an optimised material that exhibits good characteristics of both photovolaics and thermoelectricity is something that would benefit humanity greatly.   
Thermoelectric materials, like solar cells, convert electricity directly without any moving parts, which is suitable for a static system. Hence finding an optimised material that exhibits good characteristics of both photovolaics and thermoelectricity is something that would benefit humanity greatly.   


== References ==
1. B.V. Chaluvaraju, K. Sangappa, M.V. Ganiger, Murugendrappa,
Polym. Sci. 57(4), 467–472 (2015)





Revision as of 01:56, 1 February 2019

Thermoelectric cooler.

Introduction

Nearly two-thirds of the energy that is produced by conventional power generation methods is lost as heat. Be it in thermal power plants, nuclear power plants or something as common as a car, that we use everyday. By harnessing this heat, we increase the overall efficiency of the system, hence, reducing the carbon emission, and potentially saving huge amounts of money. Thermoelectric materials like bismuth and lead tellurides show high Seebeck coefficients, which essentially means that the amount of power generated per unit change in temperature is higher. This, along with high electrical conductivity and low electrical conductivity are the traits expected in a thermoelectric material. Historically, these materials have been used in Cassini and Voyager space missions.

Project Goals

Thermoelectricity is yet to be used on a large scale. The goal of the project was to build inexpensive thermoelectric modules to be in used in small, easy-to-make, and portable cooling machines. [1]

Design

The first step was to synthesise a good thermoelectric material. We chose to make polymer composites as is much cheaper than using bulk thermoelectric materials. Polymerised pyrrole (a conducting polymer) was used as the matrix, and it was reinforced with vanadium oxide nanobelts. Both were synthesised in the lab and pellets were made out of the resulting composite. These pellets were individually stacked in an appropriate fashion to create a thermoelectric module.

We built a small cooling machine out of scrapped metal sheets and thermal insulators. The thermoelectric module was coupled with exchangers and a heat sink and installed into the box through incisions. What this effectively does, is absorb the heat and covert it into electricity through the thermoelectric module, and use this electricity to run the assembled cooler.


Costs

Costs involved in making the thermoelectric module and cooler:

Expenditure TE Module Cooler Total
Raw Materials $45 $10 $55
Synthesis $30 $10 $40

Grand total = $95


Discussion

Although the efficiency of the system is low (<4%) due to the repeated conversion of the form energy, it is to be noted that no external source is used. Additionally, these coolers operate without any refrigerants.


Next steps

Naturally, the next step is to increase the efficiency. This is as much a materials science challenge as it is an engineering challenge, as the efficiency of bulk thermoelectric materials it self is <6%. Hence, we plan to research on more inexpensive materials that show good Seebeck coefficient. The cost of making the coolers (or any TEM based machines) will go down drastically when mass-produced, hence, the costs for future machines is expected to go down by at least 40% as per our estimates.

Another goal that we would like to pursue is the integration of thermoelectricity with photovoltaics, as they would boost overall efficiency when they're working in tandem or as a combination.

Conclusions

Thermoelectric materials, like solar cells, convert electricity directly without any moving parts, which is suitable for a static system. Hence finding an optimised material that exhibits good characteristics of both photovolaics and thermoelectricity is something that would benefit humanity greatly.


Contact details

E-mail: prajwal.ml714@gmail.com

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