Heat pipe cover materials

Yesterday was the 25th of June and according to my plan, I should have some heat pipes in my lap ready to be tested... Alas, due to busy schedules at DTU (some departments close for summer and people are taking vacation), it won't be until next week that I will be fabricating the different components including the etched silicon wafers (and cutting/cleaning) and the top covers. Still plenty to write about though and I have sent in a draft of chapter 4 relating to heat pipe technology (a literature review) to Torben. I will be adding a short chapter on my work methods and how I arranged my time, held meetings and put the project together. At this point, I have to consider the possibility (very real) that these heat pipes will not work and as my supervisor said, it is about the logical process and how you failed that is importa.... ah feck that! They better work!

Building the container

Yesterday I spoke with Jan F. Pedersen, who is the manager/foreman of the MEK production labs at building 427S at DTU. As before, he was very helpful and we discussed some issues regarding the milling of my parts. Three issues were clarified:

Milling depth - Depending on the time available, 10 covers will be fabricated. The vacuum cavity area of the heat pipe will remain at 1 mm high while the depth of the etch will vary. The milling drill head is 1 mm in diameter and had to be taken into account so that the covers would fit over the etched structures. A 1 mm hole will be drilled through the top of the container so that it can be filled.

Polyvinyl chloride (image credit)

Material - There are many different plastics available at the MEK building but it was necessary to go to the workshop to check out what was ready for milling. As discussed in the last blog the material should have high heat thermal conductivity and a low coefficient of thermal expansion. PVC was chosen as it is available but I think there could be problems with it.

1. The thermal coefficient of expansion (E-6 mm/mm °C)  is 50.4 and for silicon is 3. Will the materials expand to a point which will create large stresses in the glue seal and rip the container?
2. The thermal conductivity of PVC (W/m °C) is approx. 0.20 and 149 for silicon. At the cooler condenser end, it will be necessary to release the heat so this material will not be efficient at doing this. A suggestion from Jacob at the 3D Fab Lab at DTU seems the right choice: orientate the heat pipe such that the heat is released through the silicon side.