Difference between revisions of "Cooling"
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== Heat management == | |||
concept by Anton Tagunov | |||
http://octoray.co.uk/axiom/ | |||
== Internal Airflow Solution == | |||
Under consideration of these points: | |||
1. Flexibility: A solution with heat transmission via heatpipes or watercooling will reduce flexibility in designing or changing the body of the camera. | |||
2. Cooling: Cooling of the sensor for astrophotogrpahy (d450) reduce the sensor noise a lot, making the camera better. | |||
3. Cooling: For hot environments a solution is nessesary that goes below the environment temperature. | |||
4. Closed Body: Opening up the Body for air circulation makes waterproofness a problem | |||
5. Low noise: Active fan results in noise while shooting. | |||
One possible Solution would be an internal air-cooling, this means using a sealed body with a fan to keep the air inside moving. | |||
+ No hotspots or damaged hardware | |||
+ Chips or Hardware that are getting to hot can easily be equipped with heatsinks and therefore be cooled via airflow too. | |||
+ water proofness | |||
- noise: maybe still hearable outside | |||
- space: fan and guiding the airflow will take a lot of space | |||
Additionally peltier elements in the body with heatsinks that are keeping the air inside cooler than outside. | |||
+ Cooling is possible e.g. for astrophotgraphy or in the desert | |||
+ When you're in a development area running the camera without body is possible as long as room temperature is okay | |||
+ it's easy to remove and assemble the body because the parts are not connected to each other via heatpipes | |||
+ flexibility if you need more cooling, change the body and add more peltierelements or different cooling solutions | |||
- possibility for condensing water | |||
- space: heatsinks and peltier elements will take a lot of space | |||
== Technology Overview, Ideas and Research == | |||
Panasonic PGS could be use to transfer the heat from the FPGA to the Camera Body. It can reduce weight and makes the Camera smaller in the ideal case the Apertus doesn’t need a fan. | Panasonic PGS could be use to transfer the heat from the FPGA to the Camera Body. It can reduce weight and makes the Camera smaller in the ideal case the Apertus doesn’t need a fan. | ||
More Information: | More Information: | ||
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Sensible advice on thermoelectric cooling: http://www.customthermoelectric.com/TECmounting.html | Sensible advice on thermoelectric cooling: http://www.customthermoelectric.com/TECmounting.html | ||
Heat conductive plastics http://www.ptonline.com/articles/plastics-that-conduct-heat | |||
claimed heat conductivity: | claimed heat conductivity: | ||
- new plastics: 10-100 | |||
- cast magnesium: 50-100 | - new plastics: 10-100 W/mK | ||
- extrusion grade aluminum: 150 W/mK | |||
New plastics 10x more expensive than normal ones per kg, have thermal expansion closer to those of electronic components than metal, can be conductive (for shielding) or insulating | - cast magnesium: 50-100 W/mK | ||
- extrusion grade aluminum: 150 W/mK. | |||
New plastics 10x more expensive than normal ones per kg a bit more birttle, have thermal expansion closer to those of electronic components than metal, can be conductive (for shielding) or insulating |
Latest revision as of 14:25, 1 November 2014
1 Heat management
concept by Anton Tagunov
2 Internal Airflow Solution
Under consideration of these points:
1. Flexibility: A solution with heat transmission via heatpipes or watercooling will reduce flexibility in designing or changing the body of the camera.
2. Cooling: Cooling of the sensor for astrophotogrpahy (d450) reduce the sensor noise a lot, making the camera better.
3. Cooling: For hot environments a solution is nessesary that goes below the environment temperature.
4. Closed Body: Opening up the Body for air circulation makes waterproofness a problem
5. Low noise: Active fan results in noise while shooting.
One possible Solution would be an internal air-cooling, this means using a sealed body with a fan to keep the air inside moving.
+ No hotspots or damaged hardware
+ Chips or Hardware that are getting to hot can easily be equipped with heatsinks and therefore be cooled via airflow too.
+ water proofness
- noise: maybe still hearable outside
- space: fan and guiding the airflow will take a lot of space
Additionally peltier elements in the body with heatsinks that are keeping the air inside cooler than outside.
+ Cooling is possible e.g. for astrophotgraphy or in the desert
+ When you're in a development area running the camera without body is possible as long as room temperature is okay
+ it's easy to remove and assemble the body because the parts are not connected to each other via heatpipes
+ flexibility if you need more cooling, change the body and add more peltierelements or different cooling solutions
- possibility for condensing water
- space: heatsinks and peltier elements will take a lot of space
3 Technology Overview, Ideas and Research
Panasonic PGS could be use to transfer the heat from the FPGA to the Camera Body. It can reduce weight and makes the Camera smaller in the ideal case the Apertus doesn’t need a fan. More Information: http://www.panasonic.com/industrial/electronic-components/protection/pyrolytic-graphite-sheet.aspx Video: http://www.youtube.com/watch?v=ZAEhyY1_czM
A hole can be cut in the PCB to allow a metal plate to touch the back of the sensor (image courtesy of danieel)
Practical experience of cooling down a d450 sensor to sub-zero temperatures with Peltier http://nightskyinfocus.com/diyprojects/canon-450d-dslr-modification
Peltier sensor cooling can be an upgrade pack for Beta
danieel, speaking on KAC-12040 sensor [1]:
uncooled sensor without any thermal management gets to at most 45deg (internal reading).. so you should rather cool/separate the fpga, than care about a sensor (big package with relatively low power)
Sensible advice on thermoelectric cooling: http://www.customthermoelectric.com/TECmounting.html
Heat conductive plastics http://www.ptonline.com/articles/plastics-that-conduct-heat
claimed heat conductivity:
- new plastics: 10-100 W/mK
- cast magnesium: 50-100 W/mK
- extrusion grade aluminum: 150 W/mK.
New plastics 10x more expensive than normal ones per kg a bit more birttle, have thermal expansion closer to those of electronic components than metal, can be conductive (for shielding) or insulating