I was inspired to make the stainless steel immersion tubes found in the following thread:
I made mine with the following materials
- x metres of annealed seamless stainless steel tube grade 316. Outer Diameter 12.7mm, Wall Thickness 0.9mm, ASTM 269. I got mine from Midway Metals in Sydney for $5 per metre.
- A hand bender, rated to bend thin walled stainless steel. Got one from ebay for $99.
- A tube cutter, again make sure it will cut thin wall stainless steel. I got mine from ebay for $32.
For 60cm tanks I recommend 3 metres of tubing
For 30cm tanks I recommend 2 metres of tubing
Your hand bender will have an inherent bend radius, using this you can calculate the length of tube that you will use up with each bend whether it be 90 degrees or 180 degrees and pretty much how much tube you will need depending on your design.
NOTES: I used 12.7mm tubing as you can then squeeze 12/16mm aquarium hosing on to it snugly (if you are paranoid use hose clamps as well). I also used 12.7mm OD tubing as its the maximum diameter you can get a hand bender for that is rated to bend stainless steel. Do not get thicker than 1.0mm walled stainless steel it will be a nightmare to bend. Make sure your stainless steel is annealed seamless tube this is specifically made for severe manipulation. This is for freshwater application only... the guys at midway said this would last 3 months in a saltwater tank lol. Good hand benders are each made for one specific diameter only, make sure you get the right one for your tube diameter.
I am happy to post links to the ebay items if I'm allowed to.
I'm pairing this with an Eheim 2213 and a Resun cl 200 chiller to chill 2 x 60cm tanks and ultimately 3 x 60cm, I'll update once this is done and give some feedback on the temp differences. I hope the info is useful.
A few months ago, I lost a lot of shrimps due to high temperature (around 32°C).
So I decided to make an aquarium chiller for my nano (20L).
My requirements were :
- Able to reduce by 5-7°C a 20L aquarium
- Economic electrically
- Part of the canister filtration system (no visual inconvenience)
- Not pricey (under 100$)
- Shrimp compatible (no copper used)
Becarefull : Aluminium is used to "exchange" the heat. It can be toxic if used in pH below 5.3
During my initial research, I found this interesting article :
I changed the peltier module used, here are the calculation :
For a 400W Peltier, if I have 4.9V in input, and the local temperature is 32°C, the temperature of my 20L aquarium should be 24°C for 40W used.
Here are all the needed parts :
- Peltier module : TEC1-12726 (50x50mm 400W) around 20$US
- Aluminium Water cooling block (76x68x8mm)
I prefer this one over the classic 50mm one because it's bigger so better thermal exchange
- 12V 240W Power supply (transform AC to DC)
- 100W LED driver (0.8-28V output) (adjust the tension on the peltier module)
- 2 Fan speed controllers (3A DC-DC step down converter)
- 12V Thermostat (the chiller is working only when it needs to)
- Heat sink (Noctua NH-D14)
Based on http://www.frostytech.com/articleview.cfm?articleid=2789&page=4 , this heat sink is perfect
- A 50x50mm copper sheet to make the connection between the heat sink and peltier module. The peltier is bigger than the heat sink base, so I thought it's better to have this sheet to reduce the heat of the Peltier
- 6mm silicon pipe (it's the diameter of the water cooling block)
- 6=>12 water pipe coupler
- Thermal paste
- Electrical cable
All the parts together :
The total cost is around 100$US (greatly depends on the heat sink, i bought mine 2nd hand)
The final build :
Just started to make some test, it's working perfectly!
The only drawback is that it reduce the outflow of my canister filter.
If you have any questions :)
I am in need some advice, I've no experience with plumbing whatsoever (with the exception of using canister filters with chillers if that counts) so please bear with me if my questions seem silly or obvious!
I came across 2 cheap 4 foot tanks with holes drilled already in the base of them that I am hoping to use. There are only a couple of minor scratches here and there and the only damage is on a back corner where the bezel is chipped - I intend to silicone this inside and out to be safe.
Anyway I have a few points that I'd really love help to address.
- How best to plumb these 2 sitting at the same height and integrate a sump.
- Is it feasible to use 2 eheim canisters with a my chiller connected to a sump? When I only ran one canister the flowrate was not quite enough and the chiller was turning on and off too frequently as a result. Do I have to just bite the bullet and fork out money on a pump instead?
- Opinions on how best to divide the setup into several bays for different colonies. Currently I am looking at following Paul Minett's lead using tropical flyscreen which has less than 0.4mm aperture but he has told me there is still the occasional fugitive baby.
Thanks in advance, once I actually start doing anything on this setup I will post the progress in a journal here. Once again NB I am totally clueless so I'd appreciate it if you could dumb down your suggestions for me :-)
Love and peace
We are blessed with a beautiful climate here in Australia, arguably mild summer and winter seasons compared to other continents around the world. However, we experience the infrequent heat waves and harsh summer days which inevitably require hobbyists who keep heat sensitive shrimps to explore cooling options for their tanks, perhaps more so for those living in the warmer regions. Shrimps require a consistent environment to flourish and temperature is one of such parameters that can be easily controlled with a chiller.
I will endeavour to outline easy-to-follow steps on how to select a chiller for your tank. As the target audience of this article is for the general hobbyists, I will not delve into physics, thermal dynamics or explain how a heat exchanger works.
Step 1: Determine the total water volume to be cooled
This is simply a measurement of your total water volume to be cooled. Please remember to include the water volume of the sump if your system runs on one.
Most tanks are rectangular or cubic shape so a simple Length x Width x Height measurement will suffice.
Example: For a 4’ x 18” x 18” tank,
120cm (L) x 45cm (W) x 45cm (H) = 243,000 cm3 = 243,000 ml = 243L
Step 2: Select a chiller based on total water volume to be cooled
Chillers are usually rated to cool a specific volume of water to a set temperature below ambient air temperature. Simply select a chiller that is rated to cool the water volume calculated in Step 1.
The general rule of thumb is to consider a chiller that is one size larger than what you require in order to be energy efficient. A chiller works a lot harder if it kicks in frequently. Selecting a larger chiller that kicks in less often can save you money in the long run.
Example: With reference to the example in Step 1,
(a) Hailea HC-100A is rated for 50L to 220L*.
(b) Hailea HC-130A is rated for 50L to 300L*.
(c) Hailea HC-150A is rated for 50L to 400L*.
Based on the above specifications, the HC-100A would not be adequate for our purpose.
While the HC-130A is rated appropriately and adequate to cool 243L, I would select the HC-150A following the general rule of thumb to go one size larger.
The efficiency of a chiller is affected by a number of factors ranging from ambient conditions, physical location of the chiller, flow rate, whether the air filter has been kept clean, etc.
It is also dependent on the cooling requirements to your specific environment. If you live in a very warm region and you would like to cool your tank 15 or 20 degrees Celsius lower than your ambient air temperature, you might have to consider a chiller that is two sizes larger.
Step 3: Select the appropriate flow rate to drive the selected chiller
The appropriate flow rate to drive the selected chiller is an important consideration.
If the flow rate is too slow, the water within the chiller gets cooled too quickly and the thermostat switches the chiller off. Warm water then enters the chiller triggering it to kick in again within a short period of time. This is not energy efficient and frequent kicking in of the compressor would result in more wear and tear.
If the flow rate is too fast, the water flows through the chiller too quickly to be cooled effectively. The chiller takes a longer time to cool the water in the tank, which is also not very energy efficient.
Example: With reference to Step 1 and Step 2, the Hailea HC-150A has a recommended flow rate of 250lph to 1,200lph*.
We need to consider a few things before we can decide the appropriate flow rate for the Hailea HC-150A. This depends on how you would like to drive the chiller. Below are 3 typical scenarios on how most hobbyists would drive their chillers.
A canister filter’s flow rate is usually rated without any filtration media (i.e. an empty canister) or without taking into account any inline equipment (e.g. inline heater, UV, pre-filter, CO2 diffuser, etc.). If you plan to have other equipment connected inline to your canister filter, I would recommend getting a canister filter that is rated on the higher side of the chiller’s recommended flow rate. Also, as the canister filter gets cycled and matures, dirty filtration media, hoses and pipes would also reduce the flow rate. In this instance, I would recommend getting a canister filter rated at 800 lph to 1,200 lph.
If you are planning to drive your chiller from a sump pump, you could potentially select a sump pump that is higher in flow than what is recommended for the chiller. The flow rate through the chiller can be easily adjusted by teeing off from the sump pump and controlled using a valve. This also allows you to ‘future proof’ your design if you should add more equipment in future (e.g. fluid reactors, UV, etc.). In this instance, I would recommend getting a sump pump of 1,200 lph to 2,000 lph, factoring in other considerations like pressure head, hose/pipe diameter, etc.
If you should elect to drive the selected chiller with a dedicated pump, with no intention of connecting any other inline equipment, I would recommend selecting a flow rate that is slightly above the mid-range of the chiller’s recommended flow rate. In this case, I would select a dedicated pump of around 800 lph. A dirty impellor would have a slower flow rate so it is recommended to clean your pump impellor periodically.
A few tips:
- Locate the chiller in a cool location away from direct sun.
- Do not enclose the chiller in a confined space (e.g. in the aquarium cabinet) without proper ventilating devices (e.g. exhaust fans, etc).
- Clean the air filter of the chiller (if applicable).
- Connect your chiller as the last piece of equipment before the water is returned back to the tank. You would want filtered clean water to be passing through the chiller as it is easier to clean canister filters, sump pumps or dedicated pumps than it is to flush out a dirty chiller.
*Specifications are taken from Hailea website (http://www.hailea.com/e-hailea/index.htm) as at 21 December 2015.
might interest all DIY. Enjoy! : https://www.youtube.com/watch?v=n5s8Cu59-NM