I recently had a chance to brew with the professionals at a local brewery. They were brewing on a SABCO Brew-Magic (15 gallon) system that they use for their weekly small batch releases. The brewer explained the components and how they all worked together. The wort would circulate throughout the mash process and that the temperature would be kept constant by an electric heater that was in the circulation loop. And, the re-circulation helped with the efficiency and the clarity of the wort. The price tag for a system like this is way out of my price range, so buying one was not an option. It didn’t take long for me to start putting ideas together to build my own RIMS. My quest began to put something together that I could build cheaply and maybe upgrade over time. So, a low cost system (that was modular) is what I set out to build.
Editor's Note: Hello everyone, this article was previously released and the author had used PVC piping for some of the heated elements of the system. After a lot of feedback on the issue, I made the decision to take the article down after potential safety issues were raised. I spoke with the writer and he agreed to upgrade the system he had originally built to use SS parts and re-write the article for the new build. So thank you to you the readers who spotted an issue, and a big thank you to Ted for upgrading and re-writing which took a lot of work.
There is already a bunch of nice, well thought out, designs out on the web. But, many were not cheap to build. The biggest expense was going to be the pump. I lucked out, I already had a 1200 GPH pump that I bought for a Koi pond and it wasn’t being used anymore. Yes, I cleaned the crap out of it, literally. Next, all those stainless steel pipes and fittings were $10-15+ each, times 10 or more. It was adding up fast. I originally chose PVC for a bunch of the parts. It was cheap, but after a lot of push back from reviewers about PVC temperature ratings, I replaced the PVC parts for the heat chamber with stainless steel parts. This increased the cost about $65. So, if you had to buy everything and did your shopping around, everything should cost under $350.
To clean the RIMS, I get a few gallons of PBW solution in a bottling bucket and connect it to the pump input and just pump it through the system and back up to the bucket. I let it run for about 20 minutes to a half hour. I’ll switch out the PBW with some sanitized to get it squeaky clean. The system works great. Nice clean beer and my efficiency is up about 5%.
YOU MUST USE GFCI OUTLETS AND ALL ELECTRIC CONNECTIONS MUST BE GROUNDED!
This system is being used around water and hot wort. Accidents can and will happen. Don’t shortcut the safety of the electrical. If you don’t know how to do this, let some who does take care of the electrical work or save up and buy one.
Modular design
I wanted to make my setup modular and compact. Something I could build into a portable carry case.
Temperature
Use the temperature controller for more than just controlling re-circulation temperatures.
Pumping
Use the pump for more than just re-circulation during mashing.
Power
Project and electrical boxes for containing, controlling and switching things.
I set up my temperature controller with multiple switches to turn on and off the pump and heater. The power outputs from the controller box are wired to a standard A/C outlet within the covered box. So, the pump goes into the pump outlet and the heater goes into a heater outlet. I accomplished by breaking the hot power contact on the outlet and wiring them separately from the project box. Then, the switches will control whatever is plugged in to the outlets. This helps to keep the equipment modular. Now, I can plug in a heat wrap and control the temperature in a fermenter or pump water and moving wort between pots and to the fermenter using the switches on the project box.
Connections
I went with hose clamp connections between the heating element and the pump (not in the pictures), so they can be disconnected fairly easily. These will eventually be upgraded with some quick disconnects to make it even faster.
Temperature
I did not want to hard connect the temperature sensor to the heating chamber or the load on the heating element. By setting it up this way, I am able to plug in whatever load I wanted and mover the temperature probe to wherever I needed it. For example, I can use the temperature controller for my heater wrap to control fermenter temperatures or just move the probe to measure temperature of grain, cooling wort, liquid in a hot liquor tank, etc.
The liquid from the mash tun will come down into the pump on the right. The flow can be controlled with the valve before it enters the heating chamber on the left, where it is heated and forced back up to the mash tun.
I built a base out of some scrap wood. It is basically an “L” shape, with parts connected to it for stability and transport, and a box to hold pump. The dimensions will probably be different for yours, depending on size of the pump. My base dimensions: 18” long x 8” high x 7” deep
2a. Upper Tee Assembly:
Assembled the following parts using Teflon tape to complete the upper tee assembly.
2b. Hose End Adapters:
The heating element will thread through the outlet cover and into the 1" reducer in the Tee. Use Teflon tape or pipe joint compound to seal it! It is super important that this does not leak!!! You don’t want liquid getting into you electrical box.
Assembled the following parts using Teflon tape to complete the lower tee assembly:
3a. Screw the two tee assemblies together.
3b. Screw the electric box to your base.
I made a little housing for my pump. I will just pop out of its home for when I want to move it to another task.
4a. Attach valve and hose adapter to the pump output.
4b. Connect with a short hose to the heat chamber.
4c. Attach hose adapter and hose to pump input. This will connect to you mash tun.
5a. Make the Control Box and mount it to your base
5b. Cut holes for your switches and controller.
5c. Drill holes and insert rubber grommets to accept power cord input and output feeds.
5d. Install switches and controller into the case
6a. Black power lead and white neutral to pins 1 and 2 to power the controller.
6b. Black power lead to each switch inputs.
6c. Output of pump switch goes to the pump
6d. Output of heater switch to heat connect pin 5
6e. Output on pin 6 goes to the heater
6f. The neutral leads (white) get connected together and pair with the power lead outputs to go to the pump and heater outlets.
6g. Connect temperature sensor to pins 3 and 4.
I wired my heater and pump outputs to the electrical box. One socket for the heater. One socket for the pump. The pump and the heater can then plug into their proper outlet. I did this to make it more modular.
Editor's Note: Hello everyone, this article was previously released and the author had used PVC piping for some of the heated elements of the system. After a lot of feedback on the issue, I made the decision to take the article down after potential safety issues were raised. I spoke with the writer and he agreed to upgrade the system he had originally built to use SS parts and re-write the article for the new build. So thank you to you the readers who spotted an issue, and a big thank you to Ted for upgrading and re-writing which took a lot of work.
There is already a bunch of nice, well thought out, designs out on the web. But, many were not cheap to build. The biggest expense was going to be the pump. I lucked out, I already had a 1200 GPH pump that I bought for a Koi pond and it wasn’t being used anymore. Yes, I cleaned the crap out of it, literally. Next, all those stainless steel pipes and fittings were $10-15+ each, times 10 or more. It was adding up fast. I originally chose PVC for a bunch of the parts. It was cheap, but after a lot of push back from reviewers about PVC temperature ratings, I replaced the PVC parts for the heat chamber with stainless steel parts. This increased the cost about $65. So, if you had to buy everything and did your shopping around, everything should cost under $350.
To clean the RIMS, I get a few gallons of PBW solution in a bottling bucket and connect it to the pump input and just pump it through the system and back up to the bucket. I let it run for about 20 minutes to a half hour. I’ll switch out the PBW with some sanitized to get it squeaky clean. The system works great. Nice clean beer and my efficiency is up about 5%.
Safety First
YOU MUST USE GFCI OUTLETS AND ALL ELECTRIC CONNECTIONS MUST BE GROUNDED!
This system is being used around water and hot wort. Accidents can and will happen. Don’t shortcut the safety of the electrical. If you don’t know how to do this, let some who does take care of the electrical work or save up and buy one.
Modular design
I wanted to make my setup modular and compact. Something I could build into a portable carry case.
Temperature
Use the temperature controller for more than just controlling re-circulation temperatures.
Pumping
Use the pump for more than just re-circulation during mashing.
Power
Project and electrical boxes for containing, controlling and switching things.
I set up my temperature controller with multiple switches to turn on and off the pump and heater. The power outputs from the controller box are wired to a standard A/C outlet within the covered box. So, the pump goes into the pump outlet and the heater goes into a heater outlet. I accomplished by breaking the hot power contact on the outlet and wiring them separately from the project box. Then, the switches will control whatever is plugged in to the outlets. This helps to keep the equipment modular. Now, I can plug in a heat wrap and control the temperature in a fermenter or pump water and moving wort between pots and to the fermenter using the switches on the project box.
Connections
I went with hose clamp connections between the heating element and the pump (not in the pictures), so they can be disconnected fairly easily. These will eventually be upgraded with some quick disconnects to make it even faster.
Temperature
I did not want to hard connect the temperature sensor to the heating chamber or the load on the heating element. By setting it up this way, I am able to plug in whatever load I wanted and mover the temperature probe to wherever I needed it. For example, I can use the temperature controller for my heater wrap to control fermenter temperatures or just move the probe to measure temperature of grain, cooling wort, liquid in a hot liquor tank, etc.
The liquid from the mash tun will come down into the pump on the right. The flow can be controlled with the valve before it enters the heating chamber on the left, where it is heated and forced back up to the mash tun.
Parts List
- 1 Hose Fitting, Adapter, 3/4" NPT Male x 1/2" Barbed
- 1 Ball Valve Full Port 304 Stainless Steel w/Blue Vinyl Handle 2PC 2-PC
- 3 AC 110-120V 3 Pin I/O Control SPST Rocker Switch
- 2 Hose Fitting, Adapter, 1/2" NPT Male x 3/8" Barbed
- 1 White Silicone Tubing, 3/8"ID, 1/2"OD, 1/16" Wall, 10' Length (I’d recommend using ½ inch ID to go back to the tun, it won’t kink as easily.)
- 1 5500W 240V Screw-In Foldback Water Heater Element - High Watt Density
- 1 2-1/2" Thermowell Stainless Steel 304 - 1/2" Male x 1/2" Female
- 1 Hammond 1591ESBK ABS Project Box Black
- 1 Inkbird All-Purpose Digital Temperature Controller Thermostat w Sensor 2 Relays1 1/4"
- 1 1 1/4" X 8" Stainless Steel Pipe
- 2 1 1/4" Stainless Steel T
- 3 1 1/4" X 1/2" Stainless bushing
- 1 1 1/4" X 1" Stainless bushing
- 1 2 gang outdoor outlet box for GFI
- 1 GFI outlet
- 1 Standard Outlet
- 2 Outdoor A/C extension cords
Basic Build Steps
1. Build a Base
I built a base out of some scrap wood. It is basically an “L” shape, with parts connected to it for stability and transport, and a box to hold pump. The dimensions will probably be different for yours, depending on size of the pump. My base dimensions: 18” long x 8” high x 7” deep
2. Build the Heat Chamber and Connect the Pump
2a. Upper Tee Assembly:
Assembled the following parts using Teflon tape to complete the upper tee assembly.
- 1 1/4” Stainless Tee
- 1 1/4”x 8” Pipe
- 1 1/4" Male X 1/2" adapter
- Hose Fitting Adapter, 1/2" NPT - Male x 1/2" Barbed
- 1 1/4" Male X 1/2" adapter
- 2-1/2" Thermowell SS - 1/2" - Male x 1/2" Female
The heating element will thread through the outlet cover and into the 1" reducer in the Tee. Use Teflon tape or pipe joint compound to seal it! It is super important that this does not leak!!! You don’t want liquid getting into you electrical box.
Assembled the following parts using Teflon tape to complete the lower tee assembly:
- 1 1/4" Stainless Tee
- 1/4" Male X 1/2" adapter
- Hose Fitting Adapter, 1/2" NPT Male x 1/2" Barbed
- Single gang plastic outlet box
- Outlet cover with a 1.3” hole drilled in the center
- 1 1/4" Male X 1" adaptor
- 5500W 240V Screw-In Foldback Water Heater Element - High Watt Density
3. Complete the Heating Chamber
3a. Screw the two tee assemblies together.
3b. Screw the electric box to your base.
4. Attach the pump
I made a little housing for my pump. I will just pop out of its home for when I want to move it to another task.
4a. Attach valve and hose adapter to the pump output.
4b. Connect with a short hose to the heat chamber.
4c. Attach hose adapter and hose to pump input. This will connect to you mash tun.
5. Build the Heat Controller Box and Connect
5a. Make the Control Box and mount it to your base
5b. Cut holes for your switches and controller.
5c. Drill holes and insert rubber grommets to accept power cord input and output feeds.
5d. Install switches and controller into the case
6. Wire your RIMS up
6a. Black power lead and white neutral to pins 1 and 2 to power the controller.
6b. Black power lead to each switch inputs.
6c. Output of pump switch goes to the pump
6d. Output of heater switch to heat connect pin 5
6e. Output on pin 6 goes to the heater
6f. The neutral leads (white) get connected together and pair with the power lead outputs to go to the pump and heater outlets.
6g. Connect temperature sensor to pins 3 and 4.
I wired my heater and pump outputs to the electrical box. One socket for the heater. One socket for the pump. The pump and the heater can then plug into their proper outlet. I did this to make it more modular.