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[[Category:Wort production]] [[Category:Equipment and maintenance]]
[[File:Grain-milled.png|thumb|Milled grain. Photo by Bryan Rabe.]]
[[Grain]] consists mainly of [[starch]] granules (endosperm) inside a husk. Before the [[mashing|mash]], grain must be mechanically crushed using a mill. The crushing process breaks open the husks, exposing the starch, and also cracks the starch into smaller bits, increasing the surface area exposed to water and [[enzymes]] during mashing.<ref name=mostra>Mosher M, Trantham K. [[library|''Brewing Science: A Multidisciplinary Approach.'']] 2nd ed. Springer; 2021.</ref> The crushed grain is referred to as ''grist''. In general, the crush quality affects the [[mashing|mashing process]], including [[starch|saccharification]] time, [[lautering]], [[efficiency]], [[fermentation]], as well as the color, taste, and overall character of the beer.<ref name="Kunze">Kunze W. Wort production. In: Hendel O, ed. [[Library|''Technology Brewing & Malting.'']] 6th ed. VLB Berlin; 2019:203–218.</ref><ref name="Mousia">Mousia Z, Balkin RC, Pandiella SS, Webb C. [https://www.sciencedirect.com/science/article/pii/S0032959203004400 The effect of milling parameters on starch hydrolysis of milled malt in the brewing process.] ''Process Biochem.'' 2004;39(12):2213–2219.</ref>


[[Grain]] (also called grist) consists mainly of starch granules inside a husk. Before the [[mashing|mash]], it must be mechanically crushed using a grain mill in order to break open the husk and expose the [[starch]] and [[enzymes]] inside. The starch granules (endosperm) are also crushed in the process, increasing their surface area. In general, the crush quality affects the [[mashing|mashing process]] and [[saccharification]] time, [[lautering]], [[efficiency]], [[fermentation]], and the color, taste, and overall character of the beer.<ref name="Kunze">Kunze, Wolfgang. "3.1 Milling the Malt." ''Technology Brewing & Malting.'' Edited by Olaf Hendel, 6th English Edition ed., VBL Berlin, 2019. pp. 203-218.</ref><ref name="Mousia">Mousia, Z., et al. [https://www.sciencedirect.com/science/article/pii/S0032959203004400 "The effect of milling parameters on starch hydrolysis of milled malt in the brewing process."] ''Process Biochemistry'', Vol. 39, No. 12, 2004, pp. 2213-2219.</ref>
Milling Process Overview:
# '''Weigh''' the grain on a [[scale]] per the recipe specifications.
# '''Condition''' the grain (optional)
# '''Crush''' the grain by adding it to the hopper and spinning the drive roller. The grist must be collected in a bucket or milled directly into the mash vessel.
# '''Verify''' the crush by visual inspection. It's generally a good idea to inspect the first handful of grain before continuing with the rest.


Basic Milling Process:
==Grain mills==
# Set the desired mill gap.
Why own a mill?
# Weigh out the grain on a [[scale]] per the recipe specifications.
* '''Freshness''' - Milling immediately before brewing results in the freshest malt possible (helping to avoid [[oxidation]]).
# Optional: Condition the grain. (See below)
* '''Control''' - Adjusting the gap allows you to tailor the crush to your own system and maximize [[efficiency]].
# Add the grain to the hopper.
* '''Consistency''' - The crush size may be inconsistent with pre-milled grain.
# Spin the drive roller to run the grain through the mill (into a container or directly into the mash tun). It's generally a good idea to visually inspect the crush after milling a handful of grain before continuing with the rest.
* '''Grain conditioning''' - Milling on site gives you the option to condition your grain (see below).
* '''Cost savings''' - A personal grain mill eventually pays for itself because A) you avoid a milling fee and B) you can buy grain in bulk.


==Grain Mills==
=== Features ===
A variety of options exist:
[[File:Knurled-rollers.jpg|thumb|right|Knurled rollers on a 3-roller mill (bottom view)]]
*'''3-roller vs 2-roller''' - In a 3-roller mill, the grain is pre-crushed in the gap between the top two rollers, and then the grain flows into the gap between the drive roller and bottom roller, crushing it further. The top gap is fixed at around 0.060–0.070" which easily pulls in both wheat and barley, providing superior feed, and softening the starch without tearing up the husk.<ref name="monster">[https://www.monsterbrewinghardware.com/store/pc/FAQs-d2.htm FAQs.] Monster Brewing Hardware. Accessed May 2020.</ref> The lowered husk damage aids in lautering among other things (see below). The double crush also more fully separates the husk from the starch. The downsides to 3-roller mills are that more power (torque) is typically required to drive them and they are generally more expensive. 2-roller mills are more budget friendly.
*'''Bearings vs bushings''' - Sealed ball bearings generally require no maintenance and can have a significantly longer lifespan than bushings, particularly if you drive the mill with a pulley.<ref>[https://www.homebrewtalk.com/threads/grain-mill-recomendations.662727/post-8529641 Grain mill recomendations.] Homebrew Talk website. 2019. Accessed 2020.</ref><ref>[https://www.homebrewtalk.com/threads/quality-corona-hand-crank-mill.645349/post-8224674 Quality corona/hand-crank mill?] Homebrew Talk website. 2018. Accessed 2020.</ref><ref>[https://www.homebrewtalk.com/threads/tell-me-about-grain-mills.666252/post-8598698 Tell me about grain mills.] Homebrew Talk website. 2019. Accessed 2020.</ref><ref>[https://www.homebrewtalk.com/threads/grain-mill-recomendation.672926/post-8734778 Grain mill recomendation.] Homebrew Talk website. 2019. Accessed 2020.</ref> On the other hand, bushings have more friction and may wear over time, such that they will need to be replaced at some point.<ref>Layosa C. [https://blog.misumiusa.com/introduction-to-working-with-linear-bushings-bushings-vs-bearings/ Introduction to working with linear bushings: bushings vs. bearings.] Misumi website. 2016. Accessed 2020.</ref><ref>[https://youtu.be/fJVGlvZQvGk Ball Bearings vs Bushings.] ServoCity on YouTube. 2017. Accessed 2020.</ref> Therefore we recommend a mill with sealed ball bearings. However, bushings are still an acceptable option when using a direct drive system such as a drill. Bushings may benefit from periodic cleaning and lubrication with a drop of food-grade mineral oil; check with the manufacturer.<ref name="LOB-1069">[http://www.themodernbrewhouse.com/forum/viewtopic.php?f=18&t=1069 Choosing a malt mill.] The Modern Brewhouse website. 2018–2020. Accessed 2020.</ref><ref>[https://www.homebrewtalk.com/threads/monster-mill-problems.102809/post-1141303 Monster mill problems.] Homebrew Talk website. 2009. Accessed 2020.</ref>
*'''Roller material''' - For most brewers, hardened steel is the best option for roller material due to its durability.<ref>[https://www.reliance-foundry.com/blog/carbon-steel-versus-stainless-steel Carbon steel vs stainless steel.] Reliance Foundry. Accessed June 2020.</ref> However, stainless steel has better protection against corrosion (although it is also more expensive). If you live in a damp or coastal region, stainless might be a good option.<ref>[https://www.monsterbrewinghardware.com/store/pc/3-Roller-Homebrew-Grain-Mill-p86.htm 3 roller homebrew grain mill.] Monster Brewing Hardware. Accessed June 2020.</ref>
*'''Roller diameter''' - Larger diameter helps the grain feed through the rollers.<ref name="Kunze"/><ref name=mashing>Evans E. [[Library|''Mashing.'']]  American Society of Brewing Chemists and Master Brewers Association of the Americas; 2021.</ref>
*'''Knurled vs fluted rollers''' - Roller morphology has an important effect on the crush by reducing damage to the husk. Modern ''commercial'' mills always have fluted rollers.<ref name=Mousia/><ref name=Kunze/><ref name=hob11>Miedl-Appelbee M. Brewhouse technology. In: Stewart GG, Russell I, Anstruther A, eds. [[Library|''Handbook of Brewing.'']] 3rd ed. CRC Press; 2017.</ref> On the other hand, most home brew mills have rollers with a diamond knurling pattern, which is necessary to improve the grain feed through small diameter rollers. A few home brew mills with relatively larger rollers (e.g. MattMill and Ss Brewtech) have a fluted morphology. However, the fluting pattern on these is completely different than commercial mills,<ref name=Kunze/> so it is unclear whether the fluting provides any benefit over knurling for home milling.
*'''Drive shaft''' - A 1/2" integrated drive shaft is the most durable. If you have a drill that you plan to use for milling, verify that it can fit on the drive shaft for the mill you want to purchase. (See [[Milling#Driving the mill|Driving the mill]] below)
*'''Hopper size''' - Hopper size is a matter of convenience and budget. It is most convenient to add the grain to the hopper all at once, however it doesn't hurt anything if you need to pause partway through milling in order to fill the hopper with more grain. Portability, weight, and storage space should be also be taken into account. Some mills have optional hopper extensions to purchase, or you can make a hopper extension yourself.
*'''Throughput rate''' - Differences in roller length and how fast the rollers feed grain is generally negligible for home brewers and not something that needs to be considered. Throughput depends largely on drive speed (RPM) and not the particular mill characteristics.
*'''Roller speed differential''' - Modern large-scale commercial mills have the rollers spinning at different speeds.<ref name=Kunze/> This increases the effectiveness of the crush by shearing off the husk from the endosperm, which serves to increase yield while reducing husk damage.<ref name=Mousia/> The only home brew mill with speed differential is from Ss Brewtech.


'''2-Roller Mills'''
=== Best mills available ===
* Malt Muncher 2 Roller ([https://www.morebeer.com/products/malt-muncher-2-roller-grain-mill.html?a_aid=ModernBrewhouse MoreBeer], [https://amzn.to/3bTOjnl Amazon])
{| class="wikitable"
* The Evill Twin ([https://www.morebeer.com/products/evill-twin-grain-malt-mill.html?a_aid=ModernBrewhouse MoreBeer])
!colspan="5"|2-Roller Mills
* Monster Mill MM2 ([https://www.morebeer.com/products/monster-mill-mm2-grain-complete-packages.html?a_aid=ModernBrewhouse MoreBeer])
|-
* Crankandstein 220C ([https://www.crankandstein.net/index.php?main_page=product_info&cPath=6&products_id=9 Direct from manufacturer])
!Mill
* MattMill Kompakt ([https://www.austinhomebrew.com/MattMill-Kompakt-Grain-Mill_p_7192.html Austin], [https://shop.humle.se/en/equipment/milling/mattmill-kompakt-grain-mill Humlegårdens])
!Rollers
* Cereal Killer, Kegco KM7GM-2R ([https://www.beveragefactory.com/homebrew/pre-fermentation-equipment/kegco-KM7GM-2R-grain-mill.html Beverage Factory] [https://www.austinhomebrew.com/Cereal-Killer-Grain-Mill_p_4432.html Austin])
!Bearing type
!Accessories
!Where to purchase
|- style="vertical-align:top;"
|[[File:Star-6-16.png|right|alt=star]]Cereal Killer, <br/>Kegco 2, <br/>Hullwrecker, <br/>Malt Muncher 2 <br/>(All the same)
|Knurled 1.25" x 5" hardened steel
|Sealed ball bearings
|Includes 7lb hopper and hand crank
|
* {{Amazon|B014M8WQIY}} (includes base)
* [https://www.homebrewing.org/Cereal-Killer-Grain-Mill_p_2310.html AIH] (includes base)
* [https://www.beveragefactory.com/homebrew/pre-fermentation-equipment/kegco-KM7GM-2R-grain-mill.html Beverage Factory] (includes base)
* [https://www.austinhomebrew.com/Cereal-Killer-Grain-Mill_p_4432.html Austin Homebrew Supply] (includes base)
* [https://www.northernbrewer.com/collections/grain-mills/products/hullwrecker-2-roller-grain-mill-base Northern Brewer] (includes base)
* {{MB|malt-muncher-2-roller-grain-mill}}
* {{MB|motorized-maltmuncher-pro-1}} (Motorized)
* {{Amazon|B074D9TP8B}}
|- style="vertical-align:top;"
|Monster Mill 2
|Knurled 1.5" x 6" hardened steel or stainless steel optional
|Bronze bushings
|11lb hopper, hopper extension, hand crank, and base are all optional.
|
*[https://www.monsterbrewinghardware.com/store/pc/2-Roller-Homebrew-Grain-Mill-p69.htm Monster Brewing]
|- style="vertical-align:top;"
|MattMill&nbsp;Kompakt
|Fluted 2.75" x 2" hardened steel
|Roller bearings<ref>[http://www.mattmill.de/wp-content/uploads/2018/12/MattMill-Docu-MMKP-MMKO-2018-EN.pdf "MattMill Kompakt / Kompakt Komfort documentation."] MattMill. 2018. Accessed 2020.</ref>
|Hand crank and base are optional and hopper is generally DIY.
|
*[https://www.austinhomebrew.com/MattMill-Kompakt-Grain-Mill_p_7192.html Austin Homebrew Supply]
|-
!colspan="5"|3-Roller Mills
|-
!Mill
!Rollers
!Bearing type
!Accessories
!Where to purchase
|- style="vertical-align:top;"
|[[File:Star-6-16.png|right|alt=star]]Kegco 3, <br/>Malt Muncher 3 <br/>(same)
|Knurled 1.5" x 6" hardened steel
|Sealed ball bearings
|Includes 12lb hopper and hand crank. Base is optional.
|
*[https://www.beveragefactory.com/homebrew/pre-fermentation-equipment/kegco-km11gm-3r-grain-mill.html Beverage Factory] (includes base)
*{{Amazon|B014M8WS14}} (includes base)
*{{MB|malt-muncher-3-roller-grain-mill}}
*{{Amazon|B074DBJR8X}}
*[https://www.brewhardware.com/product_p/grainmill3roller.htm Brew Hardware]
*[https://www.williamsbrewing.com/Home-Brewing-Equipment/Wort-Making-Equipment/Grain-Mills/Maltmuncher-Three-Roller-Mill William's Brewing]
|- style="vertical-align:top;"
|Monster Mill 3
|Knurled 1.5" x 6" hardened steel or stainless steel optional
|Bronze bushings
|11lb hopper, hopper extension, base, and hand crank are all optional.
|
*{{Amazon|B017MR35MS}}
*[https://www.monsterbrewinghardware.com/store/pc/3-Roller-Homebrew-Grain-Mill-10p86.htm Monster Brewing]
|-
!colspan="5"|Premium Motorized Mills
|-
!Mill
!Rollers
!Bearing type
!Accessories
!Where to purchase
|- style="vertical-align:top;"
|Ss Brewtech
|Fluted 4" diameter stainless steel, with speed differential
|Sealed ball bearings
|Includes motor and 25lb hopper. Base/cart is optional.
|
* {{MB|ss-brewtech-grain-mill}}
|- style="vertical-align:top;"
|MoreBeer UltiMill
|Knurled 2" diameter hardened steel
|Unknown
|Includes 60lb hopper with lid, motor, and stand.
|
*{{MB|ultimill-ultimate-grain-mill-3}}
|}
[[File:Star-6-16.png|alt=star]] = Editor's Pick


'''3-Roller Mills'''
Crankandstein has a few barebones mills that are suited to the DIY-inclined brewer. You can get a basic mill and mount it in any mill housing design of your choice. They offer a [https://www.crankandstein.net/index.php?main_page=product_info&cPath=7&products_id=11 2-roller] mill, [https://www.crankandstein.net/index.php?main_page=product_info&cPath=7&products_id=13 3-roller] mill, and a [https://www.crankandstein.net/index.php?main_page=product_info&cPath=6&products_id=9 2-roller mill that can also crush corn]. All of these have knurled hardened steel rollers and bronze bushings.
* Malt Muncher 3 Roller ([https://www.morebeer.com/products/malt-muncher-3-roller-grain-mill.html?a_aid=ModernBrewhouse MoreBeer], [https://amzn.to/2znt2Fy Amazon])
* Monster Mill MM3 ([https://www.morebeer.com/products/monster-mill-mm3-grain-complete-packages.html?a_aid=ModernBrewhouse MoreBeer], [https://amzn.to/2LRG5l9 Amazon])
* Kegco KM11GM-3R ([https://www.beveragefactory.com/homebrew/pre-fermentation-equipment/kegco-km11gm-3r-grain-mill.html Beverage Factory],  [https://amzn.to/2XpMYPV Amazon])


'''Motorized Mills'''
=== Mills to avoid ===
* Motorized MaltMuncher Pro ([https://www.morebeer.com/products/motorized-maltmuncher-pro-1.html?a_aid=ModernBrewhouse MoreBeer])
*'''The Barley Crusher''' - It has soft rollers and soft/cheap bronze bushings, which lead to relatively frequent problems and a short product lifespan.<ref>[https://www.homebrewtalk.com/threads/grain-mill-stopped-working.654248/ Grain mill stopped working.] Homebrew Talk website. 2018. Accessed 2020.</ref> Their customer service is also very poor.<ref>Barley Crusher - customer service???? Homebrew Talk website. 2012–2018. Accessed 2020. (This webpage has since been deleted. That's one more reason not to trust homebrewtalk.com)</ref>
* Ss Brewtech ([https://www.morebeer.com/products/ss-brewtech-grain-mill.html?a_aid=ModernBrewhouse MoreBeer]) [http://www.lowoxygenbrewing.com/brewing-methods/ss-brewtech-malt-mill/ User review] [http://www.lowoxygenbrewing.com/forum/viewtopic.php?f=18&t=1505 LOB thread]
*'''Suspicious budget mills''' such as the [https://www.vevor.com/products/electric-grain-mill-barley-grinder-malt-crusher-hold-up-to-11lbs-crushing-dy-368 motorized] and [https://www.vevor.com/products/grain-mill-barley-grinder-malt-crusher-3-roller-wheat-home-brew-food-industry 3-roller] mills at Vevor - These cheap mills have a number of {{amazon|B07D1Y51WT|bad reviews}} and generally don't have a strong track record, so we don't recommend these products at this time.<ref>[https://www.homebrewtalk.com/threads/anyone-try-those-cheap-ebay-motorized-grain-mills.688262/ Anyone try those cheap eBay motorized grain mills?] Homebrew Talk website. 2020–2021. Accessed Jan 4 2021.</ref>
* MoreBeer!® UltiMill ([https://www.morebeer.com/products/ultimill-ultimate-grain-mill.html?a_aid=ModernBrewhouse MoreBeer])
*'''Non-roller mills''' such as food processors, rolling pins, or Corona/Victoria style disc mills ({{Amazon|B00JZZKLHI|example}})<ref>[https://www.homebrewtalk.com/threads/my-ugly-junk-corona-mill-station.90849/ My ugly junk- Corona mill station.] Homebrew Talk website. 2008–2020. Accessed 2020.</ref> - These tools are not designed to create a proper crush, they're not easily adjustable, they tend to create a mess and/or require significant modification just to be useable.<ref name=bsp/> Corona-style mills are generally low-quality products (e.g. they may add metal shavings to the grist). Buy pre-milled grain until you're ready to invest in a roller mill.


== Mounting the mill ==
It is important to set up the mill on a base to keep the frames aligned properly. If the frames aren't straight, the rollers may bind.<ref>[https://www.monsterbrewinghardware.com/store/pc/catalog/MM-2-3-20Instructions.pdf "Monster Mill MM 2/3/PRO Instructions."] Monster Brewing Hardware, 2015.</ref> As you are securing it to the base, make sure all the rollers spin freely. Most mills either come with a base or have one available. These bases are typically designed to let the mill sit on top of a plastic bucket, and this setup is fine in most cases. However if you are adding a dedicated motor, it will be necessary to attach the mill to a larger base or table.


We have intentionally excluded the "Barley Crusher". It is a poor choice due to its soft rollers and soft/cheap bronze bushings, which lead to relatively frequent problems...<ref>[https://www.homebrewtalk.com/threads/grain-mill-stopped-working.654248/ "Grain mill stopped working."] HomeBrewTalk.com forum thread, 2018.</ref> and then there's the sub-par customer service.<ref>[https://www.homebrewtalk.com/threads/barley-crusher-customer-service.297352/ "Barley Crusher - Customer Service????"] HomeBrewTalk.com forum thread, 2012.</ref>
Monster Mill accessories like {{Amazon|B0064OMA04|this base}} will also work for the Kegco 3-roller mill.


Some brewers use very low budget milling options such as Corona/Victoria style mills<ref>[https://www.homebrewtalk.com/threads/my-ugly-junk-corona-mill-station.90849/ "My Ugly Junk- Corona Mill Station..."] HomeBrewTalk.com forum thread, 2008.</ref> (example: [https://amzn.to/3gnbSZk Amazon]), food processors, or rolling pins, but most likely you're better off buying your grain pre-milled if you're not ready to invest in a roller mill.
== Driving the mill ==
Three options exist for powering the mill. Any of these options can produce a good crush, so the choice of power just depends on your personal preference and budget. Warning: We do not recommend [https://www.homebrewtalk.com/threads/motorize-grain-mill-will-a-drill.403217/post-5086940 driving the mill with a hamster].


===Reasons to buy a mill===
# Hand crank
* '''Freshness''' - Milling immediately before brewing results in the freshest malt possible (which is especially important when using [[low oxygen brewing|brewing techniques to maintain fresh grain flavor]]).
# Electric drill
* '''Control''' - Adjusting the gap and speed allows you to tailor the crush to your own system and maximize efficiency.
# Electric non-drill motor
* '''Consistency''' - When other sources mill your grain, the crush size may be inconsistent.
* '''Grain conditioning''' - Milling at home gives you the option to condition your grain. (See below)
* '''Cost savings''' - A mill will eventually pay for itself since you avoid a milling fee and can buy grain in bulk.


===Features to consider===
=== Hand crank ===
'''3-roller vs 2-roller'''<br/>
A hand crank is available for many models, and attaches to the drive shaft with a screw. It is operated by turning the crank handle. This may get tiring for milling large amounts of grain.
The 3-roller works by pre-crushing the grain in the preliminary gap between the top two rollers, then opening the husk to expose the crushed kernel in the secondary gap with the third roller. The top gap is fixed at around .060" which easily pulls in both wheat and barley, softening the starch without tearing up the husk.<ref name="monster">[https://www.monsterbrewinghardware.com/store/pc/FAQs-d2.htm "FAQs"] Monster Brewing Hardware. Accessed May 2020.</ref> The 3-roller mill provides less husk damage, which aids in lautering (among other things). A 3-roller mill also more fully separates the starch from the husk, while providing superior grain feed. However, additional power is typically required to drive a 3-roller mill and they are generally more expensive.


'''Bearings vs bushings'''<br/>
=== Electric drill ===
While higher cost, sealed ball bearings generally require no maintenance<ref>[https://www.homebrewtalk.com/threads/grain-mill-recomendations.662727/post-8529641 "Grain Mill Recomendations."] HomeBrewTalk.com forum thread, 2019.</ref><ref>[https://www.homebrewtalk.com/threads/quality-corona-hand-crank-mill.645349/post-8224674 "Quality corona/hand-crank mill?"] HomeBrewTalk.com forum thread, 2018.</ref> and have can a significantly longer lifespan than bushings,<ref>[https://www.homebrewtalk.com/threads/tell-me-about-grain-mills.666252/post-8598698 "Tell me about grain mills...."] HomeBrewTalk.com forum thread, 2019.</ref> particularly if you drive the mill with a pulley or gears.<ref>[https://www.homebrewtalk.com/threads/grain-mill-recomendation.672926/post-8734778 "Grain Mill Recomendation."] HomeBrewTalk.com forum thread, 2019.</ref> Therefore we recommend a mill with bearings. However, bushings are still generally OK when using a direct drive system such as a drill. Bushings typically require periodic cleaning and lubrication with a drop of food-grade mineral oil.<ref name="LOB-1069">[http://www.lowoxygenbrewing.com/forum/viewtopic.php?f=18&t=1069 "Choosing a malt mill."] Low Oxygen Brewing forum thread, 2018.</ref><ref>[https://www.homebrewtalk.com/threads/monster-mill-problems.102809/post-1141303 "Monster mill problems."] HomeBrewTalk.com forum thread, 2009.</ref> A food-grade dry lubricant may possibly be used instead, although care must be taken when selecting a product.<ref>[https://www.homebrewtalk.com/threads/grain-mill-issues.638539/ "Grain mill issues."] HomeBrewTalk.com forum thread, 2017.</ref>
[[File:Milling-drill.png|thumb|Driving the mill with a cordless drill. Photo by Rob Stein.]]
For most home brewers a drill is the preferred method to drive a mill. It is easier to set up and more economical than using a non-drill motor, and significantly less laborious than hand cranking. Low RPM drills provide the best torque. We don't recommend using an external speed limiter ({{Amazon|B00U3LD1WA|example}}) on a high RPM drill because they significantly reduce the torque.<ref>[https://www.homebrewtalk.com/threads/speed-controller-for-corded-drill-used-for-milling-grain.629645/ Speed controller for corded drill, used for milling grain?] Homebrew Talk website. 2017. Accessed 2020.</ref><ref>[https://www.homebrewersassociation.org/forum/index.php?topic=23703 Monster mill drill question.] American Homebrewers Association website. 2015. Accessed 2020.</ref> Affixing a zip tie, 2" tri-clamp, or U-bolt to the trigger of a variable speed drill can help control and maintain a constant speed. A corded drill is generally more powerful than a cordless one, and will usually last longer. However cordless drills can also work well.<ref>[https://www.beeradvocate.com/community/threads/need-drill-recommendations.581479/ Need drill recommendations.] BeerAdvocate website. 2018. Accessed 2020.</ref><ref>[https://www.homebrewersassociation.org/forum/index.php?topic=9367 Proper drill for milling grain.] American Homebrewers Association website. 2011. Accessed 2020.</ref> The one requirement to using a drill is that the drill chuck fits onto the mill drive shaft (which range from 3/8" to 1/2" [9-12mm]). If you are holding the drill while milling, you must also hold down the base of the mill. Otherwise the torque may cause the mill to flip over, causing damage to equipment and/or personal injury.


'''Roller diameter'''<br/>
{| class="wikitable"
Larger diameter helps the grain feed through the rollers.<ref name="Kunze"/>
|+ Recommended Products
|[https://www.harborfreight.com/power-tools/drills-drivers/drill-mixers/75-amp-12-in-low-speed-spade-handle-drillmixer-56179.html Bauer corded drill from Harbor Freight] || 1/2" chuck, 0-600 rpm, variable speed. These are tried and true, and are frequently recommended by home brewers due to the low cost.
|-
|{{Amazon|B086K5Q6JG|Greenworks 24V cordless drill (Amazon)}} || 1/2" chuck, 0-380 rpm (also has higher speed setting), variable speed, brushless.
|}


'''Roller material'''<br/>
=== Non-drill motor ===
For most brewers, hardened steel is the best option for roller material due to its durability. However, stainless steel has better protection against corrosion (although it is also more expensive). If you live in a damp or coastal region, stainless might be a good option.<ref name="bison">Green, T. [https://bisonbrew.com/grain-mill/ "The Best Grain Mills For Homebrewing."] Bison Brew. 2020.</ref>
Some brewers prefer using a dedicated non-drill motor. See [[Motorizing a mill]].


'''Knurled vs fluted rollers'''<br/>
=== Reducing torque requirement ===
Roller morphology is an important parameter in the resulting crush.<ref name="Mousia"/> Modern commercial mills always have fluted rollers.<ref name="Kunze"/> However, no home brew rollers exist that are comparable to commercial rollers. Knurled rollers are most common on home brew mills.
If your drill/motor is having issues with stalling, or you'd like to reduce the load on it in order to extend its life, or you are wanting an easier job of hand cranking, you can reduce the amount of torque needed to drive the mill by reducing the amount of grain feeding into the rollers. All you need to do is create and affix cardboard inserts into the bottom of the hopper.


'''Hopper size'''<br/>
<gallery widths=300px heights=300px mode="nolines">
Hopper size is simply a matter of convenience and budget. It doesn't hurt anything if you need to pause partway through milling in order to fill the hopper with more grain, so larger hoppers generally aren't necessary. However, it is more convenient to add the grain to the hopper all at once, and some mills have optional hopper extensions to hold more grain. Portability, weight, and storage space should be also be taken into account in you are considering purchasing a hopper extension. It is also possible to make a hopper extension yourself.
File:Mill-tabs.jpg
 
File:Roller-mill-flow-limiting2.jpg
'''Throughput rate'''<br/>
File:Torque-barrier.png
Differences in roller length and/or how fast the rollers pull in grain is generally negligible for home brewers, and not something that needs to be considered.
File:Clear-flow-limiters.png
</gallery>


===Gap Setting===
==Setting the gap==
[[File:Milled-barley.jpg|thumb|0.049" dry crushing on a 3 roll at around 70 RPM, courtesy of Bilsch on LOB]]
[[File:Angled-feeler-gauge.png|thumb|An angled feeler gauge for measuring the roller gap on a 3-roller mill. Photo by Dr. Adam Bittner]]
All of the mills recommended here have an adjustable roller gap. Generally a smaller roller gap produces smaller grain particles.
All of the mills we recommend have an adjustable roller gap. A tighter gap produces smaller grain particles, called a fine crush, and a larger gap creates a coarse crush. '''There is not a one-size-fits-all gap setting.''' The ideal mill gap setting is dependent on your mill, your brewing system, and factors related to the grain (which can vary even from batch to batch and with storage time).<ref name=Kunze/><ref name=Crescenzi>Crescenzi AM. [https://onlinelibrary.wiley.com/doi/abs/10.1002/j.2050-0416.1987.tb04498.x Factors governing the milling of malt.] ''J Inst Brew.'' 1987;93:193–201.</ref><ref name=delucchi>Delucchi V. [https://byo.com/article/the-perfect-crush/ The perfect crush.] Brew Your Own website. 2019. Accessed January 2021.</ref> For each batch, the objective is to find an acceptable middle ground between lautering/recirculation effectiveness, [[efficiency]] (yield), and quality.<ref name="Briess">Hansen B. [https://web.archive.org/web/20190712061433/https://www.brewingwithbriess.com/Assets/Presentations/Briess_2007CBC_Practical_Milling.ppt Practical milling for the craft brewer.] Briess Malt & Ingredients Co. 2007. Accessed 2020.</ref><ref name=smart3>Holbrook CJ. Brewhouse operations. In: Smart C, ed. [[Library|''The Craft Brewing Handbook.'']] Woodhead Publishing; 2019.</ref> Some experimentation with different settings is needed to find out what works best for your mill and your brewing system, although there is a wide range that will be adequate.<ref>[http://www.themodernbrewhouse.com/forum/viewtopic.php?f=2&t=1795 Mashing for high gelatinisation temps.] The Modern Brewhouse website. 2020. Accessed 2020.</ref> Also, the grist should be visually monitored every milling to ensure it is being properly crushed.


The optimal mill gap setting is dependent on your mill, your brewing system, and other factors. Therefore there is not a one-size-fits-all gap setting. For some brewing systems, the husks must be disintegrated as little as possible during milling because they are required for [[lautering]]. For other brewing systems such as [[BIAB]], the grain can be finely milled if desired. The ideal gap setting can even vary based on the particular batch or type of grain. For example, less well modified malt requires finer milling.<ref name="Kunze"/> The crush should be monitored every milling to ensure it is being properly crushed. Barley is an agricultural product and friability and kernel size assortment vary from maltster-to-maltster and even harvest-to-harvest.<ref>Delucchi, V. [https://byo.com/article/the-perfect-crush/ "The Perfect Crush."] ''Brew Your Own'', 2019.</ref> It is important that you experiment with different settings and find out what works best for you. Milling ultimately is a compromise that each brewer reaches with a batch of grain.<ref>Hansen, B. [http://www.brewingwithbriess.com/Assets/Presentations/Briess_2007CBC_Practical_Milling.ppt "Practical Milling for the Craft Brewer."] Briess Malt & Ingredients Co., 2007.</ref> The objective is to find an acceptable middle ground between efficiency (yield), lautering effectiveness, and quality.
There are two main things to consider when experimenting with the roller gap:
# The gap must be small enough so that all the kernels are crushed, which helps to maximize efficiency. This can easily be verified by milling about a cup of grain and visually inspecting it (carefully sort through it looking for uncrushed kernels).<ref name=pro/>
# The gap must be large enough to avoid problems with a [[stuck mash]] or slow lautering/recirculation.<ref name=bsp/><ref name=pro>Miller D. [http://brewlikeapro.net/maltmilling.html Mills and milling.] Brew Like A Pro website. 2012. Accessed 2020.</ref><ref name=kuhbeck>Kühbeck F, Dickel T, Krottenthaler M, et al.  
[https://onlinelibrary.wiley.com/doi/pdf/10.1002/j.2050-0416.2005.tb00690.x Effects of mashing parameters on mash β-glucan, FAN and soluble extract levels.] ''J Inst Brew.'' 2005;111(3):316–327.</ref><ref name=kall>Kallmeyer M. [https://draymans.com/to-mash-or-not-to-mash-kurzhoch/ To mash or not to mash Kurz/Hoch.] Drayman's Brewery website. 2016. Accessed online March 2024.</ref> This greatly depends on your system/process, and experimentation is required to find the smallest acceptable gap. For example, a simple BIAB system can tolerate a fine crush, whereas a recirculating system tends to benefit from more intact husks. Keep in mind that excessive husk damage can potentially affect beer quality (see below).<ref name=Mousia/> Also be aware that 2-roller mills have a lower limit at which the rollers can feed the grain.


For most systems, usually a gap in the range of 0.030" to 0.050" (0.7–1.2mm) is appropriate.<ref name="LOB-1069"/><ref>[http://www.lowoxygenbrewing.com/forum/viewtopic.php?f=4&t=697 "Dry crush mill gap."] Low Oxygen Brewing forum thread, 2018.</ref> Generally it is not necessary to change the gap frequently, but crush should be monitored to ensure consistency. On 2-roller mills you will find a point at which the mill will stop feeding the grain if you close the gap too tightly.
For most systems, a gap in the range of 0.025" to 0.050" (0.7–1.2mm) is appropriate.<ref name="LOB-1069"/><ref>[http://www.themodernbrewhouse.com/forum/viewtopic.php?f=4&t=697 Dry crush mill gap.] The Modern Brewhouse website. 2018. Accessed 2020.</ref> To measure this, a feeler gauge (which is a stack of metal pieces with different marked thicknesses) can be inserted into a gap to precisely measure it. To achieve gaps that are not the same as a single blade, stack multiple blades together to add up to the gap you want to set. In a pinch, a standard credit card can be used to set a 0.030" (0.76mm) gap.<ref>[https://en.wikipedia.org/wiki/ISO/IEC_7810 "ISO/IEC 7810."] Wikipedia. Accessed May 2020.</ref> If you have a 3-roller mill, an angled feeler gauge should be used because a straight feeler gauge cannot access the adjustable gap while the mill is assembled.


Un-crushed kernels with fully intact husks represent a direct loss of efficiency, so we want to avoid a so coarse (large roller gap) that it does not crush all the grain. The large difference (relatively speaking) in brewhouse efficiency is between coarse and normal crushed malt. In a normal sample, you will find no un-crushed kernels. A fine crush gives only a small increase in efficiency (relative to a normal crush), but a large increase in lauter time and difficulty.<ref name="pro">Miller, D. [http://brewlikeapro.net/maltmilling.html "Mills and Milling."] ''Brew Like A Pro'', 2012.</ref>
{| class=wikitable
 
|+Recommended products
For your first trial at milling you may have to make a best guess with regard to the gap setting. If you have no test sieves, a good option is to adjust the mill by carefully evaluating one-cup samples.<ref name="pro"/> Start with the stock gap setting, or about 0.045" (1.1mm). Keep tightening the gap until you no longer find any un-crushed kernels. The problem with the "eyeball" evaluation is that even a one-cup sample requires a lot of patience to pick through. Obviously, the coarser the crush, the more intact kernels there will be, and the easier it is to find one. However, as you tighten the mill down uncrushed grains become harder to find &mdash; or to be sure they are not to be found.
|-
 
|{{Amazon|B07B3TQQSV|Straight feeler gauge (Amazon)}} || Blades range from 0.001" to 0.040" (0.03mm to 1mm)
Particle size plays an important role in the [[gelatinization]] process, which affects the mash results. Specifically, decreasing the mill gap increases the sugar concentrations during the mash and also reduces the time needed for mashing.<ref name="Mousia"/> However your "mileage may vary" depending on your system, process, and ingredients.<ref>[http://www.lowoxygenbrewing.com/forum/viewtopic.php?f=2&t=1795 "Mashing for high gelatinisation temps."] Low Oxygen Brewing forum thread, 2020.</ref>
|-
 
|{{Amazon|B004FEPDJU|Angled feeler gauge (Amazon)}} || Blades range from 0.005" to 0.020" (0.127mm to 0.508 mm)
'''Measuring the gap'''<br/>
|}
A feeler gauge should be used to adjust the gap setting. This tool is a stack of metal pieces with different marked thicknesses, which you can insert into a gap to precisely measure it. To achieve gaps that are not the same thickness as a single blade, stack multiple blades together to add up to the gap you want to measure. If you have a 3-roller mill and a normal (straight) feeler gauge, it is best to measure the gap before assembly, otherwise the adjustable gap will be inaccessible. If for some reason you do not want to buy a feeler gauge, you could use a credit card to get close to a 0.038" (1mm) gap.


[[File:Gap-markings.jpg|thumb|right|Gap settings marked by the adjustment knobs]]
Process:
Process:
# Insert the gauge as you are adjusting the gap. The blades should go into the gap between the rollers with a minimum amount of force, and should not be crushed in the gap. Try to adjust the gap on both ends of the roller to be the same.<ref name="monster"/><ref>Ream, J. [http://www.homebrewengineer.com/adjust-mill-gap-barley-crusher/ "How To: Adjust the Mill Gap of a Barley Crusher."] Homebrew Engineer blog, 2015.</ref>
# Insert the gauge into a loose gap and then gently tighten the rollers on it. The blades should go into the gap between the rollers with a minimum amount of force, and should not be crushed in the gap. Adjust the gap on both ends of the roller to be the same.<ref name=monster/><ref>Ream J. [http://www.homebrewengineer.com/adjust-mill-gap-barley-crusher/ How to: adjust the mill gap of a barley crusher.] Homebrew Engineer blog. 2015. Accessed 2020.</ref>
# On mills with adjustment knobs you can mark an arrow on the knob, and then turn it to set the gap at different points and mark on the frame what the gap is at the corresponding knob position. This way you can repeat different gap settings without getting out your feeler gauge again. It would be wise to mark in increments of 0.005" from 0.025" to 0.055" (every 0.1mm).
# On mills with adjustment knobs, mark on the frame what the gap is at the a variety of knob positions. This allows you to repeat different gap settings without needing the feeler gauge again. We suggest marking increments every 0.005" (0.1mm) over a range of 0.020" to 0.055" (0.5–1.4mm).
 
===Driving the Mill===
Generally three options exist for powering the mill:
# Hand crank
# Drill
# Dedicated motor
 
Any of these options can produce a good crush, so what you choose just depends on your preference and budget.
 
'''Using a drill'''<br/>
coming soon
 
'''Using a motor'''<br/>
See [[Motorizing a mill]].
 
'''Milling speed'''<br/>
Anecdotally, milling speed on a home brew mill has more effect on a good crush (specifically the prevention of husk shredding) than the roller gap or grain conditioning.<ref name="lob993"/><ref name="lob271">[http://www.lowoxygenbrewing.com/forum/viewtopic.php?f=2&t=271 "Conditioned Grain Mill Gap."] Low Oxygen Brewing forum thread, 2017.</ref> A lower speed produces more intact husks/hulls.
 
The consensus on the Low Oxygen Brewing forum seems to be that running the rollers at about 50–150 RPM provides a good crush while minimizing damage to the husks.<ref name="LOB-1069"/><ref name="lob271"/> Other online sources generally suggest higher rates... around 150–300 RPM, but they also acknowledge that slower is generally better, whatever the lowest speed it can run without your drill or motor stalling.<ref name="monster"/><ref name="bison"/> It usually takes a little more torque to get the mill going than to keep it going, so you will have to give it some more power to start the mill, and then slow it down once you are milling. If your drive method is struggling with the torque needed to mill at low speed, a simple solution is to limit the amount of grain flowing into the rollers.
 
'''Roller speed differential'''<br/>
Modern professional mills have the rollers spinning at different speeds.<ref name="Kunze"/> This increases the effectiveness of the crush, decreasing particle size and increasing yield.<ref name="Mousia"/> No home brew mills are sophisticated enough to enable this without modification. However, the benefit from speed differential is likely not worth the effort needed to modify a mill to operate in such a way, and home brew rollers are very different and so a speed differential may produce undesirable results.


==Other Considerations==
== Milling considerations ==
There are many complexities to keep in mind.
Several things should be considered when deciding on mill gap and other parameters that will affect grist performance during [[mashing]].


'''Husk integrity'''<br/>
=== Husk integrity ===
There is absolutely no need to shred the grain to a powder. Barley cell walls contain beta-glucans which are directly related to viscosity and therefore the rate at which the wort can be extracted, whether recirculating or transferring to the kettle. Grinding the grain (and husk) to a flour will break down the cell walls and increase the viscosity of your wort, increasing the likelihood of the dreaded "stuck mash". We want the husks to be as intact as possible, not only for filtering, but also because finely shredded husks can cause astringent, bitter, or harsh off flavors.<ref>[https://www.winning-homebrew.com/homebrew-grain-mills.html "Homebrew Grain Mills and a Pictorial Guide to Milling Grain."] Winning-Homebrew.com, Accessed May 2020.</ref><ref name="brewer">Whitting, C. [https://www.beerandbrewer.com/milling-your-grain/ "Milling Your Grain."] Beer & Brewer, 2018.</ref><ref name="more">Brown, R. [https://www.morebeer.com/articles/DIY_Homebrew_Grain_Mill "Homemade Grain Milling Systems."] MoreBeer, Accessed May 2020.</ref><ref name="Narziss">Narziss, L., et al. ''Abriss der Bierbrauerei (Demolition of the brewery)'', 8th ed., WILEY ‐ VCH Verlag GmbH & Co. KGaA, 2017, pp. 126-130.</ref> Excessive milling promotes the extraction and solubilization of undesirable compounds into the wort and beer, such as silicates, lipids, husk-derived tannins (phenolic compounds), and large-molecular proteins, which can cause excess formation of [[trub]], deposits, color changes, [[haze]]s, and a shorter shelf life.<ref>Zepf, M. [https://beerandbrewing.com/dictionary/VWpGLEPUS6/ "Milling"] Craft Beer & Brewing, Accessed May 2020.</ref><ref>Siebert, K. [https://www.sciencedirect.com/science/article/pii/S0023643806000259 "Haze formation in beverages."] ''LWT'', vol. 39, 2006, pp. 987–994.</ref><ref name="Kunze"/> To put this in perspective, approximately 70–80% of the total polyphenol content of beer comes from the malt husk; and its transfer to the wort is largely influenced by milling parameters.<ref name="Moura">Pereira de Moura, F., and Rocha dos Santos Mathias, T. [https://www.mdpi.com/2306-5710/4/3/51/pdf "A Comparative Study of Dry and Wet Milling of Barley Malt and Its Influence on Granulometry and Wort Composition."] ''Beverages'', vol. 4, no. 51, 2018.</ref>
Pulverizing the entire grain into flour should generally be avoided.<ref name="Szwajgier">Szwajgier D. [https://onlinelibrary.wiley.com/doi/pdf/10.1002/j.2050-0416.2011.tb00505.x Dry and wet milling of malt. A preliminary study comparing fermentable sugar, total protein, total phenolics and the ferulic acid content in non-hopped worts.] ''J Inst Brew.'' 2011;117(4):569–577.</ref><ref name=Warpala>Warpala IWS, Pandiella SS. [https://www.sciencedirect.com/science/article/abs/pii/S0960308500701982 Grist fractionation and starch modification during the milling of malt.] ''Food and Bioproducts Processing.'' 2000;78(2):85–89.</ref><ref name=kall/> A high percentage of flour will increase the viscosity of the wort, increasing the likelihood of the dreaded "stuck mash" or slow recirculating and lautering. We want the husks to be as intact as possible, not only for filtering, but also because finely shredded husks can cause astringent, bitter, or harsh off flavors.<ref name=mostra/><ref name="Szwajgier"/><ref>[https://www.winning-homebrew.com/homebrew-grain-mills.html Homebrew grain mills and a pictorial guide to milling grain.] Winning-Homebrew.com website. Accessed May 2020.</ref><ref name=brewer>Whitting C. [https://www.beerandbrewer.com/milling-your-grain/ "Milling Your Grain."] Beer & Brewer. 2018. Accessed 2020.</ref><ref name=more>Brown R. [https://www.morebeer.com/articles/DIY_Homebrew_Grain_Mill Homemade grain milling systems.] MoreBeer. Accessed May 2020.</ref><ref name=adb>Narziss L, Back W, Gastl M, Zarnkow M. [[Library|''Abriss der Bierbrauerei.'']] 8th ed. Weinheim, Germany: Wiley-VCH Verlag GmbH & Co. KGaA; 2017:126–130.</ref><ref name=fix>Fix G. [[Library|''Principles of Brewing Science.'']] 2nd ed. Brewers Publications; 1999.</ref> Excessive milling promotes the extraction and solubilization of undesirable compounds into the wort and beer, such as [[silicates]], [[fatty acids|lipids]], husk-derived tannins ([[phenolic compounds]]), and large-molecular [[protein]]s, which can cause excess formation of [[trub]], deposits, color changes, [[haze]]s, and a shorter shelf life.<ref name=Kunze/><ref>Zepf M. [https://beerandbrewing.com/dictionary/VWpGLEPUS6/ Milling.] Craft Beer & Brewing. Accessed May 2020.</ref><ref>Siebert KJ. [https://www.sciencedirect.com/science/article/pii/S0023643806000259 Haze formation in beverages.] ''Lebenson Wiss Technol.'' 2006;39(9);987–994.</ref><ref name=Szwajgier/><ref name=Moura>Pereira de Moura F, Rocha dos Santos Mathias T. [https://www.mdpi.com/2306-5710/4/3/51/pdf A comparative study of dry and wet milling of barley malt and its influence on granulometry and wort composition.] ''Beverages.'' 2018;4(51).</ref><ref name=golston/><ref name=pre>Prechtl C. [https://www.mbaa.com/publications/tq/tqPastIssues/1967/Abstracts/tq67ab16.htm Some practical observations concerning grain bitterness in beers and its amelioration.] ''Tech Q Master Brew Assoc Am.'' 1967;4(1):98–103.</ref> Lastly, too much husk flour can potentially result in loss of [[extract]] because starch will be adsorbed to the husk and discarded with it.<ref name=esslinger>Krottenthaler M, Back W, Zarnkow M. Wort production. In: Esslinger HM, ed. [[Library|''Handbook of Brewing: Processes, Technology, Markets.'']] Weinheim, Germany: Wiley-VCH Verlag GmbH & Co. KGaA; 2009.</ref>


Husk integrity can be improved by conditioning the grain, milling slowly, using a reasonably large mill gap, and by using a 3-roller mill (or the Ss Brewtech mill that has unique rollers).
However, fine milling does not ''necessarily'' cause extraction of harsh flavors, and it can be acceptable depending on the [[lautering]] method.<ref name=bsp>Briggs DE, Boulton CA, Brookes PA, Stevens R. [[Library|''Brewing Science and Practice.'']] Woodhead Publishing Limited and CRC Press LLC; 2004.</ref><ref name=derouck>De Rouck G, Jaskula-Goiris B, De Causmaecker B, et al. [https://www.brewingscience.de/index.php?tpl=table_of_contents&year=2013&edition=0001%252F0002&article=82374 The impact of wort production on the flavour quality and stability of pale lager beer.] ''BrewingScience.'' 2013;66(1/2):1–11.</ref> [[brewing pH|Mash pH]] strongly influences the extraction of negative compounds, which can be particularly troublesome when [[Sparging|fly sparging]]. Therefore the issue of undesirable flavor extraction from pulverized husks may be less worrisome for home brewers who properly control mash and sparge pH, although husk pulverization may still lead to other issues such as haze and excessive trub depending on other factors.<ref>De Rouck G, Jaskula B, De Causmaecker B, et al. [https://www.tandfonline.com/doi/abs/10.1094/ASBCJ-2013-0113-01 The influence of very thick and fast mashing conditions on wort composition.] ''J Am Soc Brew Chem.'' 2013;71(1):1–14.</ref>


'''Preventing oxidation'''<br/>
Husk integrity can be improved by conditioning the grain, using an appropriately large mill gap, and using a 3-roller mill or a mill with fluted rollers.
[[Oxidation]] processes start immediately after milling and can have a negative impact on the subsequent beer quality.<ref name="Kunze"/> Therefore the time between milling and dough-in should be kept as short as possible. Microbiological problems may also become a concern if it is stored for too long after conditioning.


Modern commercial low oxygen breweries fill all areas containing milled grain with inert gas (CO<sub>2</sub> or N<sub>2</sub>) to prevent oxygen exposure.<ref name="Kunze"/> Brewers looking to [[low oxygen brewing|preserve fresh grain flavor]] may also attempt this by flowing inert gas into the bottom of the mash tun and milling directly into it, or by flowing inert gas through the grist only after milling.<ref>[http://www.lowoxygenbrewing.com/forum/viewtopic.php?f=2&t=1025 "CO2 purge of mash tun prior to underletting?"] Low Oxygen Brewing forum thread, 2018.</ref><ref name="lob1394">[http://www.lowoxygenbrewing.com/forum/viewtopic.php?f=18&t=1394 "milling into mash tun"] Low Oxygen Brewing forum thread, 2019.</ref> Purging a mostly covered mash tun at 1–2 psi for about 10 minutes had been shown to effectively remove the vast majority of oxygen in the vessel.<ref>[http://www.lowoxygenbrewing.com/forum/viewtopic.php?f=11&t=751 "Purging grist in the tun."] Low Oxygen Brewing forum thread, 2018.</ref> A regulator may start to freeze up and/or significantly chill the mash tun parts, causing dough-in temperature to be too low. A fix for that is to get a cheap hair dryer and set it up to blow on your regulator.<ref name="lob1394"/> Dry ice can also be used to purge: put the dry ice in a jar with water and connect it with tubing to the mash tun.
=== Milling speed ===
In general, a milling speed between 50–300 RPM is considered appropriate for small scale milling.<ref name="lob271"/><ref name="LOB-1069"/><ref name="monster"/> Be aware that it usually takes a little more torque to get the mill going. If your drive method is struggling, use the method to reduce torque described above.


'''Sieve testing'''<br/>
Some home brewers have found that milling at a lower speed reduces damage to husks.<ref name=lob993/><ref name=lob271>[http://www.themodernbrewhouse.com/forum/viewtopic.php?f=2&t=271 Conditioned grain mill gap.] The Modern Brewhouse website. 2017–2018. Accessed 2020.</ref><ref>[https://www.homebrewtalk.com/threads/so-what%E2%80%99s-the-right-harbor-freight-drill-for-a-mill-20-off-coupon-out-now.673941/ So what's the right Harbor Freight drill for a mill? 20% off coupon out now.] Homebrew Talk website. 2020. Accessed 2020.</ref><ref>[https://www.homebrewtalk.com/threads/best-place-to-get-a-grain-mill.700592/post-9272893 Best place to get a grain mill.] Homebrew Talk website. 2022. Accessed May 27, 2022.</ref> Other brewers have not noticed a significant effect of milling speed on the grist (appearance or granulometry),<ref>[http://www.themodernbrewhouse.com/forum/viewtopic.php?f=11&t=1929 Milling test results.] The Modern Brewhouse website. 2020. Accessed July 2020.</ref><ref name=bittner/> which is in agreement with professional literature.<ref name=Warpala/><ref name=Mousia/>
We have ability to objectively and scientifically measure the resulting crush (called granulometry) using standardized sieves and a protocol which sort the crushed grain into different size ranges. While interesting, this is generally not a worthwhile endeavor for home brewers. However it is an excellent way to compare how different parameters can affect the crush.


Here are some external resources for further reading:
=== Oxidation ===
*[http://brewlikeapro.net/maltmilling.html Brew Like a Pro] - Malt Milling
[[File:Mill-on-cooler.jpg|thumb|right|Mill with base on top of a cooler mash tun]]
*[https://beerandwinejournal.com/malt-sieves/ Beer and Wine Journal] - Malt Sieves
The grist begins to [[Oxidation|oxidize]] immediately upon milling (because the inside of the kernels are then exposed to air and moisture) and this can have a negative impact on the subsequent beer quality.<ref name=Kunze/><ref name=adb/><ref name=pasame>Pascoe HM, Ames JM, Chandra S. [https://www.tandfonline.com/doi/abs/10.1094/ASBCJ-61-0203 Critical stages of the brewing process for changes in antioxidant activity and levels of phenolic compounds in ale.] ''J Am Soc Brew Chem.'' 2003;61(4):203–209.</ref><ref name=cheyni>Cheynier V. [https://www.sciencedirect.com/science/article/pii/S0002916523275115 Polyphenols in foods are more complex than often thought.] ''Am J Clin Nutr.'' 2005;81(1):223S–229S.</ref> Therefore the time between milling and dough-in should be kept as short as possible.<ref name=golston>Golston AM. [https://www.mbaa.com/publications/tq/tqPastIssues/2021/Pages/TQ-58-1-0322-01.aspx The impact of barley lipids on the brewing process and final beer quality: A mini-review.] ''Tech Q Master Brew Assoc Am.'' 2021;58(1):43–51.</ref>
*[https://byo.com/article/the-perfect-crush/ Brew Your Own] - The Perfect Crush
*[http://www.lowoxygenbrewing.com/forum/viewtopic.php?f=11&t=1532 LOB forum] - Ss brewtech mill review With Sieve Testing
* Book: Technology Brewing and Malting by Kunze


Examples:
Modern commercial low oxygen breweries fill all areas containing milled grain with inert gas (CO<sub>2</sub> or N<sub>2</sub>) to prevent oxygen exposure.<ref name=Kunze/><ref name=bsp/><ref name=adb/><ref name=derouck/><ref name=golston/> Brewers looking to [[low oxygen brewing|preserve fresh grain flavor]] may do this simply by flowing inert gas into the bottom of the mash tun and milling directly into it, or by flushing the grist with inert gas after milling.<ref name=stephenson>Stephenson WH, Biawa JP, Miracle RE, Bamforth CW. [https://onlinelibrary.wiley.com/doi/pdf/10.1002/j.2050-0416.2003.tb00168.x Laboratory-scale studies of the impact of oxygen on mashing.] ''J Inst Brew.'' 2003;109(3):273–283.</ref><ref name=mullerr>Muller R. [https://www.tandfonline.com/doi/abs/10.1094/ASBCJ-53-0053 Use of 5,5’-dithiobis (2-nitrobenzoic acid) as a measure of oxidation during mashing.] ''J Am Soc Brew Chem.'' 1995;53(2):53–58.</ref><ref>[http://www.themodernbrewhouse.com/forum/viewtopic.php?f=2&t=1025 CO2 purge of mash tun prior to underletting?] The Modern Brewhouse website. 2018. Accessed 2020.</ref><ref name="lob1394">[http://www.themodernbrewhouse.com/forum/viewtopic.php?f=18&t=1394 Milling into mash tun.] The Modern Brewhouse website. 2019. Accessed 2020.</ref> Purging a mostly covered mash tun at 1–2 psi for about 10 minutes has been shown to effectively remove the vast majority of oxygen in the vessel.<ref>[http://www.themodernbrewhouse.com/forum/viewtopic.php?f=11&t=751 Purging grist in the tun.] The Modern Brewhouse website. 2018. Accessed 2020.</ref> A regulator may start to freeze up and/or significantly chill the mash tun parts, causing dough-in temperature to be too low. A fix for that is to get a cheap heat lamp or hair dryer and point it at your regulator.<ref name="lob1394"/> Dry ice can also be used to purge: put the dry ice in a jar with water and connect it with tubing to the mash tun. Note that flushing with inert gas during the actual milling process appears not to be critical, as oxidation does not occur immediately (at least with regard to [[lipids]] or [[protein]]s).<ref name=wackerbauer>Wackerbauer K, Meyna S, Marre S. [http://themodernbrewhouse.com/wp-content/uploads/2017/04/174-178.pdf Hydroxy fatty acids as indicators for ageing and the influence of oxygen in the brewhouse on the flavour stability of beer.] ''Monatsschrift Brauwiss.'' 2003;56(9/10):174–178.</ref><ref name=mullerr/>
<gallery widths=350px heights=300px mode="nolines">
File:Coarse grind.jpg
File:Normal grind.jpg
File:Fine grind.jpg
</gallery>


'''Cleaning a mill'''<br/>
=== Grain moisture ===
First time cleaning: After adjusting the gap, mill about a pound of grain and then throw that away. This removes the machine oils from the rollers.<br/>
The moisture content of the malt influences the fineness of the grist. Moisture makes the grain more elastic and the crush becomes more coarse. Coarse particles adhering to the husks are more difficult to degrade during the mashing process, leading to a lower yield. This mainly applies to malts which, if improperly stored, have a water content of 8–12%. Unlike with grain conditioning, this moisture is distributed through the entire grain. On the other hand, a malt with very little moisture has a tendency to be crushed too fine, destroying the husks and increasing the flour content. This may occur when very young dark malts are used, which is probably an unlikely situation for home brewers. Conditioning may help avoid problems in both of these cases, although minimizing moisture during [[grain]] storage is still a high priority.<ref name=adb/>
Cleaning after use: A paintbrush and/or compressed air will remove dust and any grain clinging to the rollers.


Removing rust from rollers... Stainless steel brush? BKF? Passivate stainless steel rollers?
=== Specialty grains ===
Lighter color kilned or dry roasted specialty malts will crush like base malts, while caramel/crystal and extremely dark roasted products are more brittle and tend to shatter rather than crush. Malts that shatter tend to create more flour which can contribute to difficulties during [[lautering]]. The fine particles can fill in the spaces in the otherwise permeable bed causing a slowed or stuck lauter. These brittle specialty malts can typically be milled with a wider mill gap resulting in a larger particle size that will still allow for complete flavor and aroma extraction which is the primary function of these malts. Finding the balance of desired particle size starts with adjusting the mill gaps.<ref>Geurts J. [http://blog.brewingwithbriess.com/9-5-grind/ 9-5 grind.] Briess blog. 2018. Accessed 2020.</ref>


'''Milling location'''<br/>
'''Wheat, rye, and oats'''<br/>
To avoid excess dust contaminating your gear/wort, mill away from from your cold side gear and away from where you'll be chilling and fermenting your wort, particularly if you do not condition the grain.
Generally speaking, these grains have smaller kernels (especially rye)<ref name=smart1>Howe S. Raw materials. In: Smart C, ed. [[Library|''The Craft Brewing Handbook.'']] Woodhead Publishing; 2019.</ref> and are harder than barely. Therefore the mill gap may need to be decreased when milling these grains, and more torque may be required while milling. Mill small samples to check for whole kernels, just as we suggested above for setting the gap for barley. Take note of the ideal gap for each grain.


'''Things that don't need to be milled'''<br/>
'''Things that don't need to be milled'''<br/>
* "Flaked" or "rolled" grain [[adjuncts]] do not need to be milled, although they can be run through the mill with the rest of the grain if it is convenient.<ref>[http://www.brewingwithbriess.com/Assets/PDFs/Briess_PISB_BrewersBarleyFlakes.pdf "Brewers Barley Flakes."] Product Information Sheet, Briess, 2019.</ref>
* "Flaked" or "rolled" grain [[adjuncts]] do not need to be milled, although they can be run through the mill with the rest of the grain if it is convenient.<ref>[http://www.brewingwithbriess.com/Assets/PDFs/Briess_PISB_BrewersBarleyFlakes.pdf Brewers barley flakes.] Briess Product Information Sheet. 2019. Accessed 2020.</ref>
* Rice hulls should not be put through the mill because their whole purpose is to remain intact in order to aid filtering.
* Rice hulls should not be put through the mill because their whole purpose is to remain intact in order to aid filtering.
* Most home brew mills are not suitable for milling corn.
* Most home brew mills are not suitable for milling corn.
* Fingers, clothing, rocks, or bits of metal should not be milled. Please be careful, especially when using power tools.
* Fingers, clothing, rocks, or bits of metal should not be milled. Please be careful, especially when using power tools.


==Conditioning the Grain==
=== Dust ===
Dry husks fragment easily, which may cause issues (see above). However husks become more elastic when they are moist, making them easier to protect.<ref name="Kunze"/><ref>Rabe, B. [http://www.lowoxygenbrewing.com/uncategorized/grain-conditioning/ Grain Conditioning] Low Oxygen Brewing blog, 2016.</ref><ref name="LOB-1069"/><ref name="lob993"/><ref>https://www.scielo.br/scielo.php?pid=S0101-20611999000200003&script=sci_arttext</ref> Wetting the grain is called "conditioning". The goal is to increase the moisture content of the husk enough to minimize shredding as the grain passes through the mill. Generally the amount of water should be about 1–2% of the weight of grain.<ref name="Narziss"/> It's important not to add too much water because our mills do not like wet grain. The recommended amount of water is low enough that it will not cause rollers to rust. Wheat malt also benefits from conditioning.<ref name="Kai">Troester, K. [http://braukaiser.com/wiki/index.php?title=Malt_Conditioning Malt Conditioning.] German brewing and more wiki, 2009.</ref>
To avoid excessive dust contaminating your gear and wort, it's considered prudent to mill away from your cold-side gear and away from where you'll be chilling and fermenting your wort, particularly if you do not condition the grain. Conditioning can help lower the amount of dust generated while milling. However, dust can still be created when measuring the grain. Wearing a mask can be beneficial for your health since breathing in grain dust is not so great.<ref name=mostra/> Thanks to COVID-19 you do have a mask, right?
 
==Conditioning the grain==
[[File:Unmilled-grain.jpg|thumb|Simple grain conditioning setup]]
Dry husks fragment easily, which may cause issues (see above). Husks become more elastic when they are moist, making them easier to protect.<ref name=Kunze/><ref>Rabe B. [http://www.themodernbrewhouse.com/uncategorized/grain-conditioning/ Grain Conditioning.] The Modern Brewhouse website. 2016. Accessed 2020.</ref><ref name=LOB-1069/><ref name=lob993/><ref>Venturini Filho WG, Nojimoto T. [https://www.scielo.br/scielo.php?pid=S0101-20611999000200003&script=sci_arttext Utilization of the wet milling malt steep water as raw material on brewing.] ''Ciênc Tecnol Aliment.'' 1999;19(2):174-178.</ref><ref name=Crescenzi/><ref name=bsp/><ref name=hob11/> Increasing the moisture content of the grain husk right before milling is called "conditioning". The goal is to increase it just enough to minimize shredding as the grain passes through the mill. Generally the amount of water added should be about 1–2% of the weight of grain.<ref name=adb/><ref name=Kunze/><ref name=Szwajgier/><ref name=esslinger/> It's important not to add too much water because our mills cannot process wet grain; it will stick to the rollers. The recommended amount of moisture is low enough that the grain should not be sticky and it will not cause rollers to rust. Wheat malt also benefits from conditioning even though it is huskless.<ref name=Kai>Troester K. [http://braukaiser.com/wiki/index.php?title=Malt_Conditioning Malt Conditioning.] German brewing and more wiki. Updated 2009. Accessed 2020.</ref>


Obviously conditioning is not a necessary step, but it does have advantages when combined with a proper roller gap and milling speed. The roller gap may need to be (and probably should be) tightened when conditioning, to make sure all the grains get crushed and to reap the benefits of more finely crushed starch.<ref name="lob1167">[http://www.lowoxygenbrewing.com/forum/viewtopic.php?f=2&t=1167 "Seriously bad mash efficiency suddenly!"] Low Oxygen Brewing forum thread, 2019.</ref> Basically all modern commercial breweries that use lauter tuns (as opposed to mash filters) either condition their malt or mill it wet.<ref name="Kai"/>
Conditioning is not a necessary step, but it does have advantages when combined with a proper roller gap.<ref name=Szwajgier/> The roller gap may need to be (and probably should be) tightened when conditioning, to make sure all the grains get crushed and to reap the benefits of more finely crushed starch.<ref name=lob1167>[http://www.themodernbrewhouse.com/forum/viewtopic.php?f=2&t=1167 Seriously bad mash efficiency suddenly!] The Modern Brewhouse website. 2019. Accessed 2020.</ref><ref name=Crescenzi/><ref name=bsp/> Basically all modern commercial German breweries that use lauter tuns (as opposed to mash filters) either condition their malt or mill it wet.<ref name=Kai/>


Advantages:
Advantages:
* Dust is reduced during milling.<ref name="lob993"/>
* Dust is reduced during milling.<ref name=lob993/><ref name=mashing/>
* The risk of [[dough balls]] is decreased.<ref name="lob993">[http://www.lowoxygenbrewing.com/forum/viewtopic.php?f=2&t=993 "Revisiting grain conditioning."] Low Oxygen Brewing forum thread, 2018.</ref>
* The risk of [[dough balls]] is decreased.<ref name=lob993>[http://www.themodernbrewhouse.com/forum/viewtopic.php?f=2&t=993 Revisiting grain conditioning.] The Modern Brewhouse website. 2018–2019. Accessed 2020.</ref>
* The rollers may grip the grain better and feed faster.<ref name="lob993"/>
* The rollers may grip the grain better and feed faster.<ref name="lob993"/>
* Husk volume increases (looser grain bed).<ref name="Kunze"/>
* Improved husk integrity provides a looser grain bed and easier lautering.<ref name="Kunze"/><ref name="Szwajgier"/><ref name=bsp/><ref name=mashing/>
* More intact husks means that the grain can be ground more thoroughly (tighter gap) without affecting lautering.<ref name="Kunze"/>
* More intact husks means that the grain can be ground more thoroughly (tighter gap) without affecting lautering.<ref name="Kunze"/><ref name="Szwajgier"/><ref name=bsp/><ref name=adb/>
* A tighter gap means that the starch is crushed more thoroughly.
* A tighter gap means that the starch is crushed more thoroughly.
* More thoroughly crushed starch means that [[efficiency]] and [[attenuation]] are increased and [[conversion]] is faster.<ref name="Kunze"/><ref name="Narziss"/>
* More thoroughly crushed starch means that [[efficiency]] and [[attenuation]] are increased and [[conversion]] is faster.<ref name="Kunze"/><ref name=adb/><ref name=bsp/>
* Reduced husk damage can have quality benefits on the resulting beer. (See above)
* Reduced husk damage can have quality benefits on the resulting beer. (See above)
* Manually stirring and looking at your grain allows you to find any rocks, metal pieces, or other foreign objects that may be mixed with the grain and could otherwise damage your mill.
* Manually stirring and looking at your grain allows you to find any rocks, metal pieces, or other foreign objects that may be mixed with the grain and could otherwise damage your mill.
Line 172: Line 248:
* Additional time and labor is required.
* Additional time and labor is required.
* Milling may require additional torque.
* Milling may require additional torque.
* A roller gap adjustment may be needed.
* A roller gap adjustment is probably needed to optimize crush (and prevent uncrushed kernels).<ref name=bsp/>
* Protein extraction may be higher.<ref name="Szwajgier"/>




Method 1 (Editor's Choice)<ref name="lob993"/>
'''Conditioning Method 1''' (Editor's Choice)<ref name="lob993"/>
# Put the grain into a wide plastic tub.
# Put the grain into a wide plastic tub.
# Add water to a small spray bottle.
# Add water to a small spray bottle.
# Spray the grain evenly while stirring (e.g. with your hand or a mash paddle) until the grain becomes pliable.
# Spray the grain evenly while stirring (e.g. with your hand or a mash paddle) until the grain becomes pliable.
# The grain may be milled about 5–10 minutes after wetting.
# The grain may be milled about 10 minutes after wetting.
View this method in action:
View this method in action:
{{#ev:youtube|https://www.youtube.com/watch?v=rSAG31iTjK0|||||start=375}}
{{#ev:youtube|https://www.youtube.com/watch?v=rSAG31iTjK0|||||start=375}}


Method 2 (no stirring)<ref name="LOB-1069"/>
 
'''Conditioning Method 2''' (no stirring)<ref name="LOB-1069"/>
# Weigh out the grain in buckets.
# Weigh out the grain in buckets.
# Add water to a small spray bottle.
# Add water to a small spray bottle.
Line 189: Line 267:
# Spray it with water from a spray bottle.
# Spray it with water from a spray bottle.
# Repeat steps 3 & 4 until done.
# Repeat steps 3 & 4 until done.
# The grain may be milled about 5–10 minutes after wetting.
# The grain may be milled about 10 minutes after wetting.


Method 3 (sink sprayer)<ref name="LOB-1069"/>
 
'''Conditioning Method 3''' (sink sprayer)<ref name="LOB-1069"/>
# Put the grain into a wide plastic tub.
# Put the grain into a wide plastic tub.
# Attach a flexible misting nozzle to a sink hose.
# Attach a flexible misting nozzle to a sink hose.
# Spray the grain evenly while stirring (e.g. with your hand or a mash paddle) until the grain becomes pliable.
# Spray the grain evenly while stirring (e.g. with your hand or a mash paddle) until the grain becomes pliable.
# The grain may be milled about 5–10 minutes after wetting.
# The grain may be milled about 10 minutes after wetting.




If you are using a disc mill (like a Corona/Victoria style mill) instead of a roller mill, different amounts of moisture can possibly have variable and unpredictable effects on the resulting crush.<ref name="Moura"/> Therefore we cannot recommend conditioning when using such a mill, but you may still experiment if you wish.
If you are using a disc mill (like a Corona/Victoria style mill) instead of a roller mill, different amounts of moisture can possibly have variable and unpredictable effects on the resulting crush.<ref name="Moura"/> Therefore we cannot recommend conditioning when using such a mill, but you may still experiment if you wish.


For images comparing conditioned vs unconditioned grist, see here: [http://www.lowoxygenbrewing.com/uncategorized/grain-conditioning/ Grain Conditioning at LOB] and [http://braukaiser.com/wiki/index.php?title=Malt_Conditioning Malt Conditioning at German Brewing].
For images comparing conditioned vs unconditioned grist, see here: [http://www.themodernbrewhouse.com/uncategorized/grain-conditioning/ Grain Conditioning at LOB.] and [http://braukaiser.com/wiki/index.php?title=Malt_Conditioning Malt Conditioning at German Brewing].


==See Also==
==Cleaning and maintenance==
*[http://brewlikeapro.net/maltmilling.html Mills and Milling] by Dave Miller (''Brew Like A Pro'')
[[File:Mill-body-end-plates.jpg|thumb|right|Left: dirty end plate. Right: clean end plate]]
*If you're really into DIY: [https://www.morebeer.com/articles/DIY_Homebrew_Grain_Mill?a_aid=ModernBrewhouse Suggestions to help build a mill from scratch]
'''First time cleaning:''' After adjusting the gap, mill about a pound of grain and then throw that away. This removes the machine oils from the rollers.
 
'''Cleaning after use:''' A paintbrush and compressed air will remove dust and any grain and dust clinging to the rollers. A stainless steel brush can help remove stubborn particles.
 
'''Removing and preventing rust:''' Most mills have hardened steel rollers, so it is possible for them to rust. Running about a pound of grain or rice through the mill may be all that's needed to remove rust from the rollers. If that doesn't work, brush the affected area with a stainless steel brush until the rust is gone. Dust attracts moisture, so keeping the mill clean as described above will help prevent the rollers from rusting,<ref name=bsp/> as will storing the mill in a dry location. If you condition your grain, consider reserving a half pound of unconditioned grain to mill at the end to remove any moisture.
 
'''Maintenance:''' The mills we recommend are fairly maintenance-free, particularly if you have one with sealed ball bearings and if you clean the rollers after use. However, mills (especially those with bronze bushings in particular) may benefit from periodic cleaning: disassemble, wipe clean, and lubricate. Visually check the gap setting before milling to make sure the adjustable gap is not slipping and that the rollers are in proper alignment. Rollers out of alignment may bind. Rollers with stubborn grain stuck between the knurling can be cleaned with a short (e.g. 30 minute) hot alkaline bath (see [[cleaning]]), although some rust will likely need to be removed afterwards.
 
{| class=wikitable
|+Suggested cleaning and maintenance products
|-
|Stainless steel brush||{{Amazon|B000CFLET4}}
|-
|Food-grade machine oil for lubrication||{{Amazon|B0013J62O0}}
|}
 
==Sieve testing==
[[File:Sieves-with-grain.png|thumb|Sieves with grain sample. Photo by Dr. Adam Bittner.]]
Sieves can be used to scientifically measure the particle sizes of the grist. This is called granulometry, or sieve testing. Unfortunately, the sieves are a bit expensive and the testing process is somewhat labor-intensive. Furthermore, the results are borderline useless since the crush produced by home brew mills differs greatly from that of a commercial mill, even with similar granulometry results.<ref name=bittner>Bittner A. [[User_blog:Adam/Think_like_a_scientist:_Sieve_testing|Think like a scientist: Sieve testing.]] Brewing Forward website. 2021. Accessed February 2021.</ref> Therefore, we do not recommend home brewers invest in the materials or effort required for sieve testing.
 
Our recommendation notwithstanding, sieve testing can be used in combination with visual inspection to compare how different milling parameters can affect the crush, and it can be helpful to maintain a tight degree of consistency through periodic testing. Large breweries use a machine to conduct the test, but it can also be done by hand using a standardized protocol, which has been shown to produce satisfactory results.<ref>[https://doi.org/10.1094/ASBCJ-61-0246 Malt grist by manual sieve test.] ''J Am Soc Brew Chem.'' 2003;61(4):246–249.</ref><ref>Schwarz P, Barr J, Joyce M, Power J, Horsley R. [https://www.tandfonline.com/doi/abs/10.1094/ASBCJ-60-0010?src=recsys Analysis of malt grist by manual sieve test.] ''J Am Soc Brew Chem.'' 2002;60(1):10–13.</ref> See [[Sieve testing]] for more information.


==See also==
*[[Grain]]
*[[Malt]]
*[[Mashing]]


Potential Sources
*[http://serv-bib.fcfar.unesp.br/seer/index.php/alimentos/article/viewPDFInterstitial/660/556 O processo de fabricação da cerveja e seus efeitos na presença de polifenóis (The brewing process and its effects in the presence of polyphenols)]
*[https://ifst.onlinelibrary.wiley.com/doi/abs/10.1111/jfpp.12626 Wet-Milling of Cereals]
*[https://onlinelibrary.wiley.com/doi/pdf/10.1002/j.2050-0416.2011.tb00505.x Dry and wet milling of malt. A preliminary study comparing fermentable sugar, total protein, total phenolics and the ferulic acid content in non‐hopped worts]
*https://youtu.be/DpI4jh8Uj44
*https://youtu.be/QdScbJFJvRI


*[https://www.cerealsgrains.org/publications/cc/backissues/1982/Documents/Chem59_210.pdf "Starch degradation in endosperms of barley and wheat kernels during initial stages of germination"]
External links:
*[https://onlinelibrary.wiley.com/doi/pdf/10.1002/j.2050-0416.1980.tb03961.x "Amylolysis of large starch granules from barleys in relation to their gelatinisation temperatures"]
* [https://www.youtube.com/watch?v=_HUHdUiy6Js Video from Integrity Homebrewing] comparing the effects of different mill gaps, mill speeds, and grain conditioning (20 minute video)
*[https://www.sciencedirect.com/science/article/abs/pii/S0733521083710131 "Accessibility of Barley Starch Granules to α-Amylase during Different Phases of Gelatinization"]
*[http://brewlikeapro.net/maltmilling.html Mills and Milling] by Dave Miller, author of ''Brew Like A Pro''
*[https://www.researchgate.net/profile/Shd_Hulleman2/publication/40152328_Alpha-amylolysis_of_large_barley_starch_granules/links/0deec53c78f5d48d4b000000/Alpha-amylolysis-of-large-barley-starch-granules.pdf "α-Amylolysis of Large Barley Starch Granules"]
*If you're really into DIY: [https://www.morebeer.com/articles/DIY_Homebrew_Grain_Mill?a_aid=ModernBrewhouse Suggestions to help build a mill from scratch]
*[https://onlinelibrary.wiley.com/doi/pdf/10.1002/j.2050-0416.1973.tb03557.x "In vivo and in vitro degradation on barley and malt starch granules"]
*[https://onlinelibrary.wiley.com/doi/pdf/10.1002/j.2050-0416.1998.tb01007.x "Heat‐induced structural changes of small and large barley starch granules"]
*[https://www.sciencedirect.com/science/article/abs/pii/S0733521084710289 "Properties of Damaged Starch Granules. II. Crystallinity, Molecular Order and Gelatinisation of Ball-milled Starches"]
*[https://onlinelibrary.wiley.com/doi/abs/10.1002/star.19830350406 "Gelatinisation properties of different size classes of wheat starch granules measured with differential scanning calorimetry."]
*[https://onlinelibrary.wiley.com/doi/abs/10.1002/jsfa.2740360811 "The amylose and lipid contents, dimensions, and gelatinisation characteristics of some wheat starches and their A‐ and B‐granule fractions"]
*[https://agris.fao.org/agris-search/search.do?recordID=US9633340 "Physicochemical properties of small- and large-granule starches of waxy, regular, and high-amylose barleys"]
*[http://www.academia.edu/download/35542692/starch_granule.pdf "Starch granules: structure and biosynthesis"]
*[https://onlinelibrary.wiley.com/doi/abs/10.1094/CCHEM.2000.77.1.27 "Some Physicochemical Properties of Small‐, Medium‐, and Large‐Granule Starches in Fractions of Waxy Barley Grain"]
*[https://www.sciencedirect.com/science/article/abs/pii/S0008621500002925 "Physicochemical properties and structure of large, medium and small granule starches in fractions of normal barley endosperm"]
*[https://onlinelibrary.wiley.com/doi/abs/10.1094/CCHEM.2002.79.2.286 "Effect of Small and Large Wheat Starch Granules on Thermomechanical Behavior of Starch"]
*[https://onlinelibrary.wiley.com/doi/abs/10.1002/star.19720241004 "A Reassessment of the Chemical Structure of Barley and Wheat Starch Granules"]
*[https://www.sciencedirect.com/science/article/abs/pii/S0144861798001052 "Structures of large, medium and small starch granules of barley grain"]
*[https://onlinelibrary.wiley.com/doi/abs/10.1094/CCHEM.2001.78.2.111 "Fine structures of amylose and amylopectin from large, medium, and small waxy barley starch granules"]
*[https://www.academia.edu/download/48192426/j.1365-2621.1980.tb07586.x20160820-15772-zmcj86.pdf "Starch gelatinization phenomena studied by differential scanning calorimetry"]
*[https://www.cerealsgrains.org/publications/cc/backissues/1983/documents/chem60_381.pdf "Differential Scanning Calorimetry of Heat-Moisture"]
*[https://www.sciencedirect.com/science/article/abs/pii/0032386176902500 "Theory of gelatinization in a starch-water-solute system"]
*[https://onlinelibrary.wiley.com/doi/abs/10.1002/star.19710230104 "Thermal Properties of the Starch/Water System Part I. Measurement of Heat of Gelatinisation by Differential Scanning Calorimetry"]
*[https://www.sciencedirect.com/science/article/abs/pii/S0733521083800216 "Differential scanning calorimetry studies on wheat starch—gluten mixtures: I. Effect of gluten on the gelatinization of wheat starch"]
*[https://onlinelibrary.wiley.com/doi/abs/10.1002/star.19810330202 "Large and Small Starch Granules in Wheat – Are They Really Different?"]
*[https://www.sciencedirect.com/science/article/abs/pii/S0960308500701982 "Shorter Communication: Grist Fractionation and Starch Modification During the Milling of Malt"]
*[https://www.tandfonline.com/doi/abs/10.1094/ASBCJ-53-0104 "Barley Malt Limit Dextrinase: Its Extraction, Heat Stability, and Activity During Malting and Mashing"]
*[https://onlinelibrary.wiley.com/doi/pdf/10.1002/j.2050-0416.1987.tb04498.x "Factors governing the milling of malt"]
*[https://www.sciencedirect.com/science/article/abs/pii/S0032591000003491 "On predicting roller milling performance: Part II. The breakage function"]
*[https://www.sciencedirect.com/science/article/abs/pii/0032591081870507 "Breakage parameters of some materials in smooth roll crushers"]
*[https://onlinelibrary.wiley.com/doi/abs/10.1094/CCHEM.1998.75.6.836 "Effects of Break‐Roll Speed Differential on Product Yield and Semolina Granulation in a Durum Pilot Mill System"]
...down the rabbit hole


==References==
==References==

Latest revision as of 20:43, 15 May 2024

Milled grain. Photo by Bryan Rabe.

Grain consists mainly of starch granules (endosperm) inside a husk. Before the mash, grain must be mechanically crushed using a mill. The crushing process breaks open the husks, exposing the starch, and also cracks the starch into smaller bits, increasing the surface area exposed to water and enzymes during mashing.[1] The crushed grain is referred to as grist. In general, the crush quality affects the mashing process, including saccharification time, lautering, efficiency, fermentation, as well as the color, taste, and overall character of the beer.[2][3]

Milling Process Overview:

  1. Weigh the grain on a scale per the recipe specifications.
  2. Condition the grain (optional)
  3. Crush the grain by adding it to the hopper and spinning the drive roller. The grist must be collected in a bucket or milled directly into the mash vessel.
  4. Verify the crush by visual inspection. It's generally a good idea to inspect the first handful of grain before continuing with the rest.

Grain mills[edit]

Why own a mill?

  • Freshness - Milling immediately before brewing results in the freshest malt possible (helping to avoid oxidation).
  • Control - Adjusting the gap allows you to tailor the crush to your own system and maximize efficiency.
  • Consistency - The crush size may be inconsistent with pre-milled grain.
  • Grain conditioning - Milling on site gives you the option to condition your grain (see below).
  • Cost savings - A personal grain mill eventually pays for itself because A) you avoid a milling fee and B) you can buy grain in bulk.

Features[edit]

Knurled rollers on a 3-roller mill (bottom view)
  • 3-roller vs 2-roller - In a 3-roller mill, the grain is pre-crushed in the gap between the top two rollers, and then the grain flows into the gap between the drive roller and bottom roller, crushing it further. The top gap is fixed at around 0.060–0.070" which easily pulls in both wheat and barley, providing superior feed, and softening the starch without tearing up the husk.[4] The lowered husk damage aids in lautering among other things (see below). The double crush also more fully separates the husk from the starch. The downsides to 3-roller mills are that more power (torque) is typically required to drive them and they are generally more expensive. 2-roller mills are more budget friendly.
  • Bearings vs bushings - Sealed ball bearings generally require no maintenance and can have a significantly longer lifespan than bushings, particularly if you drive the mill with a pulley.[5][6][7][8] On the other hand, bushings have more friction and may wear over time, such that they will need to be replaced at some point.[9][10] Therefore we recommend a mill with sealed ball bearings. However, bushings are still an acceptable option when using a direct drive system such as a drill. Bushings may benefit from periodic cleaning and lubrication with a drop of food-grade mineral oil; check with the manufacturer.[11][12]
  • Roller material - For most brewers, hardened steel is the best option for roller material due to its durability.[13] However, stainless steel has better protection against corrosion (although it is also more expensive). If you live in a damp or coastal region, stainless might be a good option.[14]
  • Roller diameter - Larger diameter helps the grain feed through the rollers.[2][15]
  • Knurled vs fluted rollers - Roller morphology has an important effect on the crush by reducing damage to the husk. Modern commercial mills always have fluted rollers.[3][2][16] On the other hand, most home brew mills have rollers with a diamond knurling pattern, which is necessary to improve the grain feed through small diameter rollers. A few home brew mills with relatively larger rollers (e.g. MattMill and Ss Brewtech) have a fluted morphology. However, the fluting pattern on these is completely different than commercial mills,[2] so it is unclear whether the fluting provides any benefit over knurling for home milling.
  • Drive shaft - A 1/2" integrated drive shaft is the most durable. If you have a drill that you plan to use for milling, verify that it can fit on the drive shaft for the mill you want to purchase. (See Driving the mill below)
  • Hopper size - Hopper size is a matter of convenience and budget. It is most convenient to add the grain to the hopper all at once, however it doesn't hurt anything if you need to pause partway through milling in order to fill the hopper with more grain. Portability, weight, and storage space should be also be taken into account. Some mills have optional hopper extensions to purchase, or you can make a hopper extension yourself.
  • Throughput rate - Differences in roller length and how fast the rollers feed grain is generally negligible for home brewers and not something that needs to be considered. Throughput depends largely on drive speed (RPM) and not the particular mill characteristics.
  • Roller speed differential - Modern large-scale commercial mills have the rollers spinning at different speeds.[2] This increases the effectiveness of the crush by shearing off the husk from the endosperm, which serves to increase yield while reducing husk damage.[3] The only home brew mill with speed differential is from Ss Brewtech.

Best mills available[edit]

2-Roller Mills
Mill Rollers Bearing type Accessories Where to purchase
star
Cereal Killer,
Kegco 2,
Hullwrecker,
Malt Muncher 2
(All the same) 		Knurled 1.25" x 5" hardened steel Sealed ball bearings Includes 7lb hopper and hand crank
Monster Mill 2 Knurled 1.5" x 6" hardened steel or stainless steel optional Bronze bushings 11lb hopper, hopper extension, hand crank, and base are all optional.
MattMill Kompakt Fluted 2.75" x 2" hardened steel Roller bearings[17] Hand crank and base are optional and hopper is generally DIY.
3-Roller Mills
Mill Rollers Bearing type Accessories Where to purchase
star
Kegco 3,
Malt Muncher 3
(same) 		Knurled 1.5" x 6" hardened steel Sealed ball bearings Includes 12lb hopper and hand crank. Base is optional.
Monster Mill 3 Knurled 1.5" x 6" hardened steel or stainless steel optional Bronze bushings 11lb hopper, hopper extension, base, and hand crank are all optional.
Premium Motorized Mills
Mill Rollers Bearing type Accessories Where to purchase
Ss Brewtech Fluted 4" diameter stainless steel, with speed differential Sealed ball bearings Includes motor and 25lb hopper. Base/cart is optional.
MoreBeer UltiMill Knurled 2" diameter hardened steel Unknown Includes 60lb hopper with lid, motor, and stand.

star = Editor's Pick

Crankandstein has a few barebones mills that are suited to the DIY-inclined brewer. You can get a basic mill and mount it in any mill housing design of your choice. They offer a 2-roller mill, 3-roller mill, and a 2-roller mill that can also crush corn. All of these have knurled hardened steel rollers and bronze bushings.

Mills to avoid[edit]

  • The Barley Crusher - It has soft rollers and soft/cheap bronze bushings, which lead to relatively frequent problems and a short product lifespan.[18] Their customer service is also very poor.[19]
  • Suspicious budget mills such as the motorized and 3-roller mills at Vevor - These cheap mills have a number of bad reviews and generally don't have a strong track record, so we don't recommend these products at this time.[20]
  • Non-roller mills such as food processors, rolling pins, or Corona/Victoria style disc mills (example)[21] - These tools are not designed to create a proper crush, they're not easily adjustable, they tend to create a mess and/or require significant modification just to be useable.[22] Corona-style mills are generally low-quality products (e.g. they may add metal shavings to the grist). Buy pre-milled grain until you're ready to invest in a roller mill.

Mounting the mill[edit]

It is important to set up the mill on a base to keep the frames aligned properly. If the frames aren't straight, the rollers may bind.[23] As you are securing it to the base, make sure all the rollers spin freely. Most mills either come with a base or have one available. These bases are typically designed to let the mill sit on top of a plastic bucket, and this setup is fine in most cases. However if you are adding a dedicated motor, it will be necessary to attach the mill to a larger base or table.

Monster Mill accessories like this base will also work for the Kegco 3-roller mill.

Driving the mill[edit]

Three options exist for powering the mill. Any of these options can produce a good crush, so the choice of power just depends on your personal preference and budget. Warning: We do not recommend driving the mill with a hamster.

  1. Hand crank
  2. Electric drill
  3. Electric non-drill motor

Hand crank[edit]

A hand crank is available for many models, and attaches to the drive shaft with a screw. It is operated by turning the crank handle. This may get tiring for milling large amounts of grain.

Electric drill[edit]

Driving the mill with a cordless drill. Photo by Rob Stein.

For most home brewers a drill is the preferred method to drive a mill. It is easier to set up and more economical than using a non-drill motor, and significantly less laborious than hand cranking. Low RPM drills provide the best torque. We don't recommend using an external speed limiter (example) on a high RPM drill because they significantly reduce the torque.[24][25] Affixing a zip tie, 2" tri-clamp, or U-bolt to the trigger of a variable speed drill can help control and maintain a constant speed. A corded drill is generally more powerful than a cordless one, and will usually last longer. However cordless drills can also work well.[26][27] The one requirement to using a drill is that the drill chuck fits onto the mill drive shaft (which range from 3/8" to 1/2" [9-12mm]). If you are holding the drill while milling, you must also hold down the base of the mill. Otherwise the torque may cause the mill to flip over, causing damage to equipment and/or personal injury.

Recommended Products
Bauer corded drill from Harbor Freight 1/2" chuck, 0-600 rpm, variable speed. These are tried and true, and are frequently recommended by home brewers due to the low cost.
Greenworks 24V cordless drill (Amazon) 1/2" chuck, 0-380 rpm (also has higher speed setting), variable speed, brushless.

Non-drill motor[edit]

Some brewers prefer using a dedicated non-drill motor. See Motorizing a mill.

Reducing torque requirement[edit]

If your drill/motor is having issues with stalling, or you'd like to reduce the load on it in order to extend its life, or you are wanting an easier job of hand cranking, you can reduce the amount of torque needed to drive the mill by reducing the amount of grain feeding into the rollers. All you need to do is create and affix cardboard inserts into the bottom of the hopper.

Setting the gap[edit]

An angled feeler gauge for measuring the roller gap on a 3-roller mill. Photo by Dr. Adam Bittner

All of the mills we recommend have an adjustable roller gap. A tighter gap produces smaller grain particles, called a fine crush, and a larger gap creates a coarse crush. There is not a one-size-fits-all gap setting. The ideal mill gap setting is dependent on your mill, your brewing system, and factors related to the grain (which can vary even from batch to batch and with storage time).[2][28][29] For each batch, the objective is to find an acceptable middle ground between lautering/recirculation effectiveness, efficiency (yield), and quality.[30][31] Some experimentation with different settings is needed to find out what works best for your mill and your brewing system, although there is a wide range that will be adequate.[32] Also, the grist should be visually monitored every milling to ensure it is being properly crushed.

There are two main things to consider when experimenting with the roller gap:

  1. The gap must be small enough so that all the kernels are crushed, which helps to maximize efficiency. This can easily be verified by milling about a cup of grain and visually inspecting it (carefully sort through it looking for uncrushed kernels).[33]
  2. The gap must be large enough to avoid problems with a stuck mash or slow lautering/recirculation.[22][33][34][35] This greatly depends on your system/process, and experimentation is required to find the smallest acceptable gap. For example, a simple BIAB system can tolerate a fine crush, whereas a recirculating system tends to benefit from more intact husks. Keep in mind that excessive husk damage can potentially affect beer quality (see below).[3] Also be aware that 2-roller mills have a lower limit at which the rollers can feed the grain.

For most systems, a gap in the range of 0.025" to 0.050" (0.7–1.2mm) is appropriate.[11][36] To measure this, a feeler gauge (which is a stack of metal pieces with different marked thicknesses) can be inserted into a gap to precisely measure it. To achieve gaps that are not the same as a single blade, stack multiple blades together to add up to the gap you want to set. In a pinch, a standard credit card can be used to set a 0.030" (0.76mm) gap.[37] If you have a 3-roller mill, an angled feeler gauge should be used because a straight feeler gauge cannot access the adjustable gap while the mill is assembled.

Recommended products
Straight feeler gauge (Amazon) Blades range from 0.001" to 0.040" (0.03mm to 1mm)
Angled feeler gauge (Amazon) Blades range from 0.005" to 0.020" (0.127mm to 0.508 mm)
Gap settings marked by the adjustment knobs

Process:

  1. Insert the gauge into a loose gap and then gently tighten the rollers on it. The blades should go into the gap between the rollers with a minimum amount of force, and should not be crushed in the gap. Adjust the gap on both ends of the roller to be the same.[4][38]
  2. On mills with adjustment knobs, mark on the frame what the gap is at the a variety of knob positions. This allows you to repeat different gap settings without needing the feeler gauge again. We suggest marking increments every 0.005" (0.1mm) over a range of 0.020" to 0.055" (0.5–1.4mm).

Milling considerations[edit]

Several things should be considered when deciding on mill gap and other parameters that will affect grist performance during mashing.

Husk integrity[edit]

Pulverizing the entire grain into flour should generally be avoided.[39][40][35] A high percentage of flour will increase the viscosity of the wort, increasing the likelihood of the dreaded "stuck mash" or slow recirculating and lautering. We want the husks to be as intact as possible, not only for filtering, but also because finely shredded husks can cause astringent, bitter, or harsh off flavors.[1][39][41][42][43][44][45] Excessive milling promotes the extraction and solubilization of undesirable compounds into the wort and beer, such as silicates, lipids, husk-derived tannins (phenolic compounds), and large-molecular proteins, which can cause excess formation of trub, deposits, color changes, hazes, and a shorter shelf life.[2][46][47][39][48][49][50] Lastly, too much husk flour can potentially result in loss of extract because starch will be adsorbed to the husk and discarded with it.[51]

However, fine milling does not necessarily cause extraction of harsh flavors, and it can be acceptable depending on the lautering method.[22][52] Mash pH strongly influences the extraction of negative compounds, which can be particularly troublesome when fly sparging. Therefore the issue of undesirable flavor extraction from pulverized husks may be less worrisome for home brewers who properly control mash and sparge pH, although husk pulverization may still lead to other issues such as haze and excessive trub depending on other factors.[53]

Husk integrity can be improved by conditioning the grain, using an appropriately large mill gap, and using a 3-roller mill or a mill with fluted rollers.

Milling speed[edit]

In general, a milling speed between 50–300 RPM is considered appropriate for small scale milling.[54][11][4] Be aware that it usually takes a little more torque to get the mill going. If your drive method is struggling, use the method to reduce torque described above.

Some home brewers have found that milling at a lower speed reduces damage to husks.[55][54][56][57] Other brewers have not noticed a significant effect of milling speed on the grist (appearance or granulometry),[58][59] which is in agreement with professional literature.[40][3]

Oxidation[edit]

Mill with base on top of a cooler mash tun

The grist begins to oxidize immediately upon milling (because the inside of the kernels are then exposed to air and moisture) and this can have a negative impact on the subsequent beer quality.[2][44][60][61] Therefore the time between milling and dough-in should be kept as short as possible.[49]

Modern commercial low oxygen breweries fill all areas containing milled grain with inert gas (CO2 or N2) to prevent oxygen exposure.[2][22][44][52][49] Brewers looking to preserve fresh grain flavor may do this simply by flowing inert gas into the bottom of the mash tun and milling directly into it, or by flushing the grist with inert gas after milling.[62][63][64][65] Purging a mostly covered mash tun at 1–2 psi for about 10 minutes has been shown to effectively remove the vast majority of oxygen in the vessel.[66] A regulator may start to freeze up and/or significantly chill the mash tun parts, causing dough-in temperature to be too low. A fix for that is to get a cheap heat lamp or hair dryer and point it at your regulator.[65] Dry ice can also be used to purge: put the dry ice in a jar with water and connect it with tubing to the mash tun. Note that flushing with inert gas during the actual milling process appears not to be critical, as oxidation does not occur immediately (at least with regard to lipids or proteins).[67][63]

Grain moisture[edit]

The moisture content of the malt influences the fineness of the grist. Moisture makes the grain more elastic and the crush becomes more coarse. Coarse particles adhering to the husks are more difficult to degrade during the mashing process, leading to a lower yield. This mainly applies to malts which, if improperly stored, have a water content of 8–12%. Unlike with grain conditioning, this moisture is distributed through the entire grain. On the other hand, a malt with very little moisture has a tendency to be crushed too fine, destroying the husks and increasing the flour content. This may occur when very young dark malts are used, which is probably an unlikely situation for home brewers. Conditioning may help avoid problems in both of these cases, although minimizing moisture during grain storage is still a high priority.[44]

Specialty grains[edit]

Lighter color kilned or dry roasted specialty malts will crush like base malts, while caramel/crystal and extremely dark roasted products are more brittle and tend to shatter rather than crush. Malts that shatter tend to create more flour which can contribute to difficulties during lautering. The fine particles can fill in the spaces in the otherwise permeable bed causing a slowed or stuck lauter. These brittle specialty malts can typically be milled with a wider mill gap resulting in a larger particle size that will still allow for complete flavor and aroma extraction which is the primary function of these malts. Finding the balance of desired particle size starts with adjusting the mill gaps.[68]

Wheat, rye, and oats
Generally speaking, these grains have smaller kernels (especially rye)[69] and are harder than barely. Therefore the mill gap may need to be decreased when milling these grains, and more torque may be required while milling. Mill small samples to check for whole kernels, just as we suggested above for setting the gap for barley. Take note of the ideal gap for each grain.

Things that don't need to be milled

  • "Flaked" or "rolled" grain adjuncts do not need to be milled, although they can be run through the mill with the rest of the grain if it is convenient.[70]
  • Rice hulls should not be put through the mill because their whole purpose is to remain intact in order to aid filtering.
  • Most home brew mills are not suitable for milling corn.
  • Fingers, clothing, rocks, or bits of metal should not be milled. Please be careful, especially when using power tools.

Dust[edit]

To avoid excessive dust contaminating your gear and wort, it's considered prudent to mill away from your cold-side gear and away from where you'll be chilling and fermenting your wort, particularly if you do not condition the grain. Conditioning can help lower the amount of dust generated while milling. However, dust can still be created when measuring the grain. Wearing a mask can be beneficial for your health since breathing in grain dust is not so great.[1] Thanks to COVID-19 you do have a mask, right?

Conditioning the grain[edit]

Simple grain conditioning setup

Dry husks fragment easily, which may cause issues (see above). Husks become more elastic when they are moist, making them easier to protect.[2][71][11][55][72][28][22][16] Increasing the moisture content of the grain husk right before milling is called "conditioning". The goal is to increase it just enough to minimize shredding as the grain passes through the mill. Generally the amount of water added should be about 1–2% of the weight of grain.[44][2][39][51] It's important not to add too much water because our mills cannot process wet grain; it will stick to the rollers. The recommended amount of moisture is low enough that the grain should not be sticky and it will not cause rollers to rust. Wheat malt also benefits from conditioning even though it is huskless.[73]

Conditioning is not a necessary step, but it does have advantages when combined with a proper roller gap.[39] The roller gap may need to be (and probably should be) tightened when conditioning, to make sure all the grains get crushed and to reap the benefits of more finely crushed starch.[74][28][22] Basically all modern commercial German breweries that use lauter tuns (as opposed to mash filters) either condition their malt or mill it wet.[73]

Advantages:

  • Dust is reduced during milling.[55][15]
  • The risk of dough balls is decreased.[55]
  • The rollers may grip the grain better and feed faster.[55]
  • Improved husk integrity provides a looser grain bed and easier lautering.[2][39][22][15]
  • More intact husks means that the grain can be ground more thoroughly (tighter gap) without affecting lautering.[2][39][22][44]
  • A tighter gap means that the starch is crushed more thoroughly.
  • More thoroughly crushed starch means that efficiency and attenuation are increased and conversion is faster.[2][44][22]
  • Reduced husk damage can have quality benefits on the resulting beer. (See above)
  • Manually stirring and looking at your grain allows you to find any rocks, metal pieces, or other foreign objects that may be mixed with the grain and could otherwise damage your mill.

Disadvantages:

  • Additional time and labor is required.
  • Milling may require additional torque.
  • A roller gap adjustment is probably needed to optimize crush (and prevent uncrushed kernels).[22]
  • Protein extraction may be higher.[39]


Conditioning Method 1 (Editor's Choice)[55]

  1. Put the grain into a wide plastic tub.
  2. Add water to a small spray bottle.
  3. Spray the grain evenly while stirring (e.g. with your hand or a mash paddle) until the grain becomes pliable.
  4. The grain may be milled about 10 minutes after wetting.

View this method in action:

Load video
YouTube


Conditioning Method 2 (no stirring)[11]

  1. Weigh out the grain in buckets.
  2. Add water to a small spray bottle.
  3. Pour a thin layer into a wide plastic tub.
  4. Spray it with water from a spray bottle.
  5. Repeat steps 3 & 4 until done.
  6. The grain may be milled about 10 minutes after wetting.


Conditioning Method 3 (sink sprayer)[11]

  1. Put the grain into a wide plastic tub.
  2. Attach a flexible misting nozzle to a sink hose.
  3. Spray the grain evenly while stirring (e.g. with your hand or a mash paddle) until the grain becomes pliable.
  4. The grain may be milled about 10 minutes after wetting.


If you are using a disc mill (like a Corona/Victoria style mill) instead of a roller mill, different amounts of moisture can possibly have variable and unpredictable effects on the resulting crush.[48] Therefore we cannot recommend conditioning when using such a mill, but you may still experiment if you wish.

For images comparing conditioned vs unconditioned grist, see here: Grain Conditioning at LOB. and Malt Conditioning at German Brewing.

Cleaning and maintenance[edit]

Left: dirty end plate. Right: clean end plate

First time cleaning: After adjusting the gap, mill about a pound of grain and then throw that away. This removes the machine oils from the rollers.

Cleaning after use: A paintbrush and compressed air will remove dust and any grain and dust clinging to the rollers. A stainless steel brush can help remove stubborn particles.

Removing and preventing rust: Most mills have hardened steel rollers, so it is possible for them to rust. Running about a pound of grain or rice through the mill may be all that's needed to remove rust from the rollers. If that doesn't work, brush the affected area with a stainless steel brush until the rust is gone. Dust attracts moisture, so keeping the mill clean as described above will help prevent the rollers from rusting,[22] as will storing the mill in a dry location. If you condition your grain, consider reserving a half pound of unconditioned grain to mill at the end to remove any moisture.

Maintenance: The mills we recommend are fairly maintenance-free, particularly if you have one with sealed ball bearings and if you clean the rollers after use. However, mills (especially those with bronze bushings in particular) may benefit from periodic cleaning: disassemble, wipe clean, and lubricate. Visually check the gap setting before milling to make sure the adjustable gap is not slipping and that the rollers are in proper alignment. Rollers out of alignment may bind. Rollers with stubborn grain stuck between the knurling can be cleaned with a short (e.g. 30 minute) hot alkaline bath (see cleaning), although some rust will likely need to be removed afterwards.

Suggested cleaning and maintenance products
Stainless steel brush Amazon
Food-grade machine oil for lubrication Amazon

Sieve testing[edit]

Sieves with grain sample. Photo by Dr. Adam Bittner.

Sieves can be used to scientifically measure the particle sizes of the grist. This is called granulometry, or sieve testing. Unfortunately, the sieves are a bit expensive and the testing process is somewhat labor-intensive. Furthermore, the results are borderline useless since the crush produced by home brew mills differs greatly from that of a commercial mill, even with similar granulometry results.[59] Therefore, we do not recommend home brewers invest in the materials or effort required for sieve testing.

Our recommendation notwithstanding, sieve testing can be used in combination with visual inspection to compare how different milling parameters can affect the crush, and it can be helpful to maintain a tight degree of consistency through periodic testing. Large breweries use a machine to conduct the test, but it can also be done by hand using a standardized protocol, which has been shown to produce satisfactory results.[75][76] See Sieve testing for more information.

See also[edit]


External links:

References[edit]

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  2. a b c d e f g h i j k l m n Kunze W. Wort production. In: Hendel O, ed. Technology Brewing & Malting. 6th ed. VLB Berlin; 2019:203–218.
  3. a b c d e Mousia Z, Balkin RC, Pandiella SS, Webb C. The effect of milling parameters on starch hydrolysis of milled malt in the brewing process. Process Biochem. 2004;39(12):2213–2219.
  4. a b c FAQs. Monster Brewing Hardware. Accessed May 2020.
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  68. Geurts J. 9-5 grind. Briess blog. 2018. Accessed 2020.
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  73. a b Troester K. Malt Conditioning. German brewing and more wiki. Updated 2009. Accessed 2020.
  74. Seriously bad mash efficiency suddenly! The Modern Brewhouse website. 2019. Accessed 2020.
  75. Malt grist by manual sieve test. J Am Soc Brew Chem. 2003;61(4):246–249.
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