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Figure 6.6. Steele’s masher located under a grist case on an American infusion mash tun. Note the hot liquor inlet at the throat of the masher. (Courtesy of BridgePort Brewing Company)
Figure 6.7. Mashing-in an ale brew in a typical British mash tun. Two tuns are arranged side by side and served by a single Steele’s masher with a swiveling outlet spout. The grist-to-liquor ratio is commonly determined by visually judging the consistency of the incoming mash. Mash tuns are typically open, with flat, levered lids that are lowered after mash-in. (Courtesy of St Austell Brewery)
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Figure 6.8. Infusion mash tun with 2.1-ton capacity (75-barrel brew length) in an American craft brewery, outfitted with a grist hopper, Steele’s masher, wedge wire false bottom, and internal grain-out plow. (Courtesy of BridgePort Brewing Company)
49. What is the construction of an infusion mash tun? A mash tun is a dual-purpose vessel designed to combine both the functions of enzyme conversion and wort separation. Traditionally made of wood, cast iron, or copper and more recently made of stainless steel, this vessel is normally circular and well insulated. Small breweries may have a vessel 4–6 feet in diameter with a grain bed depth of 4 feet, whereas larger systems may use a vessel 30 feet in diameter with grain beds 8 feet deep. Figure 6.8 shows an infusion mash tun in a 75-barrel American brewhouse. Figure 6.9 shows a pair of mash tuns serviced by a Steele’s masher in a traditional British ale brewery. The traditional infusion mash tun does not incorporate any heating or cooling jackets in its design, relying entirely on the initial “strike” temperature of the added brewing liquor. Likewise, absent are mixing blades. All mixing is done during mashing in. A mash tun is equipped with the following features: a. False bottom, traditionally made of “gun metal,” is now usually made from milled stainless steel or wedge wire, although even plastic may be employed, provided it can adequately withstand heat and is braced for support.
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Figure 6.9. Two mash tuns capable of a 180-barrel brew length each serviced by a single Steele’s masher (center). This brewhouse arrangement can produce eight to 10 brews per day without the use of separate mash mixing or lauter tuns. (Courtesy of St Austell Brewery)
b. True bottom below the false bottom should be essentially flat to minimize under-screen volumes while still allowing for false bottom support, wort flow, and cleaning nozzles (in larger tuns). c. Collection piping or wort draw lines are normally evenly distributed to cover the bottom of the tun. The number of pipes averages one per 15–25 ft2 of screen area. d. Sparging device for rinsing or sparging the grain bed with hot water. e. Collection grant regulates the flow from the vessel and breaks the siphon between the mash bed and the brew kettle without creating undue suction pressure on the grain bed. f. Spent grain outlet is a manway for side discharge in smaller tuns or a trap door and plow in larger tuns to remove spent grain after wort collection is completed. 50. How is the false bottom constructed? The false bottom is installed in the mash tun to provide support for the grain bed during the mashing in process and to retain the spent grain
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Figure 6.10. Wedge wire false bottom plates in an infusion mash tun. Wedge wire is a less expensive alternative to machined false bottom plates. (Courtesy of BridgePort Brewing Company)
after runoff is complete. During the runoff, however, most of the separation of wort from spent grain occurs in the grain bed itself. Ideally, the grain bed floats several inches above the false bottom. In larger vessels, the false bottom is constructed as a series of interlocking plates that fit together to cover the entire area of the vessel bottom. Smaller vessels may have only two such plates. The design of the slots in the false bottom is important. They must be narrow enough to prevent large particles from passing through yet wide enough not to become blocked and prevent flow altogether. It is a good idea for the slots or holes to be wider on the underside than on the top side to prevent particles that pass through the screen from plugging the gaps. Some manufacturers mill slots into the screens and mill the underside wider. Others choose to construct the screens with V-shaped, or “wedge,� wire laid out in strips separated by an appropriate distance. In general, the slot gaps are 0.16–0.28 inches wide, and the total open area of the false bottom is about 10% for milled bottoms and 18% for V wire. Figure 6.10 shows a V-wire screen used in an infusion mash tun. 51. How is the sparge device constructed? The sparging system must be constructed so that it adds hot water to the top of the grain bed at the same rate at which wort is collected. The
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Figure 6.11. Open grant and taps from a traditional mash tun. Each tap leads to an individual wort draw-off line under the vessel. Lautering is adjusted by the rate of flow through each tap, collection is made in the open tub, and the wort is pumped to the brew kettle. (Courtesy of St Austell Brewery)
water must be gently sprayed or sprinkled onto the surface of the grain to avoid disturbing the bed. Several options exist: a. Rotating arm with small holes drilled in the rear side and installed in the middle of the tank. Water flowing through the arm causes it to rotate, slowly sprinkling water on the surface as it spins. b. Spray nozzles can be arranged to provide full coverage of the surface area of the grain bed. Nozzles should have full-pattern coverage at the flow rates needed. c. Simple sprayballs or even a splash plate suffices in rudimentary systems. 52. How is the wort collection controlled? It is not a good idea to pump directly from beneath the grain bed to the brew kettle. This can result in excessive negative pressure beneath the grain bed, which causes it to close up and compact, preventing flow-through (i.e., a “stuck� mash). Traditionally, wort was allowed to flow by gravity controlled by partially opening valves on collection pipes from under the tun into an open collection grant (Figure 6.11). Larger vessels have several wort draw-off points beneath the false bottom, and each has a valve to individually control runoff rates. The wort flows into a separate vessel called an underback, wort
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Figure 6.12. Closed collection grant on an infusion mash tun. All wort draw-off lines from the tun flow to the grant, which is vented back into the tun. This arrangement allows wort with minimal air contact to be pumped to the kettle without creating negative pressure on the mash bed. (Courtesy of BridgePort Brewing Company)
receiver, or grant. These used to be open collection tanks, from which the wort would either feed to a pump or flow by gravity to the kettle. Concern over wort aeration has led to different designs for separate closed but vented collection vessels from which the wort can safely be pumped. Figure 6.12 shows a closed grant design, which breaks the siphon between the mash tun and wort collection pump. In this design, the vessel completely fills and the runoff rate is dictated both by pumping speed and percolation rates through the mash bed without the splashing and possible aeration of the open grant. 53. What is the differential pressure? Differential pressure (DP) is the difference between the pressure beneath the false bottom and the pressure above it. If the DP is too high,
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Figure 6.13. Grain-out plow in a British infusion mash tun. Fins on the sides of the arm channel spent grain to the outer edge of the tank, where the scoop can then push it into the discharge hole. The spent grain falls to a spent grain pump to be transferred to a waiting truck. (Courtesy of St Austell Brewery)
the suction pulls the mash bed down onto the plates and compacts it, stopping flow. Many mash tuns are equipped with simple manometers that can be used to assess the approximate DP during runoff. One sight glass is installed above the false bottom and another below it in the runoff pipe. The difference in liquid heights in the sight glasses represents the DP. DP varies with mash tun design, but in general 2–6 inches is appropriate. 54. How is the spent grain removal equipment constructed? Most small (up to 850-lb capacity) infusion mash tuns are equipped with a side door through which spent grain can be manually shoveled or raked into collection bins. Larger vessels are equipped with rotating arms that either sit at the bottom of the tun (Figure 6.13) or can be lowered into the grain bed and used to push the grain out through an opening in the bottom of the vessel. The material can then be transferred directly to a spent grain receiver by auger or other mechanical means such as a progressive cavity pump or more commonly a rotary screw and compressed air system.