The Covid-19 pandemic has had huge impact on the UK’s hospitality sector, yet the appetite for beer and spirits remains strong. Pumps are integral to the challenges of the brewing or distilling process and switching to progressive cavity pumps could help brewers & distillers thrive.
For breweries, the UK’s continued strong appetite for beers and spirits has been driven in part by consumer taste for craft beers and in the distilling sector there has been an increased demand for authentic and flavoured products such as artisan gin.
While brewing and distilling operations of all sizes from artisan craft to large and highly automated operations remain popular, ring fencing already tight profit margins is critical if producers are to shoulder the economic burdens of Covid-19.
The many challenges faced throughout the brewing or distilling process can be divided into three major areas which are raw materials’ handling, production, and waste handling. In each of these, accurate control of product flow is essential to ensure the final product quality is consistently high, which means that pumps are vital to brewing and distilling operations.
However, not all pumps are created equal. Here, we look at how switching to a progressive cavity (PC) pump can deliver efficiency, productivity, and energy gains to help brewers and distillers thrive, not just survive, throughout the pandemic and beyond.
Mixing and transfer
The brewing or distilling process starts by mixing milled grain (grist) with water in a vessel known as a mash or lauter tun, where the starch is converted into sugar. Traditionally, the grain is cracked and stored in a grist case and then gravity-fed into a masher, where it is mixed with hot water prior to entering the mash tun. However, in newer or smaller breweries, the grist case often sits below the mash tun, with a conveyor system transferring the grist to the masher. This not only involves high incremental costs but can also add complexity to the conveying system, leading to mixing problems; water is often added unevenly, resulting in a mix that is not homogenous and reduces the yield.
An alternative to complex conveyor systems are PC pumps in Seepex’s BT range. These offer installation and mashing-in flexibility, allowing the grist to be mixed with hot water and then pumped into the mash tun. Comprising a feed hopper and an auger feed screw, the pitch and diameter of the auger can be adjusted for optimal product feed, ensuring an homogenous mix and a stable yield.
One producer who is already enjoying the benefits is Ringwood Brewery in Dorset in the UK. Following the installation of a Seepex BT pump underneath the grist case, its grist is now carried safely, effectively and consistently to the mash tun. The time taken for transfer has been cut in half, improving production and almost doubling mashing capacity. In addition, the pump system has been fitted with Seepex’s Smart Conveying Technology (SCT) which enables rapid dismantling and cleaning, increasing pump stator life by up to 200% and reducing maintenance time by up to 85%.
A critical process for any brewery or distillery is the fermentation stage when yeast is added to the wort to convert simple sugars into alcohol. Yeast is shear-sensitive so requires very gentle and hygienic handling to avoid damaging it, which would ultimately have a detrimental effect on the taste of the beer or spirit. Choosing the right yeast pump is therefore crucial.
Gentle & hygienic
Peristaltic pumps are sometimes used at this stage, but their pulsating action can have a negative effect on the quality of shear-sensitive products like yeast. By contrast, Seepex’s BCF range of PC pumps can offer more gentle and hygienic handling, better preserving the yeast quality for fermentation. This is because PC pumps move the product through the pump in a series of cavities, which prevents slip from the discharge back through the pump. Slip creates shear, so compared to other pump designs which have clearances between the lobes, screws or gears, PC pumps have a very low shear action. They also handle entrained air and foam which is important for brewers and distillers as the yeast can gain a foamy consistency at this stage.
At the end of the fermentation process, yeast can also be recovered for re-use (known as harvesting) by discharging from the conical base of closed vessels (bottom cropping) or skimming from the surface of open vessels (top cropping). In either case, the low shear characteristics of the BCF range can offer advantages over alternative pumped methods or inefficient manual procedures.
The addition of flavours and colours into beers and spirits must be done accurately and constantly to ensure even distribution and a consistent final product, with any additives metered in a non-pulsating manner. Positive displacement pumps are sometimes used but their pulsating action means that once they have dispensed a product, there is a pause before they can dispense again. This results in a gap in the process, which can cause uneven distribution of ingredients.
Pulsation-free
In contrast, Seepex’s PC dosing pumps (D range) are virtually pulsation-free and their output is directly proportional to the rotational speed of the pumping elements. This linear accuracy, varied using the pump speed, enables easy calibration and control. Their ability to meter very low flow rates means that colours, flavours and portions are all consistent, and they can also accurately meter a wide range of product consistencies – from thin to highly viscous, abrasive to sticky.
By-products of beer and spirit production include spent grains, draff and hops. At the end of the mashing process, they need to be transferred rapidly to storage tanks or silos to enable production to continue. They are then further transported for use as animal feed, as additives in bakery products, for energy generation in biogas plants or to produce biofuel.
The methods of removing spent grain or draff vary according to the size of the brewery. Small breweries favour manual removal, whilst larger breweries or distilleries tend to use compressed air units (also known as pneumatic expeller units). However, brewers and distillers can significantly reduce their costs by pump- ing these residual materials instead. Open hopper PC pumps with auger feed systems can transport the spent grain or draff within a closed pipe system over hundreds of metres. In addition, because expeller units account for one of the highest utility costs in the industry, this has the additional advantage of reducing energy consumption.
Seepex’s Smart Air Injection (SAI) technology can efficiently convey 15-40% dry solids (ds) spent grains, draff and hops in plugs of 20-30 m length, over distances of up to several hundred metres using controlled air pulses. SAI combines progressive cavity pumping with pneumatic dense-phase conveying to increase process efficiency and productivity, as well as reducing energy consumption. In a spent grain handling test at a UK brewery, conveying efficiency using SAI was evaluated to assess the air consumption savings compared to the existing pneumatic expeller. The test demonstrated the potential to reduce air consumption by ~90% for the mash tun discharge of spent grain into the bulk storage, and by ~80% for the hops discharge.
In conclusion, by moving away from traditional and inefficient product handling methods towards innovative, problem-solving PC pump solutions, brewers and distillers can maintain their product quality, reduce energy consumption and increase their production capacity. By optimising their entire operation and increasing their plant’s overall efficiency, PC pumps are helping brewers and distillers to remain profitable despite the pandemic pressures.