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Winepress

A winepress is a device or apparatus used to extract juice from crushed grapes or grape clusters during winemaking by applying mechanical pressure to separate the liquid from the solid pomace, facilitating fermentation and producing wine.^[1] The earliest known winepress, discovered in the Areni-1 cave complex in Armenia and dating to approximately 4100 BCE, consisted of a shallow clay basin for foot-treading grapes paired with a deeper vat for collecting and fermenting the juice.^[2] Archaeological evidence from pre-Roman Italy shows that wine production began in the Bronze Age (ca. 2200–1700 BCE) with simple treading methods, evolving by the Iron Age (9th–7th centuries BCE) to include rock-cut basins among Etruscan communities.^[3] In ancient Greece and Rome, mechanisms advanced to lever-and-weight presses, where a long wooden beam weighted with stones applied force to a platform over grape solids, allowing juice to drain through slats into collection vats; screw presses, using a rotating screw to lower a pressing plate, emerged in the 1st century BCE for greater efficiency.^[3]^[4] By the Middle Ages, around 1000 years ago, wooden basket presses with horizontal discs and iron-bound staves became common in Europe, particularly among nobility and the Church, marking a shift to more standardized mechanized extraction that persisted into the 19th century.^[1] In regions like southern France, local winepresses appeared by 425–400 BCE, featuring limestone platforms with spouts for draining juice after stomping, reflecting the spread of viticulture through Greek and Etruscan influences.^[5] Today, while hydraulic and pneumatic presses dominate commercial production for their precision and yield, traditional lever and screw designs continue in small-scale and historical winemaking, underscoring the winepress's enduring role in transforming grapes into one of humanity's oldest beverages.^[1]

History

Ancient Origins

The origins of the winepress trace back to the Neolithic period, with the earliest evidence of winemaking emerging in the South Caucasus region of Georgia around 6000 BCE. Archaeological excavations at sites such as Shulaveri Gora and Gadachrili Gora have uncovered pottery jars containing tartaric acid residues from grapes, indicating the production of grape wine using rudimentary techniques. These early methods marked the beginning of organized viticulture, relying on indigenous Eurasian grapevines of the species Vitis vinifera, native to the region and domesticated from wild progenitors.^[6]^[7] The earliest known winepress, discovered in the Areni-1 cave complex in Armenia and dating to approximately 4100 BCE, consisted of a shallow clay basin for foot-treading grapes paired with a deeper vat for collecting the juice.^[2] By circa 3000 BCE, similar labor-intensive practices had spread to ancient Egypt, where foot-treading was the primary means of pressing grapes, as inferred from chemical analyses of tomb residues. At Abydos, Tomb U-j yielded up to 700 jars with grape pips and tartaric acid traces, suggesting large-scale production of approximately 4,500 liters of wine, often imported from Palestinian vineyards and used in elite funerary contexts. These techniques supported Egypt's burgeoning viticulture in the Nile Delta and Fayum regions, where grapes were harvested and trodden by workers to release free-run juice before further pressing by hand or sack.^[8] Archaeological evidence from rock-cut winepresses further illustrates these early methods in the Levant and Mediterranean. In Israel, a 5,000-year-old rock-hewn press near Tel Megiddo features a sloped treading floor leading to a collection vat, providing the earliest confirmed relic of wine production in the region and highlighting organized Canaanite viticulture during the Early Bronze IB period. Similar installations appear in ancient Greece, such as the well-preserved Hellenistic example at Knossos on Crete, where bedrock was carved into treading surfaces and settling basins for juice separation. At sites like Tel Kabri in northern Israel, associated Middle Bronze Age structures underscore the scale of grape processing and palace-based winemaking. These rock-cut features, often integrated into agricultural landscapes, demonstrate the shift toward semi-permanent installations for communal pressing.^[9]^[10]^[11] In Mesopotamia and Phoenicia, manual treading in vats gradually transitioned to basic lever systems by the late Bronze Age, enhancing juice extraction efficiency on treading floors. Excavations at Tell el-Burak in Lebanon reveal an Iron Age (circa 700 BCE) Phoenician press with a plastered basin for foot-treading, representing an early step toward augmented mechanisms like weighted levers documented in nearby Syrian sites. These innovations supported expanding trade networks. Culturally, winepresses were integral to early viticulture, symbolizing abundance and fertility; the resulting wine from Vitis vinifera varieties featured prominently in religious rituals, such as Canaanite offerings and Egyptian funerary banquets, where it facilitated communal and divine communion.^[12]^[13]^[14]

Medieval Advancements

During the Middle Ages, European monastic communities played a pivotal role in advancing winepress technology, transitioning from ancient manual treading to more efficient mechanical devices. The basket press emerged as a key innovation around the 8th to 12th centuries, particularly among Benedictine and Cistercian orders, who refined it for abbey production to support liturgical needs and economic self-sufficiency. These presses consisted of a cylindrical wooden basket reinforced with wooden or metal hoops, into which crushed grapes were placed, and a heavy wooden beam lever applied downward pressure via a fulcrum to extract juice more effectively than foot treading alone.^[15]^[16]^[17] Building on Roman engineering principles, early screw mechanisms were reintroduced and adapted in Italy and France by the 12th century, enhancing control over pressure application in basket-style presses. Cistercian monks, such as those at the Abbey of Cîteaux founded in 1098, further refined these designs for large-scale abbey operations, optimizing juice yield and quality in regions like Burgundy where they established renowned vineyards. This period marked a shift toward semi-mechanical efficiency, with presses enabling the production of distinct wines like vin de goutte from free-run juice and vin de presse from the pressed residue.^[18]^[15] Regional variations highlighted diverse adaptations across Europe. In Germany, ratchet-equipped lever presses, often used in Cistercian abbeys like Eberbach established in 1136, incorporated geared mechanisms for incremental pressure adjustment. Italian designs favored vertical beam types, influenced by classical Roman levers, with taller structures allowing for precise operation in monastic and noble estates in Tuscany and beyond. These innovations, rooted in ancient manual precursors, significantly boosted productivity while preserving the artisanal essence of winemaking.^[19]^[20]^[3]

Industrial Innovations

The Industrial Revolution marked a pivotal shift in winepress technology, transitioning from labor-intensive manual operations to mechanized systems that facilitated larger-scale production. In the late 18th century, French inventor Abbé Legros introduced an advanced screw press design, illustrated in Denis Diderot's Encyclopédie, which improved pressure application and juice extraction efficiency compared to earlier vertical models.^[21] This innovation built upon medieval screw prototypes but incorporated more precise mechanical elements, enabling winemakers to handle greater volumes with reduced physical effort.^[22] By the mid-19th century, the adoption of steam and hydraulic power further revolutionized winepressing, particularly in major regions like Bordeaux, France, and emerging areas in California. Steam-powered basket presses became widespread, accelerating the process and minimizing manual labor, as seen in Bordeaux's expanding châteaux operations where they supported the region's growing export demands.^[15] In California, during the 1850s Gold Rush-era wine boom, similar steam-driven systems were imported and adapted to process increasing grape harvests from varieties like Mission, boosting local production capacity.^[23] Hydraulic presses followed, with Joseph Vaslin patenting a rectangular horizontal screw press in 1856, which allowed for continuous operation and easier emptying of pomace.^[20] Johann Bucher advanced this in 1874 with a hydraulic model that applied uniform pressure via water or oil systems, enhancing extraction in both European and American vineyards.^[24] These 1850s patents, including Vaslin's horizontal design, improved juice yields over traditional manual presses by optimizing pressure distribution and reducing juice loss in the pomace. Hydraulic variants further improved throughput, as documented in contemporary winemaking treatises.^[20]^[25] Such innovations profoundly influenced global wine trade by slashing labor costs—steam and hydraulic systems required fewer workers per ton of grapes processed—and standardizing juice quality through better control over extraction stages.^[15] Winemakers could now separate free-run juice, which constitutes 60-70% of the total yield and offers higher clarity and lower tannins, from press juice, enabling early quality metrics like yield ratios (typically 70:30 free-run to press) that ensured premium wines for export markets while directing coarser press fractions to blending or distillation.^[26] This standardization supported the 19th-century surge in international shipments from Bordeaux to Britain and the Americas, fostering economic growth in wine-exporting regions.^[23]

Design and Operation

Core Components

A traditional winepress consists of several fundamental physical parts that form the basis for juice extraction from grapes. The frame serves as the primary structural support, typically constructed from robust materials to withstand applied pressure, while the pressing surface—often in the form of fixed platens or cylindrical baskets—holds the crushed grapes during operation. Adjacent to these are drainage channels, which guide the free-run juice away from the pressing area, and collection vats positioned below or nearby to capture the must for further processing.^[3]^[27] In ancient iterations, the frame was commonly built with wooden beams anchored into stone piers or walls for stability, and the pressing surface took the form of a treading floor crafted from plastered stone or mosaic tiles to contain and slightly compress the grapes under foot. Drainage channels were integrated as sloped grooves or plastered conduits leading from the treading area, with collection vats lined in impermeable cocciopesto (a mixture of lime and crushed pottery) to prevent leakage.^[3]^[27] Materials for these components have evolved significantly over time, beginning with oak wood and stone in antiquity for their natural availability, strength, and resistance to moisture in outdoor or semi-open settings. Oak provided a breathable quality that minimized rapid spoilage in humid conditions, though it required frequent maintenance to avoid cracking. By the Roman period and into medieval designs, iron reinforcements appeared in frames and mechanisms for added rigidity, transitioning in the industrial era to steel for enhanced load-bearing capacity. Steel offers superior durability against corrosion and mechanical stress compared to wood, but it demands protective coatings to prevent unintended metallic flavors in the juice, while wood's porosity can complicate thorough cleaning.^[3]^[27]^[28] Hygiene and safety in traditional winepresses incorporate sloped floors on the pressing surface and drainage paths to enable gravity flow, ensuring juice moves efficiently without standing water that could foster bacterial growth or create slip hazards. Early sanitation practices focused on simple rinsing with clean water after each use to remove grape residues and inhibit microbial contamination, a method that predates chemical agents and remains relevant for wooden components.^[27]^[29]^[30] Dimensional standards for winepresses reflect their intended scale, with small-scale artisanal models typically 1-2 m wide to accommodate manual operation on modest grape volumes of 50-200 kg per batch. In contrast, commercial presses can extend several meters in length, handling 1-5 tonnes or more to support large-scale production, often with modular frames for adjustability.^[31]^[32]

Pressing Mechanisms

Pressing mechanisms in winepresses apply controlled force to grape pomace to extract juice, relying on fundamental mechanical principles to amplify human or machine input. Lever-based systems, common in historical designs, utilize the principle of torque where a long beam pivots around a fulcrum, providing mechanical advantage through the ratio of effort arm length to load arm length; for instance, levers spanning 4-5 meters could multiply applied force significantly, enabling one or two operators to exert substantial pressure on large volumes of grapes.^[18]^[20] Screw mechanisms operate on the inclined plane principle, converting rotational motion into linear force via a threaded rod that advances a plate against the pomace; this design offers adjustable pressure with less physical effort than levers, as the mechanical advantage equals the circumference of the screw divided by its pitch, often resulting in efficient force multiplication for batch pressing.^[20] Hydraulic systems, introduced in the 19th century, employ Pascal's principle, where pressure transmitted uniformly through an incompressible fluid (typically oil) allows a small input force on a narrow piston to generate large output force on a wider piston, with mechanical advantage determined by the ratio of piston areas—commonly achieving 10:1 or higher ratios for precise, high-force application without manual labor.^[20]^[33] The application of pressure occurs in staged increments to optimize juice quality and quantity. Initially, a gentle squeeze—often just the weight of the pomace itself or minimal force—releases free-run juice, which flows from ruptured cells in the grape pulp without significant mechanical stress, preserving delicate flavors and aromas.^[33] Subsequent stages involve incremental pressure increases, typically in cycles, to extract press juice from the remaining solids; this might include light pressing followed by heavier applications, with operators or automated controls monitoring to avoid abrupt changes that could disrupt extraction.^[20] These stages ensure separation of higher-quality free-run fractions from more robust press fractions, with the former often comprising the majority of the final wine blend.^[33] Efficiency in pressing is measured by juice yield rates, typically achieving 60-80% recovery from grape weight, where one tonne of grapes yields 500-650 liters of free-run or lightly pressed juice plus an additional 100-200 liters from heavier pressing.^[34] Factors influencing these rates include grape ripeness, as riper berries with softer skins release juice more readily under lower pressure, and pressure duration, where prolonged moderate application enhances extraction without degradation, potentially increasing overall yield by 10-20% compared to rushed processes.^[33] Optimal conditions balance these elements to minimize solids in the juice, improving clarity and fermentation efficiency.^[20] A common challenge in pressing is over-pressing, which applies excessive force and extracts bitter tannins and phenolics from seeds and skins, leading to astringent, unbalanced wines.^[33] This risk heightens above 2 bars of pressure or with aggressive pomace breakdown, introducing harsh compounds that overpower fruit character.^[33] Mitigation involves staged releases, where pressure is built gradually with pauses for drainage and selective discarding of outer pomace layers (e.g., the top 5-10 cm), preventing tannin overload while maximizing usable juice.^[33] These techniques, supported by structural frames that distribute load evenly, maintain juice integrity across mechanism types.^[20]

Juice Extraction Process

The juice extraction process in a winepress begins with the preparation of grapes through destemming and crushing to form must, a mixture of juice, skins, seeds, and pulp. This must is then loaded into the press, where the initial stage involves gravity drainage to collect free-run juice, which flows naturally without applied pressure and represents the highest quality fraction due to its lower content of tannins and phenolics extracted from prolonged skin contact.^[35]^[36] Following this, pressing cycles are applied incrementally to force additional juice from the solids, separating the liquid from the remaining skins and seeds while minimizing excessive extraction of bitter compounds.^[36] The process concludes with unloading the pomace, the compacted residue of skins and seeds, which is removed for further handling.^[37] Separation techniques distinguish between free-run juice, prized for its clarity and delicate flavor profile suitable for premium table wines, and forced press juice, which contains higher levels of solids, acids, and phenolics and is often reserved for fortification wines or blending to enhance body.^[35] The extraction relies on controlled pressure principles to rupture cell walls and release intracellular fluids without over-compressing the pomace, which could impart undesirable harshness. Quality is maintained through temperature control, ideally kept between 10-18°C during pressing to inhibit enzymatic oxidation and preserve fresh aromas, particularly for white and rosé wines.^[38] Additionally, the pomace is commonly reused for distillation into spirits like grappa or brandy, recovering residual sugars and alcohols.^[37] Manual pressing operations typically require 4-8 hours per batch, depending on the press capacity and grape volume, involving labor-intensive loading, monitoring cycles, and cleanup. From one tonne of grapes, yields generally range from 600-850 liters of total juice, with free-run and light pressing contributing 500-650 liters and heavier press fractions adding 100-200 liters.^[39]^[40]

Types of Winepresses

Basket Presses

The basket press, a traditional type of winepress, features a cylindrical basket constructed from wooden slats bound together by metal hoops or rings, enclosing the grapes during compression. A central vertical screw or ratcheting lever mechanism lowers a perforated plate onto the grape mass, applying gradual pressure to extract juice through the gaps in the slats.^[41]^[20] Originating in medieval Europe, basket presses became a staple in regions like France, Germany, Spain, and Italy, where they dominated winemaking from the Middle Ages through the 19th century. Their enclosed design facilitated controlled pressing after fermentation, making them particularly suitable for red wines by allowing extended skin contact to develop color, tannins, and flavor complexity without excessive seed breakage. By the late 19th century, innovations like iron spindles and ratchets improved efficiency, though they remained batch-oriented tools for smaller estates.^[41]^[20] Basket presses offer gentle extraction, typically yielding about 70% free-run and press juice while minimizing bitter compounds from seeds and stems, which suits artisanal production of premium reds. However, they are labor-intensive, requiring manual loading, ratcheting, and periodic crumbling of the pomace, with capacities limited to 200-500 kg per load, restricting throughput compared to modern alternatives.^[42] In contemporary winemaking, basket presses have seen a revival among organic and low-intervention producers, particularly in Burgundy, where they are used for small-batch premium wines to emphasize terroir and finesse through minimal mechanical stress. Winemakers value their ability to handle whole clusters delicately, preserving nuanced aromas in high-end cuvées.^[42]

Screw Presses

Screw presses represent a mechanical advancement in wine extraction, utilizing a threaded screw mechanism to apply controlled pressure on grape must. These devices, which originated in the 1st century BCE, evolved from earlier lever systems and were prevalent in European cellars through the 20th century, where they offered greater precision compared to manual treading or basic beam presses. The screw's helical threads distribute force evenly across the material, minimizing uneven crushing and allowing for gradual juice release to preserve wine quality.^[18] Two primary variants exist: vertical screw presses, which apply direct top-down pressure via a descending plate connected to the screw, and horizontal models, which feature side-loading chambers where the screw advances laterally against fixed plates or a perforated cylinder. Vertical designs, common in earlier iterations through the mid-20th century, suit smaller batches and traditional setups, while horizontal variants handle larger volumes and enable adjustable pressure for optimized extraction. In both, the screw is typically turned using a ratchet mechanism for incremental advancement or a hand-wheel for smoother rotation, building pressure progressively to separate juice from solids without excessive tannin release. Some models integrate a basket-like perforated enclosure to contain the must during pressing.^[43]^[44]^[45] These presses are versatile for producing both white and red wines, as the controlled mechanics allow gentle handling of delicate white grapes or firmer pressing for reds to extract color and structure. In Burgundy, horizontal screw presses, such as the Vaslin model introduced in the 1960s, gained prominence for their precision in pressing Pinot Noir, enabling winemakers to achieve nuanced fractions of free-run and press juice while minimizing oxidation. Operationally, they were staples in cellars from ancient times through the 20th century, often powered manually or later by steam, before pneumatic alternatives emerged.^[46]^[47]^[15] Maintenance considerations differ by construction: traditional wooden screws and frames, while aesthetically valued, are prone to wear from moisture and acids, potentially harboring bacteria in porous surfaces and requiring regular sanding or replacement to sustain efficiency. Metal screws, particularly stainless steel in modern adaptations, resist corrosion and simplify cleaning with pressure washing or steam, though thread wear from repeated use can diminish mechanical advantage over time, necessitating periodic inspection and lubrication to measure flight-to-screen clearance and prevent slippage. Proper upkeep ensures longevity, with steel variants offering lower long-term maintenance demands compared to wood.^[31]^[48]

Bladder Presses

Bladder presses, also known as pneumatic membrane presses, feature an inflatable rubber bladder housed within a sealed cylindrical stainless steel chamber, where grapes or pomace are loaded for processing.^[49] The bladder expands uniformly under controlled air pressure, typically up to 3 bar, to compress the material against the chamber walls, allowing juice to drain through perforated channels or slats at the base.^[50] Many models incorporate rotation of the chamber during pressing to ensure even distribution of pressure and prevent channeling, promoting consistent extraction without excessive mechanical agitation.^[51] These presses were first developed in the early 1950s, with the original horizontal rubber bladder design introduced in 1951 by the German manufacturer Willmes, marking a significant advancement over traditional screw presses that relied on manual or mechanical force.^[20] Rapid adoption followed in European winemaking regions, including Italy and France, where they became integral to commercial operations by the late 20th century due to their efficiency in handling larger volumes.^[49] Today, bladder presses are a standard in modern wineries worldwide, particularly for producing premium white and sparkling wines where quality preservation is paramount.^[43] A key benefit of bladder presses lies in their gentle operation, which minimizes skin breakage and seed damage compared to more forceful methods, resulting in juice with lower levels of suspended solids and phenolic compounds that could impart bitterness or oxidation risks.^[52] This controlled compression allows for high yields—often achieving 90% under low pressure of 0.8 bar—while the enclosed design reduces exposure to oxygen, preserving delicate aromas and flavors.^[53] Capacities vary widely, from small units handling a few hectoliters to large industrial models processing up to 50 tons of grapes per cycle, making them suitable for both boutique and high-volume production.^[54] Despite their advantages, bladder presses come with notable drawbacks, including higher upfront costs due to their sophisticated construction and automation features, often several times that of basic basket or screw presses.^[55] Additionally, they require a reliable compressed air system, such as an integrated compressor, for bladder inflation, adding to operational complexity and maintenance needs in winery setups.^[56]

Continuous Systems

Continuous systems in winepresses refer to auger-based or screw presses designed for uninterrupted operation in industrial settings. These presses employ a rotating screw conveyor, often within a perforated cylindrical cage, to continuously feed, crush, and compress grapes or must, extracting juice through mesh screens while ejecting solids steadily.^[57]^[58] Developed in the 20th century as an evolution from earlier batch screw designs, they enable high-throughput processing without the need to stop and restart cycles, making them suitable for bulk production.^[59] These systems are primarily applied in large-scale winemaking operations, such as cooperatives in regions like Australia and California, where they support the production of jug or table wines. Capable of handling 40-100 tons of grapes per hour depending on the model, they facilitate efficient processing during peak harvest periods for high-volume, economy-grade wines.^[57]^[33]^[36] Key features include integration with destemmers for handling whole or destemmed grapes and built-in filtration via perforated screens to separate juice from solids. Operators can adjust screw speed using inverters for precise control over pressing intensity, typically maintaining pressures between 1-3 bar to balance yield and quality. Hydraulic or counterweighted closure mechanisms further regulate flow and pressure, ensuring consistent output in continuous lines.^[57]^[58] From an environmental perspective, continuous systems reduce waste by enabling ongoing pomace ejection for immediate handling and potential reuse in applications like animal feed or composting. However, the prolonged exposure of must to air during the steady flow can increase oxidation levels, potentially affecting wine color and aroma stability compared to gentler batch methods.^[33]^[58]

Flash Release Methods

Flash release methods, also known as flash détente or a form of thermovinification, involve heating crushed grapes in a closed system to temperatures between 70°C and 95°C under moderate pressure, followed by explosive decompression into a vacuum chamber. This sudden pressure drop, typically from 4 to 7 bar to near-vacuum levels (20-50 hPa), causes the water in grape cell walls to flash evaporate, bursting the cells and enabling rapid juice separation without mechanical pressing. The process yields high extraction rates, often approaching 95% of available juice and significantly enhancing the release of phenolic compounds like anthocyanins and tannins, while the resulting must is quickly cooled to 30-35°C to preserve quality.^[60]^[61]^[62] The technique originated as an advancement of thermovinification, which was developed in the 1960s in France to improve color and flavor extraction from grapes. Flash détente was specifically patented in 1993 by the French National Institute for Agricultural Research (INRA) at Pech Rouge, with early applications focused on enhancing phenolic yields from thin-skinned varieties like Pinot Noir. Studies in Bordeaux during the late 1990s and early 2000s further refined its use for such grapes, and today it is widely adopted for producing rosé wines and those from early-harvest reds, where rapid processing helps mitigate underripeness or uneven maturity. Over 100 commercial systems are in operation worldwide, reflecting its integration into modern viticulture.^[60]^[61]^[63] Equipment for flash release typically consists of closed stainless-steel vessels equipped with dynamic heat exchangers or steam injection systems for rapid heating, connected to a vacuum chamber for decompression and cooling. Crushed grapes are fed into the heater, where steam or hot water raises the temperature in minutes, and the mixture is then transferred to the low-pressure chamber, where vapors are condensed and recirculated to recover aromas and volume. Systems like those from Pellenc, with capacities from 10 to 35 tons per hour, allow continuous operation and are controlled via programmable logic interfaces for precise temperature and pressure management. Post-treatment, the must undergoes cooling and separation, often followed by brief maceration if needed.^[62]^[60] These methods accelerate production, completing extraction in hours rather than days compared to traditional pressing, while denaturing oxidative enzymes like laccase and polyphenol oxidase to reduce microbial risks and improve stability. The resulting wines exhibit enhanced fruity aromas, deeper color, and softer mouthfeel due to increased polysaccharide and polyphenol extraction, with reduced vegetal or green notes from volatile compound removal. However, the high-heat treatment can lead to lower overall tannin astringency and potential flavor alterations if not managed, such as overly intense fruitiness or reduced complexity in some varietals, necessitating careful blending or adjustments in fermentation.^[60]^[61]^[62]

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Jun 25, 2020 · Winemaking by-products can be reused as different food ingredients, such as fibers, polyphenol extracts, grape seed oil, and applied to produce ...
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[PDF] Wine Fermentation
Aug 22, 2022 · Wine fermentation involves yeast converting must sugar to alcohol, typically 3-5 days at 20-28°C for red wines, and 7-14 days at 10-18°C for ...
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Pressing - Union des Maisons de Champagne
Capacity ranges from 2,000 to 4,000, 8,000 or 12,000kg of whole grapes depending on the size of machine. ... The clusters are very fragile and must be handled ...
[40]
None
### Summary of Wine Yield per Tonne of Grapes
[41]
Making Wine in Medieval Europe - Brewminate
Sep 13, 2020 · Their successors went further, developing the 'basket press'. This typically medieval wine-press used a basket made of wood staves kept ...
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The basket press comes back to Burgundy - The World of Fine Wine
Apr 13, 2022 · It is a vertical action. The pressure is relatively gentle on the skins and it doesn't crush the seeds or the stalks if whole bunches are used.Missing: beam | Show results with:beam
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Different Types of Wine Presses and Their Uses - SRAML
There are three main types of wine presses: screw presses, bladder presses and basket presses. Wine pressing is an essential winemaking process.
[44]
Screw Press | Vincent Corp
Dec 2, 2013 · All screw presses today are built with the screws in a horizontal configuration. Through the 1800's up until the 1950's vertical designs ...Missing: maintenance | Show results with:maintenance
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https://wmdequipment.com/Ratchet-Press-Instructions
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Big Red Diary – Page 325 – Burgundy-Report
p39: The pressing of grapes is now done almost totally in horizontal presses. The Vaslin horizontal screw-press is now the most common in Burgundy, but ...
[47]
Pressing White Grapes - The Vaslin Press - YouTube
Nov 28, 2021 · Introduced in the 1960s, the Vaslin uses a screw, motor and chains to press and extract. In this video, our Frence wine reviewer William ...Missing: Joseph patent 1856<|separator|>
[48]
Operating Hints – CP-6 thru CP-12 Presses | Vincent Corp
Jun 16, 2020 · The easiest way to check for screw wear is to open the cone, clean out the material and measure the distance between the screw flight and the ...
[49]
Pneumatic Presses In The Wine Industry | News - Vitikit Limited
In the 1950s, the design that forms the basis of today's pneumatic presses was introduced. The principle of operation is that a rubber bladder is placed inside ...
[50]
https://morewine.com/collections/wine-bladder-press
[51]
Bladder Tank Presses - Wine Business
Sep 1, 2022 · Tank Presses come in two basic types—open or closed. The open horizontal tank press is probably the most familiar: as the press is filled, juice ...Missing: traditional core components frame
[52]
https://westgarthwines.com/blogs/news/grape-processing-destemming-crushing-and-pressing-in-white-wines
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Willmes Presses - Scott Laboratories
SPECIALISTS IN PRESSING TECHNOLOGY · 1,200–5,100 liters · Stainless steel juice channels · Maximizes high quality juice: 90% of yields achieved under 0.8 bar · Easy ...
[54]
Pneumatic press AVANT big PMC - Miros Group
Soft pneumatic press for processing grapes from 5 to 50 tons of capacity. General features: Closed tank made of AISI 304 stainless steel with internal ...
[55]
Wine Production: Choosing a Wine Press - Gravity Wine House
Mar 11, 2022 · Pressing wine is an essential winery operation. It is important to choose the type of press most suited for your winemaking style and needs.Missing: surface | Show results with:surface<|separator|>
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[PDF] VP Standard Pneumatic Presses
• Ultra-quiet and highly efficient Becker compressor for high-pressure pressing ... • Quiet fan for fast airflow: up to +0,2 bar. • Quiet fan to vacuum the ...
[57]
continuous single screw press - winery equipment - Puleo
SINGLE SCREW PRESS MODELS ; ENO-PRESS M125. 0,75 kW. 0,5/0,6 tons ; ENO-PRESS M170. 1,1 kW. 1/1,2 tons ; ENO-PRESS M400. 5,5 kW. 7 / 9 tons ; ENO-PRESS M620. 11 kW.Missing: pressure force
[58]
Continuous Screw Press For Red Wine Processing Equipment
Continuous Screw Press is commonly used in red wine production, particularly for efficiently separating grape juice and wine from the skins, seeds.
[59]
What is Continuous Screw Press? - Definition from WineFrog
A Continuous Screw Press is one of several types of wine presses used to extract juice from crushed grapes during winemaking. Wine presses exert controlled ...Missing: auger | Show results with:auger
[60]
Heating Treatments - Part II Flash Détente (Release)
Apr 26, 2021 · The flash détente or flash release technique seems promising as a method to extract more anthocyanins and tannins from grape skins, as well as ...Missing: equipment pros cons
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https://doi.org/10.1021/jf053153k
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Thermovinification of red and white grapes: Flash Detente Technology
Compared to traditional techniques, the Flash Detente process significantly increases the quantity of extracted dyes, the polyphenols and the polysaccharides.Missing: method pros
[63]
Flash Détente Evolves - Wine Business
Dec 1, 2015 · Flash détente systems have been used since the 1990s. More than 120 systems are installed at wineries worldwide. With the exception of a small ...