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Multiple-effect evaporator

The multiple-effect evaporator was invented by Norbert Rillieux and patented in 1840. A multiple-effect evaporator (MEE) is an industrial apparatus that concentrates solutions by evaporating water or other solvents through a series of interconnected evaporation stages, known as effects, where the vapor generated in one effect serves as the heating medium for the next effect operating at successively lower pressures and temperatures. This design reuses latent heat from the vapor, achieving steam economies approximately equal to the number of effects—typically 4 to 12—compared to single-effect systems, which require fresh steam for each evaporation step. In operation, is introduced to the first to boil the feed , producing vapor that condenses in the heating tubes of the second , transferring heat to evaporate more at a reduced due to conditions. Common configurations include forward feed, where the and heating vapor flow in the same direction, ideal for heat-sensitive materials with significant elevation; backward feed, which flows counter-currently for viscous concentrates; and parallel feed, distributing the across effects simultaneously for balanced operation. Evaporator types within effects often feature falling film designs, where descends as a inside vertical tubes heated externally, minimizing (e.g., 9 seconds) and achieving high coefficients (260–420 Btu/hr·ft²·°F for at 90–212°F). The process accounts for factors like non-equilibrium allowance and rise, with performance ratios reaching 3.34 for forward-feed systems with 4 effects up to 21 when combined with vapor compression techniques. Multiple-effect evaporators are essential in diverse industries, including for producing from by evaporating and condensing across effects, for concentrating juices (e.g., apple, ), products, and soymilk while preserving quality through short exposure to heat, and the for evaporating cane to form prior to using typically five effects. They also find use in chemical plants, industries, and for and volume reduction. Key advantages include reduced —65–75% lower in systems—lower operating costs (e.g., $1.008/m³ for a 12,000 m³/day plant), minimized cooling needs, and for large volumes, making MEEs a cornerstone for efficient thermal separation processes.

Fundamentals

Definition and Purpose

A multiple-effect evaporator is a separation comprising two or more stages, known as effects, arranged in series, where the vapor generated from the liquid in one effect serves as the heating medium for the subsequent effect at a lower , thereby reusing to achieve greater than a single-effect . This sequential allows for the concentration of solutions by evaporating volatile solvents, primarily , while minimizing the consumption of external or heating utilities. The primary purpose of multiple-effect evaporators is to enable large-scale solvent removal in that demand high throughput and low operational costs, such as of to produce potable water or of chemicals from dilute solutions in . In applications, for instance, the system can achieve a performance ratio of up to 16.7 in configurations with 12 effects combined with vapor compression. Similarly, in chemical , it concentrates effluents from process plants. Key components of a multiple-effect evaporator include shell-and-tube heat exchangers, which facilitate the transfer of from vapor to the feed solution; vapor heads that collect and direct the generated vapor to the next effect; and condensate separators that remove liquid condensate from the vapor stream to maintain process purity and . These elements are integrated across the effects to form a compact, modular system adaptable to various scales. The concept originated in the , when inventor developed the multiple-effect evaporator under vacuum in the 1830s and patented it in 1846, initially to improve refining by reducing fuel use and enhancing product quality during the Louisiana boom.

Comparison to Single-Effect Evaporators

In a single-effect evaporator, is supplied to the process fluid in a single stage, where the generated vapor is condensed separately without reuse, resulting in a steam economy of approximately 0.8 to 1 kg of evaporated per kg of supplied. This configuration requires input roughly equal to the evaporation rate, making it straightforward but energy-intensive for continuous operations. Multiple-effect evaporators achieve greater efficiency by reusing the vapor from one effect as the heating medium for the subsequent effect, enabling a theoretical steam economy approaching the number of effects (N), though practical values are typically 0.75N to 0.95N due to heat losses and boiling point elevation. For instance, a four-effect system can evaporate 3 to 3.2 kg of water per kg of steam, compared to about 0.9 kg in a single-effect unit, representing a significant reduction in steam demand. In a five-effect evaporator, the steam required is roughly one-fifth that of a single-effect system for the same evaporation output, potentially saving up to 80% in boiler fuel costs. The high energy costs of single-effect evaporators limit their use primarily to small-scale, batch, or low-capacity processes where outweighs concerns. This vapor reuse mechanism in multiple-effect systems is the primary enabler of these gains, allowing for scalable operations in industries like chemical processing and .

Operating Principles

Heat and Mass Transfer

In multiple-effect evaporators, primarily occurs through convective boiling inside vertical tubes, where the process liquid flows upward or downward while heated by condensing vapor on the tube exterior. This mechanism combines near the tube wall with in the bulk fluid, enhancing the overall rate compared to sensible heating alone. The heat duty Q for each effect is described by the equation Q = U A \Delta T, where U is the overall heat transfer coefficient (typically 1500–2500 W/m²·K for aqueous solutions in clean conditions), A is the heat transfer surface area, and \Delta T is the mean temperature difference between the heating vapor and the boiling liquid. This equation assumes steady-state operation with negligible heat losses, and U accounts for resistances from the condensing vapor film, tube wall, and boiling liquid side, often dominated by the latter in fouling-prone applications. Mass transfer in each effect involves the generation of saturated vapor from the boiling liquid, driven by the heat input. Under the approximation that changes are minor relative to , the vapor generation rate m_v is given by m_v = \frac{Q}{\lambda}, where \lambda is the of vaporization of the at the effect's operating conditions (e.g., approximately 2250 kJ/kg for near 100°C). This relation holds for saturated boiling, where the vapor is in with the liquid, and balances confirm that the vapor produced equals the difference between inlet feed and outlet flows per effect. The thermodynamic driving force across effects relies on a decreasing , with each subsequent effect operating at lower and to enable vapor reuse as the heating medium. For instance, in a quadruple-effect system processing aqueous solutions, temperatures might cascade from 123°C in the first effect (at ~2.2 ) to 67°C in the last (at ~0.27 ), distributing the total available temperature difference (e.g., from at 140°C to vacuum condenser at 40°C) across multiple stages. However, (BPE) due to increasing solute concentration reduces the effective \Delta T in later effects, as the liquid's boiling temperature rises above that of pure at the same . BPE is a function of concentration and properties, often modeled empirically; for NaCl solutions, it follows a near-linear form \Delta T_{bp} = K_b \cdot w for dilute concentrations, where K_b is an effective constant (approximately 17 K per unit mass fraction for dilute NaCl solutions) and w is the solute mass fraction, though breaks down at higher concentrations. In evaporators concentrating NaCl from low salinity (e.g., 20 g/kg, BPE ≈ 0.2°C at 80°C) to near- (e.g., 280 g/kg, BPE up to 11.6°C at 80°C), this elevation can consume 10–20% of the total \Delta T, necessitating design adjustments for accurate performance prediction.

Vapor Reuse Mechanism

In a multiple-effect evaporator, the vapor reuse mechanism enables efficient energy cascading by directing the vapor generated in one effect to act as the heating medium for the subsequent effect. The vapor from effect n-1, produced during the boiling of the feed liquid, flows directly into the steam chest (or heating side) of effect n, where it condenses and releases its latent heat to evaporate more liquid in that effect. This sequential repurposing occurs naturally due to the decreasing pressure profile across the effects, from higher pressure in the first effect to lower pressure (often ) in the last, eliminating the need for external in the basic design. Vacuum pumps are typically used at the final effect to sustain this and remove non-condensable gases, ensuring continuous vapor flow without additional energy input for . The energy balance in this mechanism maintains steady-state operation by equating the heat released from condensing vapor in each effect to the heat absorbed for evaporation in that effect, accounting for minor losses. For the first effect, the incoming live steam mass flow rate m_s and its latent heat \lambda_s satisfy m_s \lambda_s = m_{v1} \lambda_{v1} + Q_{\text{losses}}, where m_{v1} is the vapor mass flow rate from the first effect and \lambda_{v1} its latent heat; this relation extends iteratively to subsequent effects, with the vapor from the prior effect substituting for live steam. This approximate equality, derived from overall enthalpy conservation, highlights how each unit of steam input generates nearly equivalent vapor output per effect, multiplying the overall evaporation capacity relative to single-effect systems. Condensate formed by the condensation of vapor in each steam chest is promptly separated from the vapor space, typically via gravity or simple traps, and either removed from the system or recycled to the feed to avoid losses that would diminish the available temperature driving force for . Proper handling prevents wastage, as subcooled would require additional energy to reheat, thereby preserving the of the vapor reuse process. To mitigate illicit entrainment, where liquid droplets are carried over with the vapor stream—potentially contaminating downstream or reducing purity—demisters such as wire mesh pads or vane-type separators are installed at the vapor outlets of each . These devices capture and return entrained droplets to the boiling liquid, achieving typical separation efficiencies exceeding 99% for droplets larger than 3–5 microns under standard operating velocities.

Feed Configurations

Forward Feed

In the forward feed configuration of a multiple-effect evaporator, fresh feed enters the first effect, which operates at the highest temperature and , and flows sequentially through subsequent effects in the same direction as the generated vapor, becoming progressively more concentrated as it moves to cooler effects under decreasing . This co-current flow pattern allows the vapor produced in each effect to serve as the heating medium for the next, enabling efficient reuse of across the system. A primary advantage of forward feed is its suitability for heat-sensitive materials, such as fruit juices or , where the decreasing prevents thermal degradation of the increasingly concentrated liquor in later effects. The configuration requires minimal temperature difference between effects, facilitating operation with viscous or sensitive liquors while avoiding excessive exposure to high temperatures. Forward feed systems achieve higher capacity at lower temperature differentials per effect, with steam economy improving as the number of effects increases; for instance, a quadruple-effect forward feed evaporator can evaporate approximately 3.5-4 kg of per kg of supplied. In a typical 4-effect setup, the gradual rise in feed reduces the need for additional pumping between effects, enhancing overall process efficiency for applications like juice concentration. Despite these benefits, forward feed requires preheating the incoming feed to near its to prevent or inefficient in the first , making it unsuitable for feeds without auxiliary heating. Additionally, the may exhibit lower economy compared to alternatives in scenarios with highly viscous products, as the concentrated encounters cooler conditions in the final effects, potentially limiting rates.

Backward Feed

In the backward feed configuration of a multiple-effect evaporator, the feed enters the last effect, which operates at the lowest temperature and , and the is then pumped sequentially through the preceding effects toward the first effect, which is the hottest. This establishes a counter-current flow pattern where the moves opposite to the direction of the vapor and heating , resulting in the most concentrated being withdrawn from the hottest effect. Pumps are necessary between each effect to overcome the increasing as the progresses from lower to higher environments. This arrangement provides a higher driving force for in the effects handling the more concentrated , as the viscous material experiences elevated temperatures that reduce its and enhance flow and heat transfer rates. It is particularly advantageous for processing viscous concentrates, where the reduced at higher temperatures improves overall capacity compared to forward feed systems under similar conditions. Additionally, for scaling-prone solutions, the can mitigate by exposing dilute feed to lower temperatures initially, though the high concentration develops in the hotter effects. The across effects, with entering the first and vapor generated cascading to subsequent ones, supports this counter-current operation by maintaining progressive as concentration increases. In terms of capacity and economy, backward feed typically yields a higher evaporation capacity for viscous fluids but similar steam economy to forward feed, though total is higher due to the energy demands of pumping against the ; however, it enables higher final concentrations in applications like evaporation in the , where solids content reaches approximately 65%. The requirement for multiple pumps—one between each pair of effects—increases operational complexity and for liquor transfer, often accounting for a notable portion of the total power input in multi-effect systems.

Parallel Feed

In the parallel feed configuration of a multiple-effect evaporator, the incoming feed is divided equally and introduced simultaneously into each , where it is heated and partially evaporated using the available vapor from the previous or in the first . The vapors generated in each flow sequentially to the heating side of the subsequent , enabling for further , while the resulting concentrates (or ) are collected separately from the bottom of each or sometimes combined downstream for further . This setup maintains a balanced distribution of feed across all , with and temperature gradients occurring independently in each stage rather than progressively through the system. This offers the easiest and among feed types, as it eliminates the need for inter-effect pumping of the feed or , reducing mechanical complexity and energy losses associated with fluid transfer. It is particularly suitable for clean, non-viscous feeds such as in processes, where uniform processing minimizes operational challenges like or pressure drops. The parallel introduction simplifies startup, shutdown, and procedures, making it ideal for systems requiring without sequential dependencies. In terms of capacity and economy, parallel feed provides performance similar to forward feed but with a more balanced load distribution, leading to even rates across effects, as seen in systems combining multiple-effect with multi-stage for enhanced overall . For instance, in plants, this balanced approach can achieve a performance ratio comparable to parallel/cross feed configurations, with specific areas reduced by utilizing higher temperatures, though it may require more cooling water than forward feed setups. Despite these benefits, parallel feed is less efficient for processes involving significant concentration gradients, as the independent evaporation in each effect can lead to suboptimal and higher energy demands compared to sequential configurations. Potential uneven performance arises if variations occur in effect temperatures or feed quality, and the separate collection of concentrates complicates handling and disposal, often requiring additional treatment steps, which limits its standalone use in favor of or specialized applications.

Design Considerations

Number of Effects

The number of effects in a multiple-effect evaporator (MEE) typically ranges from 3 to 8, determined by balancing energy efficiency gains against increased capital investment. Each additional effect reuses vapor from the previous stage as heating steam, enhancing steam economy—defined as kilograms of water evaporated per kilogram of steam supplied—which approaches approximately the number of effects under ideal conditions. For instance, a six-effect system achieves a steam economy of about 4.6–4.9, roughly five times that of a single-effect evaporator (0.75–0.95). However, capital costs rise with the number of effects due to additional heat transfer area and equipment, often scaling roughly linearly per effect while total system cost increases more gradually with factors like N^{0.75}, where N is the number of effects. Diminishing returns limit the practical number of effects, primarily due to (BPE) in concentrated solutions, which reduces the effective temperature difference available for across effects, and heat losses estimated at about 2% of input energy per effect. BPE, caused by dissolved solids raising the boiling temperature, can consume 10–20% of the total in later effects, making further stages less efficient. The overall temperature difference between supply and cooling —typically 40–60°C—further constrains N, as each effect requires a minimum \Delta T of 3–5°C for viable . Optimization of N balances steam savings against area costs through economic models, often approximated by balancing and operating costs. Feed configurations, such as forward or backward feed, may slightly influence the optimal N by affecting concentration profiles and coefficients across effects. Economic analyses in illustrate this trade-off: additional effects yield higher steam economy but increase ; payback periods can be under 5 years when steam prices are high, justifying the through reduced operating expenses. In modern large-scale plants, integration with mechanical vapor compression (MVC) enables 10 or more effects by boosting and recovering additional , achieving gained output ratios up to 15–20 in hybrid MEE-MVC systems while maintaining low specific energy consumption.

Material and Scaling Issues

In multiple-effect evaporators, selection is critical to withstand corrosive environments posed by process fluids such as and . 316, containing 16-18% , 10-14% , and 2-3% , is commonly used for applications due to its enhanced resistance to pitting and chloride-induced . is preferred for highly aggressive conditions, offering superior resistance to pitting, , and in chloride-rich environments up to 260°C. For desalination systems, copper-nickel alloys like 70-30 Cu-Ni provide excellent resistance in and , with failure rates as low as 0.05% in reject sections. Key factors influencing include , temperature, and ; low and high accelerate pitting in stainless steels, while elevated temperatures above 100°C exacerbate general in copper alloys. Scaling in multiple-effect evaporators arises from the deposition of inversely soluble salts, such as (CaSO₄), due to as temperature decreases across effects. This inverse solubility behavior—where solubility declines with rising temperature—promotes and on surfaces, particularly in the later effects where concentrates. Temperature gradients across effects further exacerbate by driving localized and surface deposition. To mitigate scaling, operators employ acid cleaning cycles, typically using sulfuric or to dissolve deposits, alongside chemical antiscalants like polyacrylates dosed at 5-10 ppm to inhibit formation and growth. Design features, such as maintaining tube velocities above 1.5 m/s, promote turbulent flow to nascent crystals and minimize buildup on surfaces. involves periodic descaling, often every 10-15 days in processing, resulting in of 1-2% of annual operating time. In the , untreated scaling can reduce the overall (U) by up to 30%, significantly impairing efficiency.

Applications and Advantages

Industrial Uses

Multiple-effect evaporators are extensively utilized in desalination processes, particularly through multi-effect distillation (MED) systems for treatment. These systems typically employ 8 to 16 effects to achieve high at low operating temperatures below 70°C, enabling capacities ranging from 10,000 to 100,000 m³/day in commercial plants. MED units are frequently integrated in hybrid configurations with (RO) to optimize energy use and water recovery, where low-grade heat from power plants or sources drives the evaporation stages. In the chemical processing industry, multiple-effect evaporators concentrate corrosive solutions such as caustic soda (NaOH) and (HCl). For caustic soda, triple- or quadruple-effect systems using backward feed are common, where the feed enters the last at lower pressure and flows countercurrent to the heating , allowing higher temperatures in the final concentration stage to handle viscosity increases efficiently. Backward feed is particularly suited for HCl concentration due to its corrosive nature, enabling operation with specialized materials like or while minimizing energy input across 4 to 6 effects. The and pharmaceutical sectors rely on multiple-effect evaporators to concentrate heat-sensitive products while preserving . In processing, forward feed configurations with 4 effects are standard for evaporating from about 9% to 50% total solids, as the co-current flow keeps temperatures low (around 50-60°C in later effects) to avoid protein denaturation and flavor changes. Similarly, in pharmaceuticals, forward feed multiple-effect evaporators (often 3-5 effects) concentrate antibiotics and other broths, maintaining gentle conditions to retain bioactivity and comply with sterility requirements. In the , multiple-effect evaporators typically feature five effects to concentrate cane juice to prior to , often employing backward feed to manage increasing effectively. In , multiple-effect evaporators are used for volume reduction and from industrial effluents, often in configurations to enhance . In the , multiple-effect evaporators recover from kraft pulping processes, concentrating it from 15% to 65-70% solids for combustion in recovery boilers. Systems typically feature 5-7 effects in backward feed arrangement, which suits the increasing of the and achieves steam economies of 4-6 kg of water evaporated per kg of consumed, recovering up to 90% of the process energy through vapor reuse. Notable scale examples include large MED plants in the ; for instance, the Al Taweelah plant in , UAE, incorporates MED units contributing to a total capacity exceeding 385,000 m³/day across 10-16 effects, demonstrating the technology's viability for mega-scale water production. In , the Shoaiba plant operates the world's largest single MED facility at 92,000 m³/day with multiple effects, highlighting global deployment for arid regions.

Energy and Cost Efficiency

Multiple-effect evaporators achieve substantial savings compared to single-effect s by reusing vapor from one to heat the subsequent , reducing overall consumption by 70-90% depending on the number of effects. For instance, a four-effect typically requires only about 0.25 kg of per kg of evaporated, in contrast to 1 kg for a single-effect . This is quantified by the gain output ratio (), defined as the mass of distillate produced per unit of heat input; multiple-effect distillation (MED) s commonly achieve a GOR of 8-12, far surpassing the GOR of 1 for single-effect evaporators. Although the capital costs for multiple-effect evaporators are higher than those for single-effect systems due to the need for multiple evaporator shells and associated , the investment typically ranges from $1-2 million per for industrial-scale installations. These upfront costs are offset by significant operating savings from reduced usage, with payback periods generally ranging from 2-5 years through lower consumption and needs. The optimal number of s further influences these savings by balancing incremental against gains. The reduced steam demand in multiple-effect evaporators leads to lower use for steam generation, resulting in decreased CO2 emissions compared to single-effect alternatives. For example, a retrofit in a sugar mill using optimized multiple-effect can achieve approximately 20% annual savings, translating to proportional reductions in CO2 output. In comparison to alternatives, multiple-effect evaporators offer a balanced profile: mechanical vapor compression (MVC) systems have higher but eliminate requirements entirely by using electrical compression, making them suitable for electricity-abundant settings. (RO), meanwhile, consumes less energy overall (typically 3-5 kWh/m³ versus 10-15 kWh/m³ thermal equivalent for MED) but is limited by and inability to handle high-salinity feeds effectively.

References

  1. [1]
    https://dr.lib.iastate.edu/bitstreams/2684df49-92d7-4879-ba79-9e5f4b05e766/download
  2. [2]
    None
    Below is a merged summary of Multiple Effect Evaporation (MEE) based on the provided segments from http://web.mit.edu/~mcyang/www/Fundamentals%20of%20desalination.pdf. To retain all information in a dense and organized manner, I will use a combination of narrative text and tables in CSV format where appropriate (e.g., for detailed operational data, performance metrics, and configurations). The response avoids redundancy while ensuring all key details are included.
  3. [3]
    [PDF] AP-42, Section 9.10.1.1: Sugarcane Processing
    Evaporator stations consist of a series of evaporators, termed multiple-effect evaporators; typically a series of five evaporators. Steam from large boilers is ...
  4. [4]
    [PDF] Optimization of multiple-effect evaporators using exergy and pinch ...
    The main objective of this thesis is to find an optimum for a multiple-effect evaporation system in a sugar manufactory. The system is modeled using ...
  5. [5]
    [PDF] APV Evaporator Hndbook
    In particular, the system is used as a finishing evaporator to concentrate materials to high solids following a low solids multi-effect or MVR film evaporator.
  6. [6]
    Multi-Effect Evaporation - an overview | ScienceDirect Topics
    Multi-effect evaporation (MEE) desalination is a process in which heat from the steam is used for evaporating the salinity water in a sequence of evaporators or ...
  7. [7]
    https://www.sciencedirect.com/science/article/pii/S0011916422005367
  8. [8]
    https://www.sciencedirect.com/science/article/pii/B9780080999685000131
  9. [9]
    Norbert Rillieux - American Chemical Society
    Norbert Rillieux (1806-1894) revolutionized sugar processing with the invention of the Multiple Effect Evaporator under Vacuum. Rillieux's great scientific ...Norbert Rillieux: Chemist and... · Sugar Production and the...Missing: 19th | Show results with:19th
  10. [10]
    [PDF] The Essentials of Continuous Evaporation - AIChE
    A multiple-effect evaporator uses the water vapor from one effect as the heating medium for the next effect, which oper- ates at a lower boiling point. The ...
  11. [11]
    None
    ### Summary of Key Comparisons Between Single-Effect and Multiple-Effect Evaporators
  12. [12]
    [PDF] Heat Transfer - Evaporation - MSubbu
    Sep 25, 2019 · The economy of a single effect evaporator is always less than 1.0. Multiple effect evaporators have higher economy but lower capacity than ...Missing: efficiency comparison
  13. [13]
    [PDF] PROC 5071: Process Equipment Design I
    Heat transfer is attained by operating the sec- ond evaporator at a lower pressure than the first one.
  14. [14]
    [PDF] Chapter 10: Boiling Heat Transfer Inside Plain Tubes
    Flow boiling models normally consider two heat transfer mechanisms to be important: nucleate boiling heat transfer (αnb) and convective boiling heat transfer ( ...
  15. [15]
    None
    ### Summary of Heat Transfer and Mass Transfer Content
  16. [16]
    [PDF] Optimization of a multiple Effect Evaporator System - ethesis
    Evaporators are kind of heat transfer equipments where the transfer mechanism is controlled by natural convection or forced convection. A solution containing a ...<|control11|><|separator|>
  17. [17]
    [PDF] Number of Transfer Units Relationship for Evaporators With Non
    Such a linearization overpredicts the BPE of NaCl solutions by no more than 0.47 K when the curve is linearized from zero to saturation salinities.
  18. [18]
    [PDF] High salinity seawater boiling point elevation: experimental verification
    As a first approximation, boiling point elevations for pure sodium chloride solutions are useful for comparison with data for seawater and salt mixtures ...
  19. [19]
    [PDF] Multiple Effect Evaporator System - NPTEL Archive
    They are equal to 6N+6[=N+6+5N]. Mathematical model: A mathematical model of a multiple effect evaporator is a relationship amongst the geometrical, operating ...
  20. [20]
    https://archive.nptel.ac.in/content/storage2/courses/103107096/module4/lecture2/lecture2.pdf
  21. [21]
    Investigating droplet separation efficiency in wire-mesh mist ...
    Apr 14, 2010 · The removal efficiency was found to increase with the increasing the demister specific surface area, packing density, and superficial gas velocity.Missing: multiple | Show results with:multiple
  22. [22]
    [PDF] Dairy Process Engineering | AgriMoon
    For a multiple – effect evaporator system calculations, the values ... In a forward feed system, the flow of process fluids and of steam are parallel.
  23. [23]
    https://agrimoon.com/wp-content/uploads/Dairy-Process-Engineering-1.0.pdf
  24. [24]
    https://eagri.org/eagri50/AENG252/lec19.html
  25. [25]
    Multiple Effect Evaporator: Forward Feed, Backward Feed, Parallel ...
    May 12, 2023 · A multiple effect evaporator is an apparatus that efficiently uses the heat from steam to evaporate water; · In a multiple effect evaporator, ...
  26. [26]
    multi-effect-evaporators-summary - LearnChemE
    Backward feed might be used if the feed is cold or if the feed becomes viscous so that the more viscous solution is at the higher temperature.
  27. [27]
    None
    Below is a merged summary of "Backward Feed" in Multiple Effect Evaporators based on the provided segments from the *Handbook of Evaporation Technology*. To retain all information in a dense and organized manner, I will use a combination of narrative text and a table in CSV format for detailed comparisons. The narrative will provide an overview, while the table will capture specific details across all segments, including variations in descriptions, advantages, disadvantages, and examples.
  28. [28]
    Multi Effect Evaportaors Fouling And Scaling - Klaren Technology
    Multiple Effect Evaporator (MEE) is a system consists of a sequence of heat exchangers – VLSs (vapor-liquid separators) used widely for many applications ...
  29. [29]
    [PDF] 3.2-1 Black Liquor Evaporators: Design and Operation - TAPPI.org
    Multiple effect evaporators (MEEs) are always used in black liquor service. The term multiple effect comes from the multiple effective use of energy to perform ...
  30. [30]
    https://www.tappi.org/content/events/08kros/manuscripts/3-2.pdf
  31. [31]
    https://doi.org/10.1016/S1359-4311(99)00098-8
  32. [32]
    [PDF] Chapter 5 Multiple Effect Evaporation Vapor Compression
    The parallel feed multiple effect evaporation is the industrial standard for seawater desalination using the multiple effect evaporation process. The ...
  33. [33]
    The Essentials of Continuous Evaporation - AIChE
    A multiple-effect evaporator uses the water vapor from one effect as the heating medium for the next effect, which operates at a lower boiling point. The latent ...
  34. [34]
    Multieffect Evaporator - an overview | ScienceDirect Topics
    The advantage of the multieffect evaporator system is a lower energy consumption, while its individual efficiency is lower than a single-effect system.
  35. [35]
    Multiple Effect Evaporators - Swenson Technology
    Multiple-effect configurations combine two or more evaporator bodies to conserve steam, which is condensed in the first-effect heat exchanger only.
  36. [36]
    [PDF] Thermoeconomic analysis of a low-temperature multi-effect thermal ...
    This study presents a thermal and economic performance analysis of a low-temperature multi-effect evaporation water desalination system (LT-MEE) integrated with ...
  37. [37]
    Mechanical vapor compression desalination technology – A review
    This work provides a review for the research investigations made in single and multi-effect desalination systems operated by mechanical vapor compressors.
  38. [38]
    [PDF] STAINLESS STEELS FOR EVAPORATORS/ CONCENTRATORS
    Stainless steels have been and will continue to be used extensively in evaporator systems in many indus- tries. They provide excellent resistance to corrosion ...
  39. [39]
    Influences of multi-factors on Corrosion Resistance of TA2 pure ...
    Considering the hash corrosion environment in brine, titanium and its alloy are widely used in the pipes and evaporators.
  40. [40]
    Cu-Ni Alloys in Desalination Systems - Copper.org
    The Cu-Ni alloys have a combination of properties, such as corrosion resistance, fabricability and mechanical properties which meet the needs of MSF plants.Copper-Nickel Alloys In... · Copper Alloys In Deaerated... · Copper Alloys In...
  41. [41]
    Effect of seawater salinity, pH, and temperature on external ... - Nature
    Jul 17, 2024 · This research aims to investigate the effects of seawater parameters like salinity, pH, and temperature on the external corrosion behaviour and microhardness
  42. [42]
    [PDF] Common Foulants in Desalination: Inorganic Salts
    Common scales encountered include calcium carbonate, calcium sulfate, silica, metal silicates, oxides/hydroxides of aluminium, iron and manganese. Other less ...
  43. [43]
    Scaling in multiple-effect distillers: The role of CO2 release
    Aug 9, 2025 · Scale formation in seawater distillers is mainly caused by crystallization of the inversely soluble salts calcium carbonate, ...
  44. [44]
    Antiscalant - an overview | ScienceDirect Topics
    The A/S dosage ranges between 2 and 10 ppm, depending on the scale-forming potential of the RO feed water, product water recovery, and A/S manufacturer's ...
  45. [45]
    Enhancement of Polyacrylate Antiscalant Activity during Gypsum ...
    The present report is dedicated to the unconventional application of spruce wood shavings in combination with polyacrylate (PAA-F1) in a model case of gypsum ...
  46. [46]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC10573910/
  47. [47]
    WO2003106735A2 - Method for scale removal - Google Patents
    [0004] Because of the formation of scale, evaporator bodies are cleaned about every 10-15 days. Typically they are cleaned with caustic soda and sometimes some ...
  48. [48]
    [PDF] The effect of scaling on heat transfer in a first-effect falling-film ...
    The paper provides an insight into the operation of a first-effect falling-film evaporator in a cane sugar factory. Keywords: falling-film evaporators, heat- ...
  49. [49]
    Multiple Effect Distillation (MED) - Veolia Water Technologies
    A Multi Effect Desalination MED unit is an evaporator where sea water is evaporated in one or more ( up to 14 ) evaporation stages at low temperature (< 70°C )Missing: 6-12 capacity 10000-100000 hybrid
  50. [50]
    Multiple Effect Distillation - an overview | ScienceDirect Topics
    Each of the Sharjah's two MED distillation plants in the UAE has a capacity of 22,700 m3/day. In addition, a module with capacity of 45,400 m3/day has been ...Missing: largest | Show results with:largest
  51. [51]
    A techno-economic review of multi effect desalination systems ...
    Feb 25, 2021 · The economic results of that study showed that the Simple Payback (SPB) time for. PTC used as thermal source of the MED desalination unit.
  52. [52]
    [PDF] Computer Aided Simulation of Multiple Effect Evaporator for ...
    Oct 29, 2020 · But for practical feed condition of dilute caustic soda stored at room temperature, the backward feed simulation finds more relevance in this.Missing: HCl | Show results with:HCl
  53. [53]
    Simulation of a triple effect evaporator of a solution of caustic soda ...
    Apr 6, 2018 · This work focuses on using and validating the model of a triple effect evaporator in Aspen Plus using plant data.Missing: HCl | Show results with:HCl
  54. [54]
    Product Concentration Evaporator Plant - Ketav Consultant
    In stockThis plant is extensively used in chemical industry for the concentration of hydrochloric acid, nitric acid, sulfuric acid, dextrose etc.
  55. [55]
    Multiple Effect Evaporator - Agitated Thin Film ... - Ketav Consultant
    ... Concentration Evaporation Plant and our product is made up of good quality. It can concentrate different products as below:- H2So4 Concentration; HCL ...
  56. [56]
    Evaporators | Dairy Processing Handbook - Tetra Pak
    To reduce the amount of steam needed, the evaporator is normally designed as a multiple-effect evaporator. Two or more effects operate at progressively lower ...
  57. [57]
    [PDF] Technews - Dairy Knowledge Portal
    In a typical case where milk of 14% total solids is concentrated in a 4-effect evaporator to 50% solids, and then dried to 3% moisture in a single stage ...Missing: forward | Show results with:forward
  58. [58]
    Multi-Effect Evaporators Market Size, Report by 2034
    Oct 2, 2025 · Multi-effect evaporator systems are increasingly being used in wastewater treatment, chemical, food and beverage, and pharmaceutical industries.
  59. [59]
    (PDF) Improving the Efficiency of Multiple Effect Evaporator to Treat ...
    Dec 27, 2014 · The pharmaceutical industry of the study uses multiple effect falling and forced circulation evaporator to achieve zero liquid discharge process ...Missing: forward | Show results with:forward
  60. [60]
    [PDF] Design of Black Liquor Multiple Evaporator System Effect Feed and ...
    backward feed multiple effect evaporator. 1. Ray, A.K. and Singh Pitam. IPPTA Vol. 12. NO.3 . . (July-Sept, 2000). •. 2. Ray, A.K., Ph.D. Thesis "University ...
  61. [61]
    [PDF] Evaporator and Recovery Boiler Energy Efficiency - Valmet
    Evaporators are the largest energy users in a Kraft pulp mill. Upgrading older evaporators and increasing recovery boiler efficiency can achieve significant ...Missing: backward | Show results with:backward
  62. [62]
    [PDF] energy analysis of a kraft pulp mill - Princeton University
    The weak black liquor is concentrated to approximately. 70% solids content in a five-effect rising film evaporator and a 3-body concentrator. During normal mill ...
  63. [63]
    [PDF] Breakthrough of MED Technology in Very Large Scale Applications ...
    The new MED plant is designed to produce 52.78 MIGD. The overall AL TAWEELAH-A1 desalination capacity will become 84.78 MIGD or 385,410 m3/day. After ...
  64. [64]
    Largest multi-effect distillation water desalination plant (capacity)
    The largest multi-effect distillation water desalination plant has a capacity of 92,000 cubic meters per day, achieved by SWCC in Shoaiba, Saudi Arabia.Missing: MED UAE effects
  65. [65]
    Gain Output Ratio - an overview | ScienceDirect Topics
    Gain Output Ratio (GOR) is the ratio of latent heat of vaporization to energy input, indicating energy efficiency for water production.
  66. [66]
    [PDF] ETHANOL INDUSTRY - Focus on Energy
    Economic benefit. Two to four-year payback with an estimated cost of $1 to $2 million. Energy savings. Reduced steam usage at beer preheater due to increased ...
  67. [67]
    Energy saving in sugar manufacturing through the integration of ...
    A sugar factory retrofit often includes improvements in the factory's energy system comprising power plant, multiple-effect evaporator and process heating ...
  68. [68]
    Model and Optimisation of a Multi-Effect Evaporator of Sugarcane ...
    Pinch analysis identified a potential 20% reduction in energy consumption through optimized vapour usage. Inversion losses due to temperature and pH variations ...
  69. [69]
    Vapor Compression Distillation vs. Multiple Effect Distillation - MECO
    Oct 28, 2024 · Comparing Vapor Compression versus Multiple Effect Distillation requires an understanding of the two processes and how they differ in their approaches.Missing: 4 | Show results with:4
  70. [70]
    [PDF] Environmental Impact Cost Analysis of Multi-Stage Flash, Multi ...
    The objective of this research is to compare four different desalination methods operating at a production capacity between 100 and 200 m3/d: 1) multi-stage ...