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    • 专利摘要:
    Zero liquid discharge treatment process to recover water from a contaminated liquid effluent for subsequent reuse. The ZLD treatment process of the invention includes at least: a) a desalination stage: with advanced reverse osmosis treatment with a high degree of recovery, several periodic cleanings are carried out, bringing the surface of the membranes into contact with water with a lower content of dissolved salts than the water to be treated; b) a concentration stage: the rejection of the first stage is concentrated by applying vibratory osmosis, direct osmosis or humidification-dehumidification; c) a zero liquid discharge stage that acts as a crystallizer or an evapo-crystallizer: the liquid effluent is around the saturation point at which the precipitation of the present salts begins to occur, recovering the rejection water by evaporation. the concentration stage and producing a stream of solids. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2754898A2
    申请号:ES201930814
    申请日:2019-09-20
    公开日:2020-04-20
    发明作者:Garcia Ignacio Martin;Portillo Pere Camprovin;Benoît Lefèvre;Portugal Belinda Gomez
    申请人:Suez Groupe SAS;
    IPC主号:
    专利说明:

    [0001]
    [0002] Zero liquid discharge treatment process to recover water from a contaminated liquid effluent for later reuse
    [0003]
    [0004] Technological field
    [0005] The present application refers to a zero discharge of liquids in which it is possible to recover almost all the water from a contaminated liquid effluent for reuse, avoiding complete or partial discharge. The process gradually reduces the volume of the liquid effluent and concentrates the contaminants until reaching the last stage of the treatment. A stream of decontaminated water and a solid residue are obtained in which all contaminants are concentrated.
    [0006]
    [0007] Background of the Art
    [0008] Freshwater scarcity, one of the most critical global challenges of our time, represents a major threat to economic growth, water security and the health of ecosystems. The challenge of providing adequate and safe drinking water is further complicated by climate change and the pressures of economic development and industrialization. The public and industrial sectors consume substantial amounts of fresh water while producing large amounts of wastewater. If not properly treated, the discharge of wastewater into the aquatic environment causes serious pollution that adversely affects aquatic ecosystems and public health.
    [0009]
    [0010] Wastewater recovery and recycling has become an increasing trend in the last decade due to the increasing demand for water. Reusing wastewater not only minimizes the volume and environmental risk of discharged wastewater, but also relieves the pressure on ecosystems that results from the extraction of fresh water. Through reuse, wastewater is no longer considered a "pure waste" that potentially damages the environment, but rather an additional resource that can be harnessed to achieve water sustainability. The zero liquid discharge (ZLD, of the zero English liquid discharge) is an ambitious strategy wastewater management that eliminates any liquid residue out of a plant or the limits of a plant, and most of the water is recovered for its reuse. The ZLD avoids the risk of contamination associated with the discharge of wastewater and maximizes the efficiency of water use, thus achieving a balance between the exploitation of water resources. fresh water and the preservation of aquatic environments.
    [0011]
    [0012] A zero liquid discharge (ZLD) installation can be defined as an installation in which there is no discharge of effluents into the environment or they are not disposed of by conventional means, such as discharge into the sewage system. Zero liquid discharge plants use effluent treatment technologies that condition all effluents for reuse, either for landscape irrigation or to replace conventional water supplies in an industrial process. The reuse of effluents reduces, as mentioned above, the demand for fresh water.
    [0013]
    [0014] Technologies present in ZLD-type facilities include sedimentation, dissolved air flotation, media filtration, activated carbon filtration, ultrafiltration, and reverse osmosis. The technologies to be used vary widely depending on the case. For example, in the power generation industry, effluents with large amounts of salts generally require an evaporation step, which separates solid waste to deposit it in landfill areas. Evaporation produces clean water for reuse in cooling or other processes.
    [0015]
    [0016] Mining is another of the industries that can benefit from the ZLD facilities for the treatment of its effluents, since the raw effluents from mining are acidic and extremely saline, and often contain a large amount of sediment. An example of a treatment plant in the mining industry that has been disclosed is the one that was implemented in the Collahuasi copper mine, whose effluent treatment plant was dimensioned to treat a flow rate of 216 m3 / h , approximately 5 million liters per day.
    [0017]
    [0018] The facility uses a number of treatments, including sedimentation, dissolved air flotation, media filtration, activated carbon filtration, ultrafiltration, and reverse osmosis. The removal of as much sediment as possible from the water is particularly important. In this way, the company's infrastructure investment is protected by preventing fouling (by the term fouling, all phenomena related to fouling of the membranes are referred to) or other damage to the membranes and other type of equipment. In the sedimentation process, suspended solids are deposited by the force of gravity. Thereafter, dissolved air flotation allows the removal of various colloidal materials and dispersed particles.
    [0019] In this stage, the water is filtered to remove the solids that still remain in it after the flotation stage. The removal of dissolved organic material is completed by filtration with activated carbon, followed by ultrafiltration. This last step ensures the removal of suspended residual solids, colloids, and organic matter, including bacteria and viruses, before the water is treated by reverse osmosis. The final polishing step in the water treatment process is reverse osmosis desalination, which ensures that dissolved salts and heavy metals are removed from the water before reuse.
    [0020]
    [0021] Other industries that represent a real challenge are those in which copper flash smelting is carried out, where the dust produced during copper flash smelting needs to be treated. The powder is currently recirculated to the flash type furnace, resulting in an accumulation of impurities in the circuit that can exceed the limit of the amount of impurities in the feed concentrate established to guarantee the quality of the final product (for example, cathodes ). By treating the dust, the main impurities will be purged from the circuit, resulting in the processing of concentrates with many more impurities (complex concentrates). But the effluents produced in the processing of these "complex" concentrates will contain far more impurities than those found in today's concentrates.
    [0022]
    [0023] Industries in which copper flash smelting is carried out generally have a weak acid treatment plant and a wastewater treatment plant, but are currently unable to stop or reduce this increase in impurities. Therefore, to treat concentrates with more impurities, the factory's wastewater treatment system must be upgraded.
    [0024]
    [0025] In relation to this, in May 2015, the environmental authorities of the Andalusian Government published new effluent limits for discharges, with stricter regulations for selenium (less than 0.1 mg / l for all discharges into the environment) and for cadmium (less than 0.012) mg / l). Meanwhile, the European Water Framework Directive 2000/60 / EC, which is a European directive that commits the member states of the European Union to achieve a good qualitative and quantitative status of all water bodies, published a list of Priority substances identified as dangerous to be removed from discharges before 2020. Mercury, cadmium, lead and their compounds are included in this list. All this will be discussed with the government for the new Environmental Authorization. Integrated (AAI).
    [0026]
    [0027] In order to comply with these regulations and control future increases in impurities, and be prepared for potentially more restrictive discharge limits, not to mention the reduction of discharges to the river by recycling most of this stream, the need to incorporate as part from wastewater treatment a new stage specially designed for the removal of selenium.
    [0028]
    [0029] Explanation of the invention
    [0030] The conventional physicochemical process does not eliminate selenium species, therefore a second stage is required for an alternative treatment method such as iron co-precipitation, biological reduction, or zero liquid discharge (ZLD) processes to achieve elimination goals . Of these alternatives, ZLD processes are considered ideal because they reduce the liquid discharged into the environment and allow maximum water recovery.
    [0031]
    [0032] The first ZLD systems were based on independent thermal processes, where wastewater was normally evaporated in a brine concentrator followed by a brine crystallizer or an evaporation pond. The condensed distilled water in ZLD systems is collected for reuse, while the produced solids are either sent to a public landfill or recovered as valuable salt by-products.
    [0033]
    [0034] However, it should be mentioned that a ZLD process is generally characterized by its intensive use of energy and its high cost. Conventional ZLD systems, which have been in successful operation for 40 years and are still under construction, require a considerable amount of energy and capital. As a result, the ZLD has long been considered unfeasible and has been applied only in limited cases.
    [0035]
    [0036] Therefore, the present invention aims to provide a ZLD process to solve the problems related to the species to be eliminated, and also, that it can be versatile to be applicable to other industries and environments.
    [0037]
    [0038] Reverse Osmosis (RO), a membrane-based technology widely used in desalination, was considered to be incorporated into ZLD systems to improve energy and economic efficiency. However, reverse osmosis, although it is much more energy efficient than thermal evaporation, can only be applied to feed water with a limited salinity range.
    [0039]
    [0040] The inventors piloted conventional ZLD alternatives to treat both the final effluents from a wastewater treatment plant and a weak acid plant, resulting in a process that was costly and ineffective due to the heterogeneity of the two. currents.
    [0041]
    [0042] Conversely, some non-thermal processes showed promising results, underscoring the need for recovery enhancement technologies for the copper industrial process, i.e. in this operating environment, and to provide an economically viable solution.
    [0043]
    [0044] Therefore, zero liquid discharge according to the invention includes other technologies such as advanced RO, direct osmosis (DO), membrane distillation, humidification-dehumidification and alternative evaporators.
    [0045]
    [0046] The zero liquid discharge treatment process object of the present invention, which has been represented in Fig. 1, comprises the following steps:
    [0047] - a first stage of desalination by advanced reverse osmosis (high degree of recovery): a reverse osmosis treatment in which the precipitation of salts is avoided, which limits the degree of recovery, applying periodic cleanings in which the surface of the membranes is puts in contact with more diluted water in dissolved salts;
    [0048] - a second concentration stage: the rejection of reverse osmosis is concentrated between the application, as the case may be, of one of the following technologies: vibratory osmosis, direct osmosis, or humidification - dehumidification; and
    [0049] - a third stage of zero liquid discharge that acts as a crystallizer: in the previous stages of the process, the liquid effluent has been concentrated to the maximum, being around the saturation point at which precipitation of the salts that are present begins to occur mostly in the liquid effluent. The zero liquid discharge stage acts as a crystallizer, recovering the reject water from the concentration stage by evaporation and producing a stream of solids.
    [0050]
    [0051] Therefore, the ZLD treatment process according to the invention comprises the three stages associated previously mentioned, respectively, desalination, concentration and evaporation-crystallization, placed in series and where the concentrate from each stage is introduced into the next stage.
    [0052]
    [0053] Most of the ZLD processes on the market consist of an evaporator followed by a crystallizer. In evaporators, the volume of the liquid effluent is reduced by evaporation, obtaining a water condensate. In crystallizers, the contaminants present in the liquid effluent precipitate with the solids. However, single stage evaporation-crystallization ZLD processes are characterized by high investment and operating costs.
    [0054]
    [0055] The ZLD treatment process according to the invention has a higher economic viability than those of zero discharge processes because it includes an intermediate concentration stage (second stage) to further reduce the volume of the desalination stage (the first stage of the advanced reverse osmosis) prior to the evaporation and crystallization stage (third stage).
    [0056]
    [0057] Although the ZLD holds great promise in reducing water pollution and increasing water supply, its viability is determined by a balance between the benefits associated with ZLD, energy consumption, and capital / operating costs. Incorporation of these technologies in the first and second stages of the ZLD treatment process of the invention results in reduced energy consumption and associated costs, and expansion of ZLD applicability. The application of the treatment process of the invention has achieved the following advantages:
    [0058] - Reductions of at least 50% of all costs
    [0059] - Facilitate the processing of complex concentrates: the treatment of complex concentrates will not be possible without secondary treatment of the overflow of the wastewater treatment plant, due to the increased impurities in the water effluent produced by the impurities of the complex concentrates .
    [0060] - Reduction of discharge by 99%, and reduction of fresh water required for the process by 39%. Currently, the process requires 7 m3 of fresh water per ton of copper metal produced, of which 2.6 m3 (90 m3 / h) is discharged to a local river.
    [0061] - Comply with the administration's discharge requirements regarding the composition of the effluent (for selenium, less than 0.1 mg / l, and for cadmium, less than 0.012 mg / l).
    [0062] Two advanced osmosis systems are considered for the first stage of desalination in the present invention:
    [0063] - closed-loop desalination: a single-stage osmosis system that operates in production and purge cycles. In production cycles, the liquid effluent is concentrated over time while the water is produced. Once the concentrated liquid effluent has reached a predetermined salinity, it is purged and cleaned with the same liquid effluent with a lower concentration of salts. With this periodic cleaning system, the salts are not given time to precipitate.
    [0064] - a flow reversal: a two or three stage osmosis system with continuous operation, but periodically alternating the different stages with each other: from time to time the last stage in which the concentration of salts and, therefore, the potential of The precipitation, which is greater, is exchanged with the first stage by means of a valve system that treats the liquid effluent of lower concentration. In this way, the formation of precipitates is also avoided, and the degree of recovery is increased.
    [0065]
    [0066] Regarding the technologies that can be selected to carry out the second concentration stage according to the process of the invention, the following applies:
    [0067] - Vibratory osmosis: osmosis stage that incorporates vibratory membranes that manage to recover water and concentrate the rejection of the previous stage with high solids content and high potential for the formation of precipitates.
    [0068] - Direct osmosis: stage that uses direct osmosis membranes to concentrate the rejection with a solids content and a moderate potential for precipitate formation. In direct osmosis, the water goes from the rejection of the previous stage to a solution of higher salinity due to the osmotic pressure difference.
    [0069] - Humidification - dehumidification: stage in which hot air comes into contact with the rejection of the previous stage. During this contact, the rejection is concentrated by passing water from it to the hot air. In the dehumidification stage the hot air is cooled by condensing the decontaminated water. Concentration through humidification-dehumidification is a variant to be used in cases where there is the possibility of using residual heat sources from another process or heat from renewable energies.
    [0070]
    [0071] Brief description of the drawings
    [0072] In order to better understand the subject matter disclosed herein and exemplify how it can be carried out in practice, an embodiment will now be described by way of non-limiting examples only, with reference to the accompanying drawings, in which :
    [0073] Fig. 1 is a schematic of the ZLD treatment process of the present invention; and
    [0074] Fig. 2 is a schematic view of a system for performing the ZLD treatment process in accordance with the present invention.
    [0075]
    [0076] Detailed description of the invention and drawings
    [0077] The zero liquid discharge treatment process object of the present invention, which has been schematically represented in Fig. 1, mainly comprises three stages: 1) a first stage of advanced reverse osmosis desalination; 2) a second stage of concentration applying one of the technologies of the group formed by vibratory osmosis, direct osmosis and humidification-dehumidification; and 3) a third stage of evaporation-crystallization. See Fig. 2 for a general scheme of a system for performing the zero liquid discharge treatment process of the invention.
    [0078]
    [0079] 1) First stage of desalination by advanced reverse osmosis (high degree of recovery).
    [0080] It consists of a reverse osmosis treatment in which the precipitation of salts is avoided, which limits the degree of recovery, applying periodic cleanings in which the surface of the membranes is brought into contact with more diluted water in dissolved salts. Two advanced osmosis systems are considered: a) Closed-loop desalination, and b) Flow reversal.
    [0081]
    [0082] 1a) Desalination of closed circuit:
    [0083] It consists of a single stage osmosis system that operates in production and purge cycles. In production cycles, the liquid effluent is concentrated over time while the water is produced. Once the concentrated liquid effluent has reached a predetermined salinity, it is purged and cleaned with the same liquid effluent with a lower concentration of salts. With this periodic cleaning system, the salts are not given time to precipitate.
    [0084]
    [0085] It can be carried out using closed circuit desalination reverse osmosis (CCD-RO) technology that targets high recovery of permeated with low power consumption, which is achieved by using a reverse osmosis that works by recirculating pressurized feed water back to the membrane system while producing a low salinity effluent. The concentrate stream can be recirculated until a certain recovery rate (up to 98%) is reached, then the brine within the recirculation circuit is discarded and replaced by feed water.
    [0086]
    [0087] It has been found that one of the optimal ways to carry out closed-loop desalination is in the ReFlex RO systems from the company Desalitech, Inc. Desalitech's ReFlex RO systems with Closed Circuit Desalination desalination technology ( CCD ™) reduce brine waste by up to 75% and energy consumption by up to 35% compared to traditional RO designs. A ReFlex RO system is a reverse osmosis system consisting of commercial equipment that includes membranes and featuring Desalitech's advanced and proprietary process design and engineering.
    [0088]
    [0089] Desalitech ReFlex products work by recirculating pressurized feed water to the desired recovery level. The brine is replaced with fresh feed water without stopping the feed flow or pressurized permeate. The low initial pressure of each CCD ™ sequence means a lower average operating pressure and less pumping energy than that required in traditional RO systems. ReFlex RO systems achieve recovery by recirculation, not with multiple membrane elements and stages in series, and therefore can achieve any desired recovery percentage in a single stage. Over 97% has been demonstrated, limited only by the fouling characteristics of pretreated feed water. Recovery is adjustable on the system control panel, providing unmatched flexibility. The cross flow supplied by a circulation pump washes the membrane and the salinity cycles interrupt and greatly reduce fouling and dirt. Cycle times are shorter than the induction time for scale deposition and frequent and complete brine rejection can stop and even reverse precipitation, making very high recovery rates possible even from waters of difficult origins. Short membrane matrices and high cross flow also allow ReFlex systems to operate at higher average flow rates without exceeding the flow or recovery specifications of the membrane manufacturer. More than five years of continuous operation in commercial facilities has demonstrated that products
    [0090]
    [0091]
    [0092] ReFlex are reliable.
    [0093]
    [0094] This form of operation with cross flow reverse osmosis membranes is highly efficient and flexible as a simple filtration device. Like any simple filter device, these CCD-RO systems feature equal feed and permeate flow rates during normal operating mode. At a computer-based setpoint, the system automatically removes all of the concentrate and then returns to its normal operating mode. The discharge is activated by the CCD-RO operating software, based on any combination of flow, concentration, pressure and additional set points. During the concentrate removal stage, the system continues to feed and generate permeate, while the concentrate is flushed out of the system.
    [0095]
    [0096] The CCD-RO system has the following advantages:
    [0097] . The resulting average membrane feed pressure is claimed to be lower than the operating pressure of conventional RO systems. As a result, energy consumption is reduced by up to 35 % and the brine flow is reduced by 50-75% compared to a conventional RO system.
    [0098] . Due to the relatively high cross flow rate and short container length, a more uniform RO element flow is achieved, reducing fouling at the front of the system. Periodic dumping of concentrates reduces fouling tendencies within the RO elements at the end of the system, allowing the system to operate more efficiently.
    [0099]
    [0100] 1b) Flow reversal:
    [0101] Among the flow reversal techniques available, the one developed by the company Rotec Ltd. consists of a reverse osmosis (RO) desalination system that avoids the incrustation of minerals on the surface of the membranes and pipes of the water treatment system. water by applying flow reversal (IR) technology, in which the feed flow direction is periodically reversed to mitigate scale formation because scale does not have time to form on membrane surfaces before being swept by conditions of subsaturated feeding solution. This is a two or three stage osmosis system with continuous operation but that periodically alternates the different stages with each other: from time to time the last stage in which the concentration of salts and, therefore, the potential for precipitation, are higher , it goes exchanging with the first stage through a valve system that treats the liquid effluent of lower concentration. This also avoids giving time to the formation of precipitates and increases the degree of recovery.
    [0102]
    [0103] This process for preventing scale fouling on membrane surfaces works by periodically changing the direction of flow in the RO pressure vessel matrices. The frequency of change is determined by the time it takes for a supersaturated solution in the concentrate to grow a population of scale particles that can allow continuous growth of the scale (denoted "Induction Time"). By utilizing the effectively subsaturated feed to remove initial scale particles in the concentrate before they exceed a critical size, extensive precipitation is prevented. As a consequence, the system can achieve higher recoveries. The flow reversal principle is based on the fact that during filtration, the feed flow and the brine flow are changed before the supersaturated solutions can precipitate from the concentrate onto the membrane.
    [0104]
    [0105] 2) Concentration stage:
    [0106] Rejection of reverse osmosis is concentrated by applying, as the case may be, one of the following technologies: vibratory osmosis, direct osmosis, and humidification-dehumidification
    [0107]
    [0108] 2a) Vibratory osmosis : Osmosis stage that incorporates vibratory membranes that manage to recover water and concentrate the rejection of the previous stage with high solids content and high potential for precipitate formation.
    [0109]
    [0110] Among all the possibilities available, an optimal way to implement vibratory osmosis according to this stage is through the use of membranes in accordance with the Vibratory Shear Enhanced Processing (VSEP ) technology developed by the company New Logic. Research, Inc., which are made of various polymers such as polyethersulfone, polyamides, and other thin film compounds. VSEP systems typically employ more than 200 different types of membranes. Vibration is applied to the membranes to prevent precipitation of fouling agents. By doing so, it is possible to increase recovery efficiency. VSEP uses the same thin-film polymeric membranes found in spiral RO membrane systems, but they develop in a different way. The Membranes are attached to evenly spaced discs that wrap around a spacer. By scrolling approximately 54 times per second, VSEP can achieve up to 90% recovery in a single pass. By arranging VSEP systems in series, recoveries greater than 99% can be achieved. VSEP helps comply with discharge guidelines, recycles water, and improves the mine economy.
    [0111]
    [0112] There are main features and benefits built into VSEP. Its vibratory shear action produces high filtration rates at separations ranging from low molecular weights up to 30 microns. The feed suspension in a VSEP system can be extremely viscous (up to 70% solids) and still be processed successfully. The way it works is simple. As the elements of the membrane sheet vibrate vigorously, the shear waves produced cause solids and liquids to repel each other and liquid to flow through the membrane pores unhindered. The shear rate at the membrane surface is approximately 150,000 inverse seconds, literally ten times greater than the rates that can be obtained in cross flow filtration systems. The system achieves high energy efficiency by applying the shear in a thin area near the filter surface. Additionally, a VSEP system that takes up only 20 square feet (1.86 square meters) of floor space can support up to 1500 square feet (139.35 square meters) of membrane area and do the work of a system from 10 to 100 times bigger. The system is also modular for easy expansion and its installation is no more complicated than the installation of a pump.
    [0113]
    [0114] 2b) Direct osmosis: Stage that uses direct osmosis (DO) membranes to concentrate the rejection with a solids content and a potential for the formation of moderate precipitate. In direct osmosis, the water goes from rejecting the previous stage to a higher salinity solution due to the difference in osmotic pressure.
    [0115]
    [0116] For the implementation of direct osmosis of the second stage, the direct osmosis desalination technology developed by the company Porifera, Inc. (called PFO from now on), which uses a carbon nanotube membrane, has been considered. The high flow rates at which water and gases flow through the carbon nanotubes facilitate desalination at high flow rates. This allows water treatment systems to be low polluting and energy efficient.
    [0117]
    [0118]
    [0119] This technology from Porifera, Inc., based on the incorporation of membranes made of carbon nanotubes, presents the possibility of desalinating water at high flows through the use of a DO system (three times greater). In this line, a combined system is proposed consisting of an OD to purify the water and an OI to recover the drainage solution and the water for reuse. In addition, there is a plate and frame (PM) format that has the advantage of a short path on the permeate / drain side of the membrane, which improves hydrodynamic efficiency and has the potential to reduce polarization of the concentration. When applied to OD systems, a narrower feed channel is used, and this provides a good packing density. However, the width of the channel must be carefully selected to ensure that there is no excessive pressure drop at the cross flow rate used for the required channel length.
    [0120]
    [0121] The PFO recycler is a combined DO and OI process that uses OI products from platforms configured in an easy-to-operate design specifically designed to maximize the effectiveness of OD elements and systems patented by Porifera Inc. The PFO concentrator is a modified DO and OI process that uses certain aspects of the combination of DO stages and multiple OI to achieve higher salinity concentrations using less energy than thermal processes. The membrane and elements from Porifera Inc. provide optimum flow and rejection on the market. The combination of the best membrane and the best element provides the smallest footprint OD, lowest CAPEX and lowest OPEX based system.
    [0122]
    [0123] The plate and frame (PM) format has the advantage of a short path on the permeate / drain side of the membrane, which improves hydrodynamic efficiency and has the potential to reduce concentration polarization. When used on membranes, the plate spacing is wide enough to ensure that the supply channels are not clogged. In OD, a narrower feed channel is used, and this provides a good packing density. However, the width of the channel must be carefully selected to ensure that there is no excessive pressure drop at the cross flow rate used for the required channel length.
    [0124]
    [0125] Porifera Inc. uses a building block system made up of various PFO modules and the PFO modules are made of various stacked PFO elements. The sizes of the elements used are relatively small with a typical commercial product that It has a membrane area of 7 m2. Different spacer options are used depending on the application. The products are claimed to be able to operate in the key competitive flow range of around 30 lmh or more with low pressure loss across the module. The PFO module has significant flexibility and versatility of drain and feed flow arrangement, with the ability to configure elements in the stack for series, parallel, and conical flow schemes. In series, the cross flow rate can be increased, while if there is a significant concentration change in a single pass, the flow can be configured in parallel. Depending on different feed and drain flow requirements, series and parallel options can be adjusted to suit. Due to the short path and relatively high cross flow of PFO elements, concurrent designs are used in the simplest systems, although more efficient countercurrent flow could be used for larger systems. Finally, a conical option is available if a high degree of conversion is required in a single pass.
    [0126]
    [0127] An OD-based process provides many benefits in dealing with challenging residual flows. These benefits include high fouling resistance for most particulate, organic, and other constituents that often lead to rapid fouling and downtime for other membrane technologies (eg MF, UF, NF , and OI) and thermal technologies.
    [0128]
    [0129] On the other hand, another technology for second stage direct osmosis is also considered, namely a technology developed by Oasys Water, Inc., a US water technology company.
    [0130]
    [0131] Oasys Water, Inc. has developed the ClearFlo family of products and claims that it can be applied to treat industrial wastewater that contains up to 5 times the salinity of seawater. The ClearFlo family of Water Transformation Solutions includes three main components: its patented direct osmosis membranes, a unique drain solution along with a drain solution recovery system.
    [0132]
    [0133] The ClearFlo Brine Concentrator (MBC ™) incorporates the OD membrane elements, the patented drainage solution, as well as the recovery system. Oasys Water, Inc. has developed a direct osmosis system that uses a specially drained solution
    [0134]
    [0135]
    [0136] formulated to force fresh water through the membrane. Feed water enters the system on one side of the membrane module as the drainage solution flows from the other end in the opposite direction. The formed concentration gradient carries water through the semipermeable membrane diluting the drainage solution. The diluted drainage solution is regenerated by a thermal recovery process. In the thermal recovery system, the diluted drain solution is recovered by heating the solution to evaporate the drain solutes, leaving behind the purified water.
    [0137]
    [0138] The MBC ™ system, based on forced osmosis (ie direct osmosis), can reduce disposal volumes by more than 80%, which in turn reduces the total cost of water treatment by up to 30%. It can also treat saline waters with a salt content of 5 to 15% and generates a reuse product of drinking water quality together with a reduced volume of brine for disposal. You can achieve up to 85% water recovery and discharge brine with up to 25% salt concentration.
    [0139]
    [0140] The technology can use renewable energy sources such as solar thermal, geothermal, and industrial cogeneration heat. As a result of this unprecedented level of brine concentration in a membrane-based system, the ClearFlo Complete Zero Liquid Discharge (ZLD) system can operate with a smaller capacity crystallizer, requiring fewer inputs of thermal and electrical energy and less total cost. Oasys Water Inc. offers the ClearFlo Complete system as a comprehensive solution in association with leading crystallizer suppliers and a network of leading EPC and system operators. For complex wastewater flows from 300 m3 / day to> 10,000 m3 / day, the ClearFlo Complete system provides a path to the ZLD with lower cost, more reliable operation, and greater operating flexibility when compared to other technologies.
    [0141]
    [0142] The following is the description of the MBC ™ system developed by Oasys Water, Inc. The pretreated feed stream is pumped to the MBC ™ system feed tank. From the system feed tank, sodium bisulfite and antifouling are dosed in-line for deoxidation and fouling control, respectively, as the flow is pumped to the OD membrane matrix.
    [0143]
    [0144] Feed water and concentrated drainage solution (SDC) flow countercurrently through the OD modules separated by the high performance OD membrane of
    [0145]
    [0146]
    [0147] Oasys. Water diffuses through the membrane, diluting the drain solution while simultaneously concentrating more than 99% of the dissolved solids from the feed water in the concentrated brine.
    [0148]
    [0149] The diluted drain solution (SDD) leaves the DO matrix and is pumped into the drain recovery column, where the drain solutes are removed from the solution along with a little water vapor. The concentrated brine leaving the OD membrane matrix is pumped to the brine column, where the drain solutes are also recovered which are permeated inversely in the brine and then sent to the drain recovery column. The mixed gas stream flows to the top of the drain recovery column, where it is compressed and fully condensed in a heat exchanger. The brine and drain recovery column reheat systems use customer supplied steam as an energy source. The condenser heat exchanger uses customer supplied cooling water as a heat sink.
    [0150]
    [0151] The intermediate product water is collected at the bottom of the drain recovery column and passed through the RO cleaning system. This step reduces the SDT of the product water to less than 500 mg / l and ensures the recovery of the remaining non-volatilized drainage solutes. The RO system concentrate is directed to the MBC system feed tank. The high quality, low SDT permeate from the RO system can be reused in site operations or safely discharged. The MBC Drainage Solution Recovery System integrates the Drain Recovery Column, the Brine Column, and the RO Clean to maintain nearly 100% of the drainage solutes within the system and maximize energy efficiency.
    [0152]
    [0153] 2c) Humidification - dehumidification: Stage in which the hot air comes into contact with the rejection of the previous stage. During this contact, the rejection is concentrated when the water passes from it to the hot air. In the dehumidification stage the hot air is cooled by condensing the decontaminated water. Concentration through humidification-dehumidification is a variant that is used in cases where there is the possibility of using residual heat sources from another process or renewable energy heat.
    [0154]
    [0155] Gradiant Corporation offers a smart way to implement humidification-dehumidification stages, combining carrier gas extraction technology (Carrier Gas Extraction) (CGE ™) with the Selective Chemical Extraction (SCE ™) process in a continuous process of desalination by humidification-dehumidification at atmospheric pressure and at room temperature to evaporate water controlling the effects of coprecipitation. Air is recirculated through a humidifier and a multi-stage bubble column dehumidifier in a closed loop. When the saline feed water enters the unit, it is preheated in the dehumidifier before heating to an additional 10-15 ° C using a natural gas boiler. Some of the feed water evaporates when sprayed onto a packed bed. The water-saturated air is pumped through small holes in a series of shallow trays filled with water in the dehumidifier. As the water bubbles pass through the fresh water in the trays, it joins the water it is passing through, creating more fresh water. Meanwhile, the non-evaporated part of the feed stream is removed as saturated brine. This so-called "bubble column" allows condensation of water vapor without the need for expensive metal heat exchangers.
    [0156]
    [0157] Selective Chemical Extraction (SCE) is a proprietary suite of treatment technologies that are cost-effective improvements to conventional precipitation technologies. They were designed to address the treatment challenges posed by the high levels of contamination found in produced water and in the return flow. Selective Chemical Extraction (SCE ™) is a multi-stage treatment process that can be customized to meet any effluent quality, including oil and grease removal, H 2 S extraction, removal of VOCs and semi-volatiles, the specific removal of ions and clarification of lamellae.
    [0158]
    [0159] The central part of SCE is ion-specific induced precipitation using proprietary chemistry plans. Chemically induced reactions with targeted ions form low solubility components. Divalent ions (Ca, Mg, Ba, Sr, SO 4 , CO 3 ), trivalent ions (Fe, Al), as well as dissolved silica and boron can be economically removed by this method. The Selective Chemical Extraction (SCE ™) process is based on controlled co-precipitation effects. Additional pretreatment may include removal of fat and oil, removal of H 2 S, removal of VOCs and semi-volatiles, specific removal of ions, and clarification of lamellae. SCE ™ currently operates in the oil field by Gradiant Corporation producing various grades of clean brine.
    [0160]
    [0161]
    [0162] at low cost and with minimal operator interference.
    [0163]
    [0164] In the Carrier Gas Extraction (CGE ™) process, water below the boiling point evaporates by direct contact with a carrier gas; the moist air is subsequently bubbled through cooler water where the purified steam condenses. But the temperature difference between hot and cold water is much smaller than in conventional dehumidifiers, and the surface area provided by small bubbles is much larger than that of a flat surface of the condenser, leading to a more efficient process . By acidifying the feed water, scale formation of scale forming ions is inhibited in a thermal desalination device.
    [0165]
    [0166] The Carrier Gas Extraction (CGE) process recirculates air through a closed-loop, multi-stage bubble column dehumidifier and humidifier. When the saline feed water enters the unit, it is preheated in the dehumidifier before heating to an additional 10-15 ° C using a natural gas boiler. Some of the feed water evaporates when it is sprayed onto a packed bed and condensed as distillate in the dehumidifier. In parallel, the non-evaporated part of the feed stream is removed as saturated brine and the now rehumidified air is returned to the dehumidifier column to continue the process.
    [0167]
    [0168] Among its advantages, CGE desalination technology can achieve declared high recoveries in the range of 70-85% for saline feedwater and is claimed to be a cost-effective version of conventional chemical precipitation techniques. The combination of technologies, according to Gradiant, allows these systems to treat waters with higher levels of pollutants. Custom control systems are used to optimize the system to operate at maximum thermal performance, minimize operator intervention, and minimize the consumption of chemical compounds. According to Gradiant, several design innovations allow these systems to use less energy and treat water at lower costs than competitive treatment methods. Design innovations include evaporating water below boiling temperatures using the gas from the dry air conveyor, incorporating a microbubble column that provides a direct contact condenser that optimizes condensation surfaces, resulting in a transfer of more efficient heat and minimizes hardware, using lower temperature differences between hot water
    [0169]
    [0170]
    [0171] and cold than in a conventional dehumidification system, and the use of economic materials in the heat exchanger. At customer's request, technologies can produce water with specific characteristics ranging from 50 ppm SDT (total dissolved solids) to 260,000 ppm SDT.
    [0172]
    [0173] 3) Zero liquid discharge stage - Evapo-crystallizer:
    [0174] In the previous stages of the process, the liquid effluent has been concentrated to the maximum, being around the saturation point at which precipitation of the salts that are mainly present in the liquid effluent begins to occur. The zero liquid discharge stage acts as a crystallizer, recovering the rejected water from the concentration stage by evaporation and producing a flow of solids.
    [0175]
    [0176] This part of the system comprises evaporators followed by crystallizers. In evaporators, the volume of the liquid effluent is reduced by evaporation, obtaining a water condensate. In crystallizers, the contaminants present in the liquid effluent precipitate with the solids. Examples of evaporators that can be used are those offered by the companies GE Power & Water, Evatherm and Inerco.
    [0177]
    [0178]
    2
    权利要求:
    Claims (7)
    [1]
    1. A zero liquid discharge treatment process for the treatment of wastewater from industry that includes at least the following stages:
    a) a first stage of desalination that avoids the precipitation of salts by means of an advanced reverse osmosis treatment with a high degree of recovery, in which several periodic cleanings are carried out by contacting the surface of some membranes with water with a lower content of dissolved salts than the wastewater to be treated;
    b) a second concentration stage, in which the rejection of the first stage produced in reverse osmosis is concentrated applying one of the technologies of the group formed by vibratory osmosis, direct osmosis and humidification-dehumidification;
    c) a zero liquid discharge stage that acts as a crystallizer or an evapocrystallizer, in which the liquid effluent that has been concentrated to the maximum in the previous stages is around the saturation point at which the precipitation of salts begins to occur They are mainly present in the liquid effluent, the liquid discharge zero stage acting as a crystallizer, recovering the rejection water from the concentration stage by evaporation and producing a stream of solids.
    [2]
    2. The zero liquid discharge treatment process according to claim 1, characterized in that the advanced reverse osmosis of the first stage a) of desalination is carried out by means of a closed-loop desalination consisting of a single-stage osmosis operating in production and purge cycles, where in production cycles, the liquid effluent concentrates over time while water is produced and once the concentrated liquid effluent has reached a predetermined salinity, it is purged and it is cleaned with the same liquid effluent with a lower concentration of salts than the previous concentration, without allowing the salts to precipitate.
    [3]
    3. The zero liquid discharge treatment process according to claim 1, characterized in that the advanced reverse osmosis of the first stage a) of desalination is carried out by means of a flow inversion consisting of an osmosis system of two or three stages with continuous operation, but periodically alternating the different stages with each other, where from time to time the last stage in which the concentration of salts and therefore the potential for precipitation are greater, goes away exchanging with the first stage through a valve system that treats the liquid effluent of lower concentration.
    [4]
    4. The zero liquid discharge treatment process according to claim 1, characterized in that the second stage b) consists of a vibratory osmosis stage that incorporates vibratory membranes that manage to recover the water and concentrate the rejection of the previous stage with high solids content and high potential for precipitate formation.
    [5]
    5. The zero liquid discharge treatment process according to claim 1, characterized in that the second stage b) is carried out by means of a direct osmosis comprising the use of direct osmosis membranes to concentrate the rejection with a content of solids and moderate potential for the formation of precipitates, where the water passes from the rejection of the previous stage to a solution of higher salinity due to the difference in osmotic pressure.
    [6]
    6. The zero liquid discharge treatment process according to claim 1, characterized in that the second stage b) is carried out by means of humidification-dehumidification, where hot air is contacted with the rejection of the previous stage and during this contact , the rejection is concentrated when the water passes into the hot air, the hot air cooling in the dehumidification stage condensing the decontaminated water.
    [7]
    7. The zero liquid discharge treatment process for wastewater treatment where said wastewater comes from mining or the steel industry.
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    同族专利:
    公开号 | 公开日
    ES2754898R1|2020-04-27|
    EP3517508A1|2019-07-31|
    引用文献:
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    法律状态:
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    优先权:
    申请号 | 申请日 | 专利标题
    EP18195919.8A|EP3517508A1|2018-09-21|2018-09-21|Zero liquid discharge treatment process for recovering water from a contaminated liquid effluent for its subsequent reuse|
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