• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a plant filter wastewater treatment device (1) in which the wastewater circulation is vertical flow, the device comprising a purification basin (10) intended to receive wastewater, the basin comprising at least two superimposed layers of filtering material: - a bottom layer (100) saturated with water located in the bottom of the basin and comprising drainage means; - an upper unsaturated layer (101) in water located above the lower layer, the upper layer comprising passive aeration means, characterized in that the device comprises an active aeration system (3) of the layer saturated lower.
    公开号:FR3031516A1
    申请号:FR1550180
    申请日:2015-01-09
    公开日:2016-07-15
    发明作者:Joelle Paing;Florent Chazarenc;Vincent Gagnon
    申请人:J Voisin;
    IPC主号:
    专利说明:

    [0001] A vertical percolation plant-mounted wastewater treatment device comprising an active aeration system of a saturated lower layer. The field of the invention is that of the design and manufacture of wastewater treatment systems. More specifically, the invention relates to the design of a vertical percolation filter type wastewater treatment device. The treatment of sewage by planted filters has seen a very strong development over the last twenty years. This type of purification system is applied mainly for the treatment of domestic effluents in small communities. It has many advantages: - good landscape integration; - easy and inexpensive maintenance; - low sludge production; - no energy consumption or chemicals; - good purification performance; - good adaptation to load variations. Planted filters can be vertical or horizontal percolation. In the horizontal filters, the arrival of effluents in the massif is carried out on one of the sides, they then walk horizontally in the massif to be recovered at the other end. In this case, the water level in the massif is maintained at about 5 to 10 cm from the surface and most of the filter is then in saturated and anoxic medium. In these filters, the feed is generally continuous and the oxygen supply is greatly reduced. The conditions are then favorable for denitrification reactions carried out by denitrifying bacteria (leading to the reduction of nitrates to gaseous compounds). It should be noted that these bacteria are heterotrophic and therefore need organic matter to grow. As the flow rates are slower and the contact time with bacteria higher, these filters promote the elimination of organic matter that is difficult to biodegrade.
    [0002] In vertical filters, the wastewater is sent to the surface, percolate vertically through the filter bed and is recovered in the bottom by a drainage network. These filters are mainly maintained under aerobic conditions, thanks to "passive" aeration mechanisms: the supply of 02 excreted by the roots of the plants; convection, linked to the piston effect of the displacement of the water strips brought to each tarpaulin; diffusion, both from the surface and at the bottom through the network of drains connected to ventilation chimneys (it allows the renewal of the gaseous phase of the inter-granular spaces in unsaturated medium). The main pollutants eliminated are suspended solids, organic matter and nitrogen compounds. In the vertical filters, the purifying mechanisms are governed by physical (filtration, adsorption) and biological (aerobic microbial degradation, nitrification, plant assimilation) mechanisms. Note that in these filters, the treatment of global nitrogen is low because it is limited to nitrification by nitrifying bacteria under aerobic conditions (leading to the oxidation of ammoniacal nitrogen to nitrites and nitrates).
    [0003] In these devices, the main roles of plants planted on the surface are as follows: maintain the permeability of the filtering mass by virtue of the hydraulic paths created by their stems, roots and rhizomes (prevention of clogging phenomena); - Promote aerobic microbial activity near the roots and rhizomes that serve as biofilm support, including through the supply of oxygen plants; - promote the dehydration of solids retained on the surface if necessary, through the evapotranspiration of the reeds.
    [0004] In France, the most widely applied sector consists of two stages (or basins) of vertical filters in series, with a total filter area of 2 to 2.5 m2 / EH (1.2 to 1.5 m2 / EH on the first floor and 0.8 to 1 3031516 3 m2 / EH on the second floor, with EH = Equivalent-Inhabitant, corresponds to the daily pollution generated by a person, most often 60 gDBO5 / d, 120 gDCO / d, 90 gME / d, 15 gNTK / d and 2.4 gPT / d). One of the peculiarities of this sector is not to include pretreatment (except for rough screening) and to send the raw effluents directly onto the surface of the first stage. Thus, the particulate matter contained in the wastewater is retained by surface filtration mechanisms, where it is progressively dehydrated and mineralized. The accumulation of sludge is thus low (approximately 1.5 cm / year), resulting in very long cleaning intervals (once every 10 to 15 years). In addition, sludge quality is compatible with agricultural upgrading without additional treatment. It is now known that this die, consisting of two vertical filters in series, makes it possible to obtain high purification efficiencies for the domestic effluents (> 90%) on the pollutants: suspended matter (MES), organic matter (BOD5 and COD) and reduced nitrogen (NTK). On the other hand, performance is limited (<30%) for global nitrogen (NGL) and phosphorus (PT). This sector also has the disadvantage of having a relatively high land area (2 to 2.5 m2 / EH).
    [0005] The prior art has proposed other solutions. There are thus mixed dies constituted by the combination of vertical and horizontal type filters, in series, in particular to improve the performances on the global nitrogen by favoring the nitrification and denitrification reactions. However, to achieve high yields (> 85%) on global nitrogen (NGL), there is generally at least three stages (basins) with recirculation, resulting in a high land grab (> 4 m2 / EH). There are also solutions that use compact vertical percolation filters with superimpositions of several layers of materials and the use of porous filter material, capable of promoting the development of microorganisms and reducing the land grab and to limit operating costs. Nevertheless, these filters present risks of clogging of the additional layer of lower particle size, especially in the case of heavily loaded effluents. In addition, nitrification is often incomplete and these filters have low yields on global nitrogen (<30%). More recently, another solution has been proposed by the prior art, consisting in using vertical percolation compact filters with a water-saturated lower layer and an unsaturated upper layer. This solution improves the performance of the global nitrogen by promoting nitrification and denitrification reactions, as well as reducing the land holdings and limiting operating costs. This proposal, however, has difficulties in treating heavily loaded effluents (agri-food, agricultural, etc.) with a single basin, an often incomplete nitrification and an overall nitrogen yield of 70%. The invention particularly aims to overcome these disadvantages of the prior art. More specifically, the invention aims to provide a wastewater treatment system efficient and having a reduced land footprint. Another object of the invention is to propose such a system which makes it possible to treat highly charged effluents with a single pond, a higher nitrification yield than is allowed by the single-basin solutions proposed by the prior art. and a high yield on the global nitrogen. It is another object of the invention to provide such a system which has contained operating costs. These objectives, as well as others which will appear later, are achieved thanks to the invention which has for object a wastewater treatment device of the plant filter type in which the circulation of the wastewater is at vertical flow, the device comprising a purification tank 30 for receiving wastewater, the basin comprising at least two superimposed layers of filtering material: a bottom saturated layer of water located in the bottom of the basin and comprising drainage means; an upper unsaturated layer of water located above the lower layer, the upper layer comprising passive aeration means, characterized in that the device comprises an active aeration system of the saturated lower layer. The expression "passive aeration means" designates, for example, the supply of 02 excreted by the roots of the plants or the diffusion 10 from the surface. These systems make it possible to maintain the unsaturated upper layer in water under aerobic conditions. The unsaturated upper layer thus produced allows the filter to promote the treatment of particulate solids retained at the surface and not to require special pretreatment to remove at least a large portion of the latter. Indeed, such pretreatment, for example carried out by a septic tank, a digester digester or anaerobic reactor, requires a regular extraction of undehydrated sludge and often little mineralized, which often requires additional treatment before an agricultural revalorization , resulting in high operating costs and constraints. Thanks to the principle of the invention, the lower layer provides an advantageous treatment of dissolved pollution. In fact, the active aeration system makes it possible to increase the kinetics of degradation, in particular for effluents highly charged with organic and nitrogenous dissolved pollution. The treatment device according to the invention is suitable for the treatment of domestic wastewater discharged by a community but also for the treatment of wastewater discharged by an individual dwelling. It can also be applied for the treatment of industrial or agricultural effluents. In particular, this device is advantageously suitable for the treatment of effluents heavily loaded with organic matter and containing particulate matter as generated by the food industry (meat industry, fruit and vegetable industry, bakery). industrial pastry, dairy / dairy industry, wine cellar ...).
    [0006] A treatment device according to the invention thus makes it possible to treat highly charged effluents with a single pond, hence a reduced land footprint. In addition, the device allows the treatment of domestic effluents and industrial or agricultural effluents containing particulate matter, without pretreatment (except a rough screening), while ensuring high yields on the parameters MES, DCO, DBO5, NTK , as well as on global nitrogen. It should also be noted that the invention retains certain advantages of planted filters: good landscape integration, easy and inexpensive maintenance, low sludge production, lower energy consumption than "intensive" type activated sludge processes, no consumption of chemicals, high purification performance and good adaptation to load variations. According to an advantageous embodiment: the lower layer has a height H1; the upper layer has a height H 2, the device having a ratio R = H 1 / H 2 with 0.2 R 1 and H 2 CM. This minimum height is particularly important, especially to promote the dehydration of particulate matter by a drainage mechanism. Indeed, the dehydration of particulates favored by this feature allows the device according to the invention to overcome pretreatments found in the solutions proposed by the prior art.
    [0007] Preferably, the passive aeration means comprise a network of aeration drains situated at the bottom of the upper layer.
    [0008] 3031516 7 This drains network is particularly suitable for effluents loaded with particulate matter, in order to promote the treatment of particulate matter retained at the surface by drainage dewatering and aerobic mineralization mechanisms.
    [0009] According to a particular characteristic, the purification basin comprises systems for the supply of wastewater by sheeting. Such a wastewater supply system improves the oxygenation of the upper layer. Indeed, the arrival of the effluents being discontinuous (by "tarpaulin") there is a convection effect, related to the piston effect of displacement of the water blades made to each tarpaulin. In addition, this system provides a good distribution of wastewater over the entire surface of the purification tank. According to a preferred embodiment, the active aeration system is located in the bottom of the lower layer and is distributed essentially over the entire surface covered by the lower layer of the purification tank, the aeration system being intended to ventilate homogeneously the whole of the lower layer. The degradation kinetics in the saturated lower layer can thus be homogeneous in said lower layer.
    [0010] Advantageously, the active aeration system of the saturated lower layer is an intermittent system. The ventilation system thus designed makes it possible on the one hand to reduce energy consumption and, on the other hand, to improve the treatment of global nitrogen by promoting nitrification and denitrification reactions.
    [0011] According to one particular embodiment of the invention, the intermittent active aeration system comprises a time programmer. For example, the system can be programmed to cycle one hour of ventilation followed by one hour of aeration stop. According to a preferred embodiment, the device comprises sensors for determining dissolved oxygen parameters and / or oxidation-reduction potential in the lower layer, and in that the intermittent active aeration system 3031516 has an automatic switch coupled to the sensors. According to an advantageous characteristic, the wastewater treatment device comprises a plurality of purification tanks mounted in parallel, the intermittent aeration systems of the saturated lower layer of each basin forming an aeration network, and the network of aeration comprises alternating air supply means of aeration systems. These alternating air supply means can take the form of pumps, fans or boosters which alternately feed the aeration systems through valves. According to another advantageous characteristic, the wastewater supply systems of each basin form a sewage supply network, the sewage supply network comprising means for alternately feeding the wastewater systems. 'bring. The alternating feeding means of the delivery systems allow in particular to have rest periods favorable to the dehydration and mineralization of particulate matter retained on the surface. In addition, such a device comprising a plurality of purification tanks thus makes it possible to treat a continuous flow of wastewater while allowing the application of these rest periods. Other features and advantages of the invention will appear more clearly on reading the following description of preferred embodiments of the invention, given by way of illustrative and nonlimiting examples, and the appended drawings among which: Figure 1 is a schematic representation in a side view of the wastewater treatment device according to the invention; - Figure 2 is a schematic representation in a view from above of the wastewater treatment device according to the invention. As shown in FIGS. 1 and 2, the wastewater treatment device 1 is of the vertical percolation filter type (which involves defining a circulation of the wastewater in the device in a vertical flow). The device 1 comprises a purification tank 10. In FIGS. 1 and 2, the purification tank has: - an inlet of untreated wastewater E; an air inlet A; - A treated wastewater outlet S. As illustrated in Figure 1, a sealing complex 9 is located on the sides and the bottom of the basin. It takes the form, for example, of a geomembrane of high density polyethylene (HDPE), placed on an anti-punching geotextile. Edges 90 are also arranged around the basin, these borders may be polypropylene, wood or concrete. In particular, they make it possible to protect the filter from runoff water and to protect the sealing complex from external damage (UV, rodents, malevolence, etc.). The purification tank 10 comprises at least two superposed layers of filtering materials: a lower layer 100 and an upper layer 101 located above the lower layer.
    [0012] In the upper layer of filter materials, plants are planted to promote dehydration of surface-retained particulate materials, help maintain filter permeability, and promote aerobic microbial activity near roots and rhizomes. These plants are for example plants of the type Phragmite, Glyceria, Scirpus, Phalaris. This upper layer 101 is unsaturated with water. It comprises means of passive aeration. These passive aeration means comprise a network of ventilation drains 4 located at the bottom of the upper layer.
    [0013] The lower layer 100 is saturated with water and situated in the bottom of the basin. This lower layer comprises means for draining the treated wastewater.
    [0014] The device also comprises water retention means 2 able to maintain, in the basin in operation, a water of a predetermined height that corresponds to the entire height of the lower layer 100 .
    [0015] As illustrated by the figures, the device 1 comprises an active aeration system 3 of the saturated lower layer. This active aeration system is located in the bottom of the lower layer and extends over substantially the entire surface covered by the lower layer of the purification tank. According to particular embodiments, the active aeration system of the saturated lower layer is an intermittent system which may for example comprise: a time programmer; an automatic switch coupled to sensors located in the processing device and for determining dissolved oxygen parameters and / or oxidation reduction potential in the lower layer. The purification basin comprises wastewater delivery systems 5 by tarpaulins. The device may comprise one or more purification tanks 20 connected in parallel. In the case of several basins in parallel, these can be supplied with alternating wastewater: the wastewater supply systems of each basin form a sewage supply network comprising means for supplying wastewater. alternation of said delivery systems. For example, these alternating feed means consist of manual or automatic valves arranged between the feeding system (automatic flushing or lifting station) and the basins. This alternation makes it possible, in particular, to have rest periods favorable to the dehydration and the mineralization of the particulate matter retained on the surface. Still in the case of several basins in parallel, the artificial aeration network (formed by the intermittent aeration systems of the saturated lower layer of each basin) can also be fed alternately: aeration comprising alternating air supply means of aeration systems. For example, the alternating air supply means take the form of manual or automatic valves, arranged between the air distribution system (pump, fan, booster) and the basins. A wastewater treatment device according to the invention can operate and be adapted as described below. The device can be fed with raw wastewater 10 previously screened (20 to 30 mm mesh) to remove the coarsest waste. The wastewater is then sent to the surface of the basin in operation, through a supply ramp of the wastewater supply systems 5 which can be above ground or buried (as shown in Figure 1). In order to have a good distribution over the entire surface, the feed network formed by the delivery systems is composed of a main feeder 50 and several diffusers 51, below which are installed scouring plates 6 In the case of a buried feed ramp, a control manhole 500 may be mounted at the end of the main nanny, to allow the draining of the pipe, and possibly its cleaning. The arrival of effluents is discontinuous, by "tarpaulin", which promotes a good distribution over the entire surface and better oxygenation of the upper layer 101 unsaturated by convection. The tarpaulin feed can be obtained by an automatic flush operating without energy if the altitude allows it. In the case of land without slope or very low slope, the power supply includes a lifting station containing at least one pump. The wastewater percolates vertically in the unsaturated upper layer of the basin consisting for example of at least two sub-layers of gravel of different particle size. For example, there is a first sub-layer 1010 with a particle size of 2 to 6 mm at the surface, at a height of from 15 to 40 cm, then a second underlayer 1011, 3031516 12 located below the first underlayer. , coarser grain size of 4 to 20 mm over a height of 15 to 30 cm. The upper layer thus has a height H2 30 cm. In addition, a layer of compost 102 5 to 15 cm high can also be added to the surface, to improve filtration performance and promote reed growth at startup. The network of ventilation drains 4 connected to at least one passive ventilation chimney 40 may be positioned at the bottom of this upper layer in order to contribute to maintaining it in aerobic condition, including during the 10 phases of stopping the artificial aeration by the active aeration system of the saturated lower layer. The aeration drains network 4 is particularly recommended in the case of a particulate matter effluent to promote the treatment of particulate matter retained at the surface by drainage dewatering and aerobic mineralization mechanisms. The partially treated wastewater then reaches the lower saturated layer 100 in water with artificial aeration through the active aeration system. The water level is maintained by means of the water retention means 2 which take the form of an outlet load 6 at the outlet. This lower layer consists of at least one gravel sub-layer with a particle size of 10 to 40 mm over a height H1 of 40 to 150 cm. According to the present embodiment, the device has a ratio R = H1 / H2 with 0.2 R 1.
    [0016] The active aeration system 3 is positioned in the bottom of the basin and has an air distribution network composed of several pierced pipes allowing a homogeneous distribution of air over the entire surface of the lower layer. The pipes may for example be pipes with self-regulating drippers which ensure uniform distribution, even over long lengths, and have a high resistance to clogging. The oxygen present in the air fed to the bottom of the pond is diffused into the liquid phase of the saturated lower layer and is thus available for aerobic microbial degradations. The air supply means may for example comprise a pump, a fan or a booster. The air flow is between 0.1 and 1.5 Nm3 / m2.h depending on the pollutant load to be treated.
    [0017] As previously explained, the aeration system may be an intermittent system. The treated water is then recovered by the drainage means via at least one transverse collection drain 7 (as shown in FIG. 1) connected to an evacuation pipe 70 which opens onto the loading sight 6. look is equipped with an elbow with a water outlet whose level can be adjustable (between the bottom of the basin and the high level of the saturated lower layer, corresponding to the low level of the intermediate passive aeration drain if existing). A drain plug 71 at the base of the elbow makes it possible to empty the saturated lower layer if necessary, for example in the event of a lack of artificial aeration (electrical failure, compressor failure, etc.), in order to prevent risks of failure. prolonged anoxia in the case of heavily loaded effluents and the risk of clogging. The drainage means may also be connected to the passive ventilation chimneys 40.
    [0018] The treated water is then discharged to the natural environment (river, ditch, lake, sea ...), underground infiltration, to a storage area for reuse, or to a finishing treatment. The capacity of such a processing device according to the invention may be increased by providing an upper surface filter, or by adding one or more additional filters or sets of filters, fed in parallel and / or alternately. According to possible variants, the different layers of gravel of different particle sizes can be replaced by other types of filtering materials, allowing the fixing and the development of the purifying bacteria and / or with chemical properties allowing the elimination of certain pollutants: Porous materials having a high specific surface area, such as shale or expanded clay; materials with ion exchange properties such as zeolite, including the ability to retain ammonium ions (NH4 +); - materials allowing precipitation and / or adsorption of phosphates such as steel slags, apatite; carbon-enabling materials for denitrification, such as wood chips or other organic derivatives; - materials providing alkalinity to buffer the pH. Depending on the composition of the effluent to be treated, the effluent treatment device may comprise additional elements, upstream or downstream. Upstream, the device may comprise, for example, a degreasing device, a storage tank, an effluent neutralization device and / or a nutrient addition system in order to improve the biodegradability of the effluent. Downstream, the device may comprise, for example, a disinfection device, a sand filter, a dephosphatation device and / or a planted rejection zone.
    权利要求:
    Claims (9)
    [0001]
    REVENDICATIONS1. Device (1) for treated wastewater treatment plant type in which the flow of wastewater is vertical flow, the device comprising a purification tank (10) for receiving wastewater, the basin comprising at least two superposed layers filter material: - a lower layer (100) saturated with water located in the bottom of the basin and comprising drainage means; - an upper unsaturated layer (101) in water located above the lower layer, the upper layer comprising passive aeration means, characterized in that the device comprises an active aeration system (3) of the layer saturated lower.
    [0002]
    2. Wastewater treatment device according to claim 1, characterized in that: - the lower layer has a height H1; the upper layer has a height H 2, the device having a ratio R = H 1 / H 2 with 0.2 R 1 and H 2> 30 cm.
    [0003]
    3. Wastewater treatment device according to any one of the preceding claims, characterized in that the passive aeration means comprise a network of aeration drains (4) located at the bottom of the upper layer.
    [0004]
    4. Wastewater treatment device according to any one of the preceding claims, characterized in that the purification tank comprises wastewater delivery systems (5) per sheeted. 3031516 16
    [0005]
    5. Sewage treatment device according to any one of the preceding claims, characterized in that the active aeration system (3) is located in the bottom of the lower layer and is distributed essentially over the entire area covered by the lower layer of the purification basin, the active aeration system being intended to aerate homogeneously the entire lower layer. Wastewater treatment device according to one of the preceding claims, characterized in that the active aeration system of the saturated lower layer is an intermittent system. Wastewater treatment device according to claim 6, characterized in that the intermittent active aeration system comprises a timer. Wastewater treatment device according to claim 6, characterized in that it comprises sensors for determining dissolved oxygen parameters and / or oxidation reduction potential in the lower layer, and in that the system Active intermittent aeration system has an automatic switch coupled to the sensors. Wastewater treatment device according to any one of claims 6 to 8, characterized in that it comprises a plurality of purification tanks connected in parallel, the intermittent aeration systems of the saturated lower layer of each basin forming a aeration network, and in that the aeration network comprises alternating air supply means of aeration systems. 10. A wastewater treatment device according to claims 4 and 9, characterized in that the wastewater supply systems of each 5
    [0006]
    6. 10
    [0007]
    7. 15
    [0008]
    8. 20
    [0009]
    The basin forms a sewage supply network, the sewage supply network comprising means for alternately feeding the supply systems. 5
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    同族专利:
    公开号 | 公开日
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    FR3031516B1|2018-09-14|
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    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
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    CN202063799U|2011-04-27|2011-12-07|安徽南风环境工程技术有限公司|High-efficiency multifunctional wastewater treatment system|
    CN102633362B|2012-01-09|2013-10-16|中国环境科学研究院|Artificial wetland sewage treatment device capable of running continuously at low temperature|
    CA2777470A1|2012-05-16|2013-11-16|Quaestor B.V.B.A.|Device for the purification of sanitary waste water|FR3035395B1|2015-04-24|2021-09-24|Epur Nature|WASTEWATER AND USES TREATMENT DEVICE|
    FR3076829B1|2018-01-15|2021-12-10|Opure|DEVICE AND METHOD FOR TREATING WASTE WATER, INTEGRATING A PURIFICATION BASIN OF PLANT FILTER TYPE AND A BIOLOGICAL REACTOR|
    CN111517567A|2020-04-17|2020-08-11|雷燕|Ecological environment restoration system with automatic blockage clearing function and restoration method|
    MA49998A1|2020-06-08|2021-12-31|Univ Sidi Mohamed Ben Abdellah|Device for the treatment of waste water by vetiver zizania filters and biochar with ascending flow with forced aeration by adjustable oxygen injection rods|
    法律状态:
    2016-01-06| PLFP| Fee payment|Year of fee payment: 2 |
    2016-07-15| PLSC| Search report ready|Effective date: 20160715 |
    2017-01-02| PLFP| Fee payment|Year of fee payment: 3 |
    2017-12-08| PLFP| Fee payment|Year of fee payment: 4 |
    2018-03-22| PLFP| Fee payment|Year of fee payment: 5 |
    2019-09-19| PLFP| Fee payment|Year of fee payment: 6 |
    2021-03-26| PLFP| Fee payment|Year of fee payment: 7 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1550180A|FR3031516B1|2015-01-09|2015-01-09|VERTICAL PERCOLATION PLANT FILTER TYPE WASTE TREATMENT DEVICE COMPRISING AN ACTIVE AERATION SYSTEM OF A SATURATED LOWER LAYER|
    FR1550180|2015-01-09|FR1550180A| FR3031516B1|2015-01-09|2015-01-09|VERTICAL PERCOLATION PLANT FILTER TYPE WASTE TREATMENT DEVICE COMPRISING AN ACTIVE AERATION SYSTEM OF A SATURATED LOWER LAYER|
    CN201680004666.1A| CN107207298A|2015-01-09|2016-01-08|Including the sewage treatment equipment for the vertical percolating type plant filtration types of active ventilation systems divulged information to saturation lower layer|
    EP16702755.6A| EP3242859B1|2015-01-09|2016-01-08|Sewage treatment device, such as a vertical-percolation planted filter, comprising a system for active aeration of a saturated lower layer|
    PCT/FR2016/050033| WO2016110657A1|2015-01-09|2016-01-08|Sewage treatment device, such as a vertical-percolation planted filter, comprising a system for active aeration of a saturated lower layer|
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