OA21456A - Digester with reduced volume of gaseous sky. - Google Patents

Abstract

The invention relates to a digester intended for implementing a sludge methanization treatment to generate biogas and a digestate, the digester comprising a device for evacuating (32) foams and/or floats (16) from the digestate (12) comprising: - a first tank (33) delimited by a first wall (100) of a first height (h1), the first tank (33) being intended to be supplied with digestate (12) and foam and/ or floating (16) from a volume of material (14) by overflowing above the first wall (100); - a second tank (34) connected to the atmosphere and located outside the enclosure (13) of the digester, comprising: o a first zone (35) delimited by a second wall (103) of a second height (h2); and o a second zone (36) in communication with the reservoir (19); - a conduit (37) connecting the first tank (33) via a first orifice (101) to the first zone (35) of the second tank (34) via a second orifice (102) of altitude greater than or equal to that of the first orifice (101), - the first zone (35) being intended to be supplied with digestate (12) and foams and/or floats (16) from the first tank (33) via the conduit (37); the second zone (36) being intended to be supplied with digestate from the first zone (35) by overflow above the second wall (103); the first height (h1) and the second height (h2) being predefined so that a first mixture of variable proportions of digestate and foams and/or floating in the first tank (33) having a first average density (d1) is transferred by gravity in the first zone (35) containing a second mixture of variable proportions of digestate and foams and/or floats of second density (d2), the transfer taking place as long as the product of the first average density (d1) by the first height (h1) is greater than the product of the second average density (d2) by the second height (h2) by the first height (h1).

Description

DIGESTER WITH REDUCED GAS VOLUME

[0001] The invention lies in the technical field of biological treatment of sludge, particularly from waste water. The invention relates to a digester intended for implementing a sludge methanization treatment.

[0002] Anaerobic digestion is a technology based on the degradation of organic matter by microorganisms, under controlled conditions and in the absence of oxygen, therefore in an anaerobic environment. We also talk about anaerobic digestion.

[0003] Methanization makes it possible to generate:

- a digestate, which is a moist product, rich in partially stabilized organic matter. It is generally envisaged to return the digestate to the ground after possibly a maturation phase by composting;

- biogas, a gaseous mixture generally saturated with water at the outlet of the digester and typically composed of approximately 50% to 70% methane (CH4), 30% to 50% carbon dioxide (CO2) and some trace gases ( NH3, N2, H2S). Biogas constitutes a renewable energy, it can be injected into the natural gas network after purification. Biogas can also be used for the production of electricity and heat and/or the production of fuel.

[0004] One of the advantages of methanization is the valorization of organic matter and the production of energy via the biogas generated.

[0005] Methanization is carried out in a digester. The digester can be seen as an enclosure closed by an upper wall (also called a roof), defining two volumes: a first volume containing the material to be treated, the sludge, the digestate generated; and a second volume between the first volume and the upper wall, also called gas sky, and towards which the generated biogas rises.

[0006] The term “sludge” must be understood as any organic matter, including organic waste and all kinds of sludge, including primary sludge, biological sludge, activated sludge, and more particularly organic waste sludge. or drinking water or wastewater treatment plants. Organic matter, or natural organic matter, refers to the large source of carbon-based compounds found in natural and artificial, terrestrial and aquatic environments. It is matter composed of organic compounds originating from the remains of organisms such as plants and living things and their waste products in the environment. Organic molecules can also be made by chemical reactions that do not involve life. The basic structures are created from cellulose, tannin, cutin and lignin, as well as other proteins, lipids and carbohydrates.

[0007] Safety problems may be linked to the implementation of a digester. Indeed, biogas contains methane, which creates a risk of the digester exploding if oxygen accidentally enters the digester. Consequently, distances for explosion effects due to the presence of biogas in the digester are defined in order to delimit a so-called risk perimeter.

[0008] Aerial overpressure is the consequence of an explosion which manifests itself by the propagation from the explosion zone of a pressure wave in the atmosphere, at a speed of the order of that of acoustic waves. (340 m/s in air at 15°C). When we measure the characteristics of such a wave at a fixed point in space, we observe a positive pressure pulse (overpressure) - the duration of which is generally measured in milliseconds - followed by a depression phase.

[0009] If the explosion originates from the detonation of an explosive substance, the positive overpressure is characterized by a very sudden, almost instantaneous rise to the maximum pressure, followed by an almost linear decrease. The negative pressure peak is much less important and is generally not considered in the evaluation of the effects of a pressure wave.

[0010] Pressure is a force per unit surface capable of inducing bending or shearing forces in structures, possibly compression for the human body. A pressure wave can also propel projectiles.

[0011] In France, the decree of October 22, 2004 (Ministry of Ecology and Sustainable Development) defines the reference values for the effect thresholds of accidental phenomena in classified installations. These values are used to determine potential accident effect zones in hazard studies (explosion radii).

[0012] When the rupture pressure of a digester is known, the calculation of the explosion energy can be carried out with the so-called Brode equation. This energy is the energy that can participate in the propulsion of missiles, in the production of overpressure waves or thermal flows according to:

ΔΡ V E = ----yr — 1

[0013] With ΔΡ: Pr - PO; Pr: Burst pressure of the enclosure (Pa); PO: Atmospheric pressure (Pa); V: Volume of the gaseous sky (m3); yr: Ratio of specific heats of the gas contained in the reservoir (1.4 for methane); E: Explosion energy (J).

[0014] Once the explosion energy has been determined, there are several methods for calculating the distances of the effects of the explosion. In the case of a digester, the TNO Multi-energy model is mainly used, for confined or unconfined explosions (Unconfined Vapor Cloud Explosion (UVCE)).

[0015] The problem therefore lies in the reduction of the effect distances due to the presence of biogas. From a digester concept point of view, the two adjustable parameters which impact the level of overpressure thresholds and explosion effect distances are:

- The breaking pressure of the structure;

- The explosive volume (i.e. the volume of the gaseous sky in normal operation or of the empty digester during accidental emptying).

[0016] The gaseous sky is generally quite voluminous, and the distance between the digestate level and the upper wall of the digester can reach up to 3 m. Such a height is firstly intended to authorize the accumulation of floating products and to manage possible foaming caused either by the presence of filamentous bacteria in the process of depolluting wastewater producing sludge (expansion of sludge, " bulking" in English), or by the production of surfactant compounds in the digester. In fact, most often, digesters do not have a device to evacuate foam and floating material. It is therefore necessary to provide such a “storage” volume on the surface of the digestate.

[0017] Furthermore, the high height of the gas sky also makes it possible to manage a possible phenomenon of rapid expansion of the volume of digestate (known by the acronym RVE for “Rapid Volume Expansion”). RVE is a phenomenon linked to the sudden increase in digestate viscosity caused, most often, by a loss or disruption of the mixing function. Indeed, once the shear decreases, the viscosity of the digestate increases, which traps part of the biogas in the digestate, and can generate a rapid increase in its volume.

[0018] In summary, the usual design of digesters consists of leaving a significant height between the level of digestate and the upper wall of the digester, so as to be able to store the foams and floats on the surface of the digestate and to allow a possible phenomenon of DREAM. If this height is insufficient, the integrity of the structure - more particularly that of the upper wall - is endangered. This volume available for foam expansion is usually occupied by biogas and generates the safety constraints mentioned above.

[0019] It is therefore interesting to reduce the volume of biogas in the upper part of the digester to reduce the distance of effects in the event of an explosion. Reducing this volume of biogas without taking risks on the integrity of the digester, however, requires knowing how to extract (1) the foams and floating continuously on the surface of the digestate, and (2) the volume of digestate that cannot be contained in the digester in case of RVE phenomenon without exerting excess pressure.

[0020] However, the extraction of foams and floaters on the surface is a complex operation to carry out.

A first solution to this problem consists of extracting them from the digestate by simple overflow. This 5 makes it possible to periodically entrain “packets” of foam/floating material present on the surface.

However, with such a solution, the gas contained on the surface of the digester can escape through the overflow device. To avoid this, it is then necessary to provide another device downstream to retain the biogas and separately collect the digestate containing the foams/floats. These devices generally operate on the principle of the hydraulic seal, the operation of which is mainly dictated by the density of the liquid treated. However, the density of the digestate containing the foams/floats varies greatly over time: when the packs of foams/floats are extracted, the density drops suddenly, which prevents the proper functioning of the hydraulic seal. Another difficulty lies in the fact that these devices downstream of the overflow must meet two opposing constraints: have a sufficiently low hydraulic section to produce high speeds making it possible to drive the foam/floats, and have sufficiently wide hydraulic sections. to avoid clogging by digestate and foam/floating material. This first solution, using a simple overflow, is therefore not completely satisfactory.

[0021] A second solution consists of extracting the foam and floatants from the digestate via a submerged orifice close to the surface. In this case, extraction is generally “passive”. This makes it possible to simply contain the biogas in the digester, but poses safety problems in the event of an uncontrolled drop in the liquid level. Indeed, in this case, biogas can escape. In addition, this solution actually has low efficiency in entraining foams/floats.

[0022] Another solution may consist of managing the consequences of foaming without trying to evacuate the foam/floatants. Thus, when foaming occurs and is detected, digestate is extracted - for example by "active" pumping - so as to partially empty the digester to prevent the foam from putting pressure on the roof of the digester. The pumped digestate is discharged into an external tank provided for this purpose. If such a device makes it possible to meet safety requirements by artificially increasing the height of the gaseous sky, it has the disadvantage of at least partially draining the contents of the digester. The reaction volume is then reduced, with negative impacts on the performance of the digester. If we can hope for a return “to normal” in the event of reversible foaming, this solution does not allow us to expect a return to normal in the event of accumulation of floaters with recurrent or even permanent foaming. In these latter cases, we then obtain “sustained” operation of the digester with an increased gas phase volume detrimental to the safety objective with regard to the risk of explosion, associated with a reduction in the effective volume of the digester. , therefore its processing capacity.

[0023] Document WO 2009/118320 proposes a digester aimed at reducing the explosion effect distances by minimizing the explosive volume using a space provided to allow the biogas to escape from the sludge. without causing light surfactant-type foams, while allowing the accumulation of a certain volume of floats (excluding light foams) and managing the RVE. With this in mind, the digester includes an inverted bell which recovers the biogas produced and a device allowing access to the agitator to be able to extract it without requiring emptying of the digester. In addition, (industrial) water injection is used to reduce any foam formed in the digester and cool the biogas. This digester, however, has several drawbacks. On the one hand, if the water supply stops, the foaming can no longer be contained by the digester. The foam can then invade the biogas network, with risks of non-functioning of the flare and high pressure losses in the networks, leading to exceeding the rupture pressure in the digester. On the other hand, if the water injection described in WO 2009/118320 makes it possible to break up light foams (like white surfactant foams), it is not effective against thick and greasy foams caused by sludge. filamentous biologicals and/or floating ones coated in fat and saturated with biogas, with consequences similar to those encountered in the event of stopping the supply of water. In particular, in the event of overflow of the digester, we observe a very rapid clogging of the biogas network, as well as any additional safety valves, which initially results in causing sludge to escape through the basin. supply, then, in a second step, a direct outlet of the biogas produced by this same basin.

[0024] An evacuation of the foams/floats is envisaged, but it is planned towards a tank placed outside the digester. The gas phase of this external tank communicates with the gaseous sky of the digester, so that it is not easy to extract the floating foams from this external tank without at the same time causing a biogas leak generating risks of explosion outside the digester, with the disadvantages and risks mentioned above.

[0025] Document US 4530762 describes a digester comprising a device for removing foam/floating digestate. Any content accessing the first tank within the enclosure of this digester appears to be transferred to the first zone of the tank. The tanks are intended to recover the treated effluent and are placed on a bed of tubular decanters. The second tank is a gas separator. In normal operation, a wall must be positioned with its upper end in horizontal alignment with the edges of the tanks. By raising the wall, this allows foam to be driven out of the tanks. Then the foams are collected in the tank and blown out of the tank when necessary. In other words, to consider the evacuation of foams, the wall must be in a high position compared to the nominal position, and therefore at a higher altitude than the edges of the tanks. Furthermore, in this digester, it is impossible to collect the foams with a first submerged tank.

Finally, document US 5228995 describes a reduced gaseous sky digester with an enclosure composed of three zones:

- the first lower zone contains the digestate,

- the second middle zone is made up of a steel structural support to accommodate a filter media forming an attachment surface to a biological deposit. This zone is a solid/liquid/gas separation zone,

- The third upper zone contains the clarified liquid fraction. The treated effluent is extracted from this area by a submerged piping system and a treated effluent control system.

Therefore, this digester requires an additional foam flap system to function correctly. [0027] There is therefore a need for a reduced gas digester, simple to implement, making it possible both to maintain the integrity of the structure in the event of an RVE phenomenon and to evacuate the foams whatever the density of the foams, that is to say capable of evacuating not very dense foams but also fatty and thick foams.

The invention aims to overcome all or part of the problems cited above by proposing a reduced gaseous top digester comprising a foam evacuation device operating by gravity and by a double overflow device. In one embodiment, the digester comprises a digestate mixing device coupled to a digestate injection device into the gaseous sky, serving both to direct the foams and floating on the surface towards the first evacuation overflow and to fold down the foams by mechanical effect. Such a digester makes it possible to reconcile operational safety and reduction in the volume of the gaseous sky of the digester, which thus reduces the level of the overpressure thresholds and distances of effects of the explosion by action on the two adjustable parameters which are the pressure of rupture of the structure and the explosive volume (volume of the gaseous sky).

[0029] For this purpose, the subject of the invention is a digester intended for the implementation of a sludge methanization treatment to generate biogas and a digestate, the digester comprising:

- an enclosure intended to contain a volume of material, the volume of material comprising the digestate, the digestate comprising on its surface foams and/or floats coming from the sludge or generated during the methanization treatment, the enclosure defining a first equal volume to the volume of material and a second volume placed above the first volume;

- a roof intended to close the enclosure;

- a tank near the enclosure and intended to collect the digestate;

- a dome placed on a portion of the roof, and intended to collect the biogas, the digester being characterized in that it comprises a device for evacuating foam and/or floating digestate comprising:

- a first tank placed in the enclosure and delimited by a first wall, the first tank being intended to be supplied with digestate and foam and/or floating from the volume of material by overflow above the first wall;

- a second tank connected to the atmosphere and located outside the enclosure, comprising:

o a first zone delimited by a second wall; and o a second zone in communication with the reservoir;

- a conduit connecting the first tank via a first orifice to the first zone of the second tank via a second orifice,

- the first zone being intended to be supplied with digestate and foams and/or floats from the first tank via the conduit;

the second zone of the second tank being intended to be supplied with digestate from the first zone of the second tank by overflow above the second wall;

the second orifice being located at an altitude greater than or equal to that of the first orifice;

the upper end of the first wall being located at a first height above a reference point of the first orifice and the upper end of the second wall being located at a second height above the reference point of the first orifice;

the first height and the second height being predefined so that a first mixture of variable proportions of digestate and foams and/or floating in the first tank having a first average density is transferred by gravity into the first zone containing a second mixture of proportions digestate variables and foams and/or floats of second density, the transfer taking place as long as the product of the first average density by the first height is greater than the product of the second average density by the second height by the first height.

[0030] In one embodiment, the digester according to the invention further comprises a device for mixing the volume of material placed in the first volume, the mixing device being configured to set the volume of material in motion.

Advantageously, the mixing device comprises:

- One or more chimneys extending into the enclosure along a first axis, preferably at the periphery of the enclosure, each chimney having an upper end and a lower end;

- One or more first agitators, each being preferably positioned under the lower end of one of the chimneys, the first agitator(s) being configured to set in motion the volume of material in rotation around a vertical central axis, substantially parallel to the first axis and in translation along the first axis from the upper end towards the lower end of said chimney.

[0032] Advantageously, the mixing device comprises one or more second agitators, each being arranged in the enclosure, preferably in the bottom of the enclosure, and even more preferably at the periphery of the enclosure, the second agitators being configured ) to set in motion the volume of material in rotation around a vertical central axis, substantially parallel to the first axis.

[0033] In another embodiment, the digester according to the invention further comprises a device for injecting digestate into the second volume, preferably placed in the center of the roof, and/or into the volume of material.

[0034] Advantageously, the digestate injection device comprises:

- A first injector fixed to the roof, preferably in the center of the roof, and in fluid connection with the second volume and configured to inject digestate into the second volume;

- A first recirculation loop between the first volume and the first injector;

- A first recirculation pump configured to recirculate digestate in the first recirculation loop from the first volume to the first injector.

[0035] Advantageously, the digestate injection device further comprises:

- A second injector fixed to a side wall of the enclosure at a first height and in fluid connection with the enclosure and configured to inject digestate into the enclosure at the first height;

- A second recirculation loop between a second height of the enclosure, lower than the first height and the second injector;

- A second recirculation pump configured to recirculate digestate in the second recirculation loop from the second height of the enclosure and towards the second injector.

[0036] In another embodiment, the first recirculation loop and the second recirculation loop are grouped into one and the same recirculation loop, the first recirculation pump and the second recirculation pump forming one and the same recirculation pump. recirculation configured to recirculate digestate towards the first injector and/or towards the second injector.

Advantageously, the roof is made of metal.

[0038] The invention will be better understood and other advantages will appear on reading the detailed description of an embodiment given by way of example, description illustrated by the attached drawing in which:

[0039] Figure 1 schematically represents a digester according to the invention;

[0040] Figure 2 schematically represents a device for evacuating foam and/or floats from a digester according to the invention;

[0041] Figure 3 schematically represents an embodiment of a digester according to the invention;

[0042] Figure 4 schematically represents another embodiment of the digester according to the invention;

[0043] Figure 5 schematically represents another embodiment of the digester according to the invention;

[0044] Figure 6 schematically represents another embodiment of the digester according to the invention;

[0045] Figure 7 schematically represents another embodiment of the digester according to the invention;

[0046] Figure 8 schematically represents a sectional view of an embodiment of the digester according to the invention.

[0047] In these figures, for the sake of clarity, the scales are not respected. Furthermore, the same elements will carry the same references in the different figures.

[0048] The invention generally applies to digesters of 50 to 16,000 m ³ , and advantageously of 500 to 7,000 m ³ .

[0049] Figure 1 schematically represents a digester 10 according to the invention. The digester 10 is intended for the implementation of a sludge methanization treatment to generate biogas 11 and a digestate 12. The digester 10 comprises an enclosure 13 intended to contain a volume of material 14, the volume of material 14 comprising the digestate 12. The enclosure 13 preferably has a circular section. The digestate includes on its surface foams and/or floats 16 coming from the sludge or being generated during the methanization treatment. The enclosure 13 defines a first volume 14 equal to the volume of material and a second volume 17 arranged above the first volume 14. The digester 10 comprises a roof 18 (or upper wall) intended to close the enclosure 13. It comprises also a tank 19 near the enclosure 13 and intended to collect the digestate 12. The tank 19 is connected to the enclosure. It can be contiguous to the enclosure or close to the enclosure, so as to allow a gravity transfer of the digested sludge (the digestate 12) for example by a direct fall or by an indirect fall by ίο through a slope . Finally, the digester 10 comprises a dome 22 placed on a portion of the roof 18, and intended to collect the biogas 11.

[0050] According to the invention, the digester 10 comprises a device 32 for evacuating the foams and/or floats 16 from the digestate 12. The device 32 for evacuating the foams and/or floats 16 from the digestate 12 is shown schematically on Figure 1. It is presented in detail below.

[0051] Figure 2 schematically represents a device 32 for evacuating foams and/or floats 16 from a digester according to the invention. The device 32 for evacuating foams and/or floats 16 from the digestate 12 comprises a first tank 33 placed in the enclosure 13 and delimited by a first wall 100, and a second tank 34 connected to the atmosphere and located 10 l outside the enclosure 13. The evacuation device 32 further comprises a conduit 37 connecting the first tank 33 to the second tank 34.

More precisely, the first tank 33 is intended to be supplied with digestate 12 and foams and/or floats 16 from the volume of material 14 by overflow above the first wall 100.

[0053] The second tank 34 comprises a first zone 35 delimited by a second wall

103, and a second zone 36 in communication, direct or indirect, with the tank 19. The first zone 35 is intended to be supplied with digestate 12 and foams and/or floats 16 from the first tank 33 via conduit 37. second zone 36 of the second tank 34 is intended to be supplied with digestate from the first zone 35 of the second tank 34 by 20 overflows above the second wall 103. The second zone 36 is connected to the tank 19. The second orifice 102 is located at an altitude greater than or equal to that of the first orifice 101. The term altitude is to be understood as a measurement of the height along an axis along which the enclosure 13 extends.

[0054] The conduit 37 connects the first tank 33 via a first orifice 101 to the first zone 35 of the second tank 34 via a second orifice 102. In other words, the first orifice 101 is the interface between the first tank 33 and the conduit 37, and the second orifice 102 is the interface between the conduit 37 and the first zone 35 of the second tank 34. To facilitate the flow of foams and/or floats, the orifice 102 is located at a higher level or equal to that of port 101.

[0055] As can be seen in Figure 2, the upper end of the first wall 100 is located at a first height hl above a reference point 1001 of the first orifice 101. The upper end of the second wall 103 is located at a second height h2 above the reference point 1001 of the first orifice 101. The reference point 1001 of the first orifice 101 can be located at the lowest point of the first orifice 101. It can also be from the center of the first orifice 101 (as shown in Figure 2) in the case of an orifice with a circular section. In other words, the two heights hl and h2 are measured from the same altitude, that of the previously chosen reference point.

[0056] According to the invention, the first height hl and the second height h2 are predefined so that a first mixture of variable proportions of digestate and foam and/or floating in the first tank 33 having a first average density dl is transferred by gravity in the first zone 35 containing a second mixture of variable proportions of digestate 12 and foams and/or floats 16 of second density d2, the transfer taking place as long as the product of the first average density dl by the first height hl is greater than the product of the second average density d2 by the second height h2 by the first height hl. In other words, the evacuation of the foams/floats 16 by the evacuation device 32 takes place as long as the relationship dl*hl > d2*h2 is respected.

This relationship is established by omitting the pressure losses in the conduit 37 and the orifices 101, 102 as well as the difference between the pressure of the gas phase above the first tank 33 and the atmospheric pressure of the second tank 34. A more detailed calculation taking into account the impact of pressure losses and pressure differences can be carried out by a person skilled in the art, a specialist in fluid mechanics. Such a calculation would only marginally modify the relationship stated above. In any case, by defining the first height hl and the second height h2 so that a first mixture of average density dl is transferred by gravity into the first zone 35 containing a second mixture of density d2 based on the relationship dl *hl > d2*h2, the transfer takes place. Taking into account the effects of pressure losses in the transfer pipe and its orifices (101, 37, 102) and differential pressure between the digester and the outside, which those skilled in the art know how to determine, the transfer takes place for a mixture with a density close to dl or higher. Taking into account the effects of pressure losses and differential pressure of the digester will have a negligible impact on the density of the mixture. More precisely, if we define hl and h2 from the relation dl *hl > d2*h2, the device will allow the transfer of a mixture up to a density very close to dl (with a deviation of the order of a few % compared to dl, deviation that a person skilled in the art knows how to determine taking into account all the effects mentioned).

[0058] By way of illustration and in a non-limiting manner, the evacuation device 32 can be dimensioned based on extreme hypotheses unfavorable to the flow from the tank 33 towards the tank 34. Thus and by way of For example, the maximum density value d2 can be considered equal to 1.05 and corresponding to a dense digestate not containing foam and/or floats. Likewise, the minimum density value dl can be considered equal to 0.3 and corresponding to a mixture composed essentially of foams and/or floats. Based on the relationship above, we deduce that as soon as hl > 3.5 x h2 (with 3.5 = 1.05 / 0.3), then a mixture of density 0.3 or more will be able to evacuate by gravity flow from tank 33 to tank 34 containing a mixture of density 1.05 or less. The values of the heights hl, h2 are generally fixed at the construction of the digester with the evacuation device 32. However, it is also possible to provide walls 100 and/or 103 with variable heights hl and h2, which can be adjusted later. to the manufacture and/or installation of the evacuation device 32.

[0059] Thanks to the foam/floating evacuation device 32 16, the foam/floating evacuation can be carried out by overflow with regular and continuous operation of the digester.

[0060] Figure 3 schematically represents an embodiment of a digester 200 according to the invention. The digester 200 shown in Figure 3 is identical to the digester 10 shown in Figure 1. The digester 200 further comprises a mixing device 20 for the volume of material 14 disposed in the first volume 14. The mixing device 20 is configured to set in motion the volume of material 14. The mixing device 20 imparts a rotational movement to the volume of material 14 in such a way that the foams and/or floats 16 entrained with the digestate 12 are extracted from the volume of material 14 with the digestate 12 by overflow 100 into the first tank 33. The mixing device 20 makes it possible to avoid the accumulation of foam and/or floats 16 at a point on the surface of the volume of material 14 remote from the first tank 33.

The digester 200 may further comprise a device 21 for injecting digestate 12 into the second volume 17 and/or into the volume of material 14. The injection device 21 makes it possible to inject digestate 12 into the second volume 17 above the volume of material 14. The injection device 21 is preferably arranged in the center of the roof 18. The injection of digestate 12 above the volume of material 14 serves to project the foams and/or floats 16 , tending to accumulate in the center of the surface, towards the periphery where they are carried towards the first tank 33 to be extracted from the volume of materiall4. The driving of the foams and/or floats 16 towards the tank 33 is favored by the rotational movement of the volume of material 14 generated by the mixing device 20.

The injection device 21 can also be located on the periphery of the enclosure 13. The injection of digestate 12 from the side wall above the volume of material 14 is carried out with a jet oriented so as to produce a rotational movement of the volume of material around a vertical axis. This rotational movement drives the foam and/or floats towards the tank 33.

[0063] Figure 4 schematically represents another embodiment of a digester 210 according to the invention. In this embodiment, the digester 210 comprises the injection device 21 and the mixing device 20. Although the presence of these two devices is preferred, the invention also covers any digester includes only an injection device 21 or only a mixing device 20.

The mixing device 20 comprises one or more chimneys 23 extending into the enclosure 13 along a first axis 24, preferably at the periphery of the enclosure 13. Each chimney 23 has an upper end 61 and a lower end 62 By chimney is meant a hollow body extending along the first axis 24. The chimneys 23 can have a circular or polygonal section. In a preferred embodiment, the chimneys are half-cylinders fixed, for example by welding or riveting, to the side wall of the enclosure 13. The mixing device 20 comprises one or more first agitators 25. Each of the first agitators 25 is associated with one among the plurality of chimneys 23. In other words, each chimney 23 has its first agitator 25. Each of the first agitators is preferably positioned under the lower end 62 of its chimney 23. The first one or more agitators 25 are configured to set in motion the volume of material 14 in rotation around a vertical central axis 60, substantially parallel to the first axis 24, and in translation along the first axis 24 from the upper end 61 towards the lower end 62 of said chimney 23. In other words, the first agitators 25 are oriented so as to impart a rotational movement to the digestate 12 according to the movement represented by the arrow 271 and a movement from bottom to top in the volume 14 via the reverse movement from top to bottom through the chimney 23 represented by the arrow 251. We can qualify this movement as a combination of a horizontal rotation around the axis 60 and vertical movement from the top of the chimney towards the bottom of the 'pregnant. The flow of digestate at the suction of the agitator 25 is channeled from the surface by means of the chimney 23. This creates the vertical displacement and the orientation of the agitator 25 creates a horizontal rotation in addition to the rotation generated by the lateral injection device 21. The upper end 61 of the chimney(s) 23 is positioned under the surface of the material of the material volume 14 (for example 250 mm below the highest level low digestate). Thus, digestate 12 falls into the chimney(s) 23. The assembly formed by a chimney 23 and a first agitator 25 contributes to destratifying the volume of material 14 by producing pumping from the bottom to the top of the volume of matter 14.

Preferably, fresh sludge can be injected into the chimney 23 to promote effective mixing of the fresh sludge with the rest of the digestate. For example, the fresh sludge supply rate can be of the order of 30 m3/h while the pumping rate provided by a first agitator 25 can be of the order of 2500 m3/h, i.e. a ratio of the order of 1/100.

The mixing device 20 may also comprise one or more second agitators 27, each being arranged in the enclosure 13, preferably in the bottom of the enclosure 13, and even more preferably on the periphery of the enclosure 13. The second agitators 27 are configured to set in motion the volume of material 14 in rotation around the vertical central axis 60, substantially parallel to the first axis 24. Thus, the second agitators 27 are oriented so as to produce a rotational movement to the digestate 12 according to the movement represented by arrow 271. We can qualify this rotational movement as horizontal movement. Those skilled in the art know how to determine the appropriate characteristics (size, shape, rotation speed, etc.) of the agitators 25, 27 and orient the axes 26, 28 of the agitators 25, 27 according to the viscosity of the material to be stirred and the volume of material 14 considered.

[0067] The horizontal movement moves the foams/floats towards the periphery of the enclosure. The vertical movement moves the foams/floats from the upper surface of the material volume 14 towards the bottom of the enclosure. The combination of these two movements prevents the formation and/or stagnation of foam/floats on the surface of the volume of material and better mixing of the contents of the enclosure is obtained.

[0068] Figure 5 schematically represents another embodiment of a digester 220 according to the invention. In this embodiment, the digestate injection device 21 comprises a first injector 29 fixed to the roof, preferably in the center of the roof, and in fluid connection with the second volume 17 and configured to inject digestate 12 into the second volume 17 The injection device 21 comprises a first recirculation loop 30 between the first volume 14 and the first injector 29. Finally the injection device 21 comprises a first recirculation pump 31 configured to recirculate digestate 12 in the first loop. recirculation 30 from the first volume 14 to the first injector 29. The injection of digestate into the second volume aims to reduce the foams/floats and make them move towards the periphery of the enclosure.

The dome 22 may include two safety valves 40, 41 arranged opposite each other.

The roof 18 is generally substantially flat. If it is made of metal, it can be either concave (if the pressure applied to the roof is less than 5 mbar) or convex (if the pressure applied to the roof is greater than 5 mbar).

[0071] Figure 6 schematically represents another embodiment of a digester 230 according to the invention. In this embodiment, the digestate injection device 21 comprises a second injector 39 fixed to a side wall of the enclosure 13 at a first height 53 and in fluid connection with the enclosure 13, and more precisely the volume of material 14, and configured to inject digestate 12 into the enclosure 13, into the volume of material 14. The injection device 21 comprises a second recirculation loop 50 between a second height 52 of the enclosure 13, lower than the first height 53 and the second injector 39. Finally, the injection device 21 comprises a second recirculation pump 51 configured to recirculate digestate 12 in the second recirculation loop 30 from the second height 52 of the enclosure 13 and towards the second injector 39. In other words, the injection device of the digester 130 is configured to inject digestate initially in the lower part of the enclosure towards a higher part of the volume of material. As already mentioned, this injection helps to set the material in the enclosure in motion and to rotate the foams/floats on the surface to prevent their stagnation and send them towards the periphery of the enclosure, towards the chimneys 23 and the tank 33 Alternatively, or in addition, the digestate injection device 21 comprises a second injector 49 fixed to a side wall of the enclosure 13 at a first height 54 and in fluid connection with the enclosure 13 and configured to inject digestate. 12 in the enclosure 13 at the first height 54, the first height 54 being at the level of the second volume 17. Similar to what was explained previously, the injection device 21 comprises a second recirculation loop 50 between a second height 52 of the enclosure 13, lower than the first height 54 and the second injector 49. And the injection device 21 comprises a second recirculation pump 51 configured to recirculate digestate 12 in the second recirculation loop 30 from the second height 52 of the enclosure 13 and towards the second injector 49. This injection of digestate 12 above the volume of material 14 forms a jet oriented relative to the upper surface of the volume of material 14 so as to produce a movement rotation of the volume of material around the vertical axis 60. This rotational movement drives the foams and/or floats towards the tank 33.

[0072] This embodiment may include a single second injector 39, 49 on the side wall of the enclosure. But it can also include several second injectors 39, 49 distributed all around the wall, with one or more recirculation loops adapted to this configuration, linked to the second recirculation pump.

[0073] The digester according to the invention can comprise either one of the two recirculation loops, or a double recirculation, that is to say the two recirculations described previously, with the first recirculation loop and the second recirculation loop. recirculation. In a preferred embodiment, the two recirculation loops are shared.

[0074] Figure 7 schematically represents another embodiment of a digester 240 according to the invention. In this embodiment of the digester according to the invention, the first recirculation loop 30 and the second recirculation loop 50 are grouped into one and the same recirculation loop, the first recirculation pump 31 and the second recirculation pump 51 forming one and the same recirculation pump configured to recirculate digestate 12, alternatively or simultaneously, towards the first injector 29 and/or towards the second injector 39. Alternatively, or in addition, the second recirculation loop can be connected to the second injector 49 fixed to the side wall of the enclosure 13 at the first height 54 and in fluid connection with the enclosure 13 and configured to inject digestate 12 into the enclosure 13 at the first height 54, in the volume 17.

[0075] Figure 8 schematically represents a sectional view of an embodiment of the digester 240 according to the invention. The cut is made at the level of the enclosure 13, perpendicular to the central vertical axis 60, making visible the elements present in (or connected to) the enclosure 13 for a better representation of the digester of the invention. Note that the foam/floating evacuation device is not shown in this figure.

[0076] At the periphery of the enclosure 13, that is to say near the side walls of the enclosure, a second agitator 27 is present to impart a so-called horizontal rotational movement (represented by the arrow 271) to the volume of material 14 and therefore to the foams/floats which are on the upper surface of the volume of material. Only one second agitator 27 is shown but there could be more than one. The agitator(s) 27 can be located on the periphery of the enclosure 13 but they can also be located more in the center of the enclosure. Two first agitators 25 are present to impart a so-called vertical rotational movement to the volume of material 14 and therefore to the foams/floats which are on the upper surface of the volume of material. The first agitators 25 are each positioned under a chimney 23. Thus, the foams/floats present on the surface of the volume of material 14 are moved from the center towards the periphery by the so-called horizontal rotational movement thanks to the second agitators 27. Then, arriving in periphery of the enclosure 13, the foams/floats descend through the chimneys 23 following the so-called vertical rotational movement generated by the first agitators 25. The injection of additional mud into the chimneys 23 contributes to effective mixing of the injected mud with the rest of the digestate already present in the enclosure.

[0077] Two recirculation pumps 31, 51 are shown. The first recirculation pump 31 is associated with the first recirculation loop (not shown) and aims to inject digestate 12 taken from the bottom of the enclosure 13 at the level of the gaseous sky (second volume 17) by the first injector 29. The digestate is injected by the first injector above the volume of material 14, onto the foams/floats present on the surface. The foams/floats are thus folded down. This injection also helps to make them move towards the periphery of the enclosure.

[0078] The second recirculation pump 51 is associated with the second recirculation loop (not shown) and aims to inject digestate 12 taken from the bottom of the enclosure 13 into the volume of material 14 at a height greater than the height from which the digestate was taken. This lateral injection sets the volume of material in motion and contributes to moving the foams/floats on the surface by initiating a rotational movement to prevent their stagnation and send them towards the periphery of the enclosure, towards the chimneys 23. In other words, the second recirculation loop aims to inject digestate from a lower level of the enclosure into the digestate at a higher level of the enclosure to destratify the volume of material. The second recirculation pump 51 associated with the second recirculation loop (not shown) can also aim to inject digestate 12 taken from the bottom of the enclosure 13 into the volume of material 14 at a height greater than the height at which the digestate was taken to inject the digestate taken into the second volume, above the volume of material 14. This injection contributes to the rotational movement of the volume of material around the vertical axis 60. This rotational movement helps to direct the foams and/or floating towards the tank 33.

As explained previously, the first recirculation loop 30 and the second recirculation loop 50 can be grouped into a single recirculation loop. This single recirculation loop can be powered by the first recirculation pump 31 and the second recirculation pump 51. Alternatively, the first recirculation pump 31 and the second recirculation pump 51 can form a single and same recirculation pump configured to make recirculate digestate 12 towards the first injector 29 and towards the second injector 39, 49, either simultaneously or alternately.

[0080] Finally the digester 240 also comprises a dome 22 arranged on a portion of the roof 18, and intended to collect the biogas IL Advantageously, the dome is arranged substantially above a chimney 23. The mixture of digestate 12, of foams/floating 16 and freshly introduced mud which takes place at the level of the chimney 23 can make it possible to release pockets of biogas which will escape through the upper end 61 of the chimney 23. It is therefore judicious to position the dome 22 near the upper end 61 of the chimney 23.

[0081] Advantageously, the dome is arranged substantially on the periphery of the roof 18 and above a second injector 39 fixed on the side wall of the digester in the volume 17. The injection of digestate 12 by the injector causes an effect mechanical foam flap which therefore protects the dome from possible foam intrusions.

[0082] In a particular embodiment of the invention, the digester may further comprise a valve placed downstream of the second tank 34, for example at the level of a conduit at the outlet of the second tank 34. It may be any suitable type of valve, such as a pinch valve (pneumatic or mechanical) or a gate valve. The valve makes it possible to control the flow rate of evacuation of the contents of the second tank 34. In the closed position of the valve, there is no evacuation of the contents towards the tank 19. This makes it possible to increase the level of the contents in the digester enclosure and thus facilitate the entrainment of foams/floats by instant opening of the valve. Opening the valve in this way has the effect of flushing. The digester can optionally include a valve activation device to open and close it. The digester may also include a programmer intended to trigger the valve activation device at predefined time intervals, so as to allow preventive evacuation of foams and floats. This results in better control of the quantity of foam/floating material in the digester enclosure.

[0083] The invention proposes a reduced gas digester making it possible to evacuate the foams/floating whatever their density and to maintain the integrity of the structure in the event of an RVE phenomenon. This is made possible thanks to the foam/floating evacuation device operating by gravity with a double overflow device. In addition, the injection device helps move the foams/floats towards the periphery of the enclosure and the mixing device also helps move the foams/floats towards the bottom of the enclosure. The combination of the injection device and the mixing device ensures both very good mixing of the foams and/or floats with the digestate to promote their reincorporation into the digestate, and both good evacuation by overflow of the foams and/or or floating not reincorporated.

[0084] The invention also relates to a digestion process by implementing a sludge methanization treatment to generate biogas 11 and a digestate 12 in a digester as described above. The digestate includes on its surface foams and/or floats 16 coming from the sludge or generated during the methanization treatment. The digestion process according to the invention comprises a step of managing foams and/or floats by evacuation according to their density. This management stage includes:

- a step of supplying the first tank 33 with digestate 12 and foams and/or floats 16 from the volume of material 14 by overflow above the first wall 100, and

- a step of supplying the first zone 35 of the second tank 34 with digestate 12 and foams and/or floats 16 from the first tank 33 via conduit 37,

- a step of supplying the second zone 36 of the second tank 34 with digestate from the first zone 35 of the second tank 34 by overflow above the second wall 103.

[0085] As detailed previously, the conduit 37 connects the first tank 33 via the first orifice 101 to the first zone 35 of the second tank 34 via a second orifice 102, the second orifice 102 being located at an altitude greater than or equal to that of the first orifice 101, and the upper end of the first wall 100 being located at a first height hl above a reference point of the first orifice 101 and the upper end of the second wall 103 being located at a second height h2 above the reference point of the first orifice 101. The first height hl and the second height h2 are predefined so that a first mixture of variable proportions of digestate and foams and/or floats in the first tank 33 having a first average density dl is transferred by gravity into the first zone 35 containing a second mixture of variable proportions of digestate and foams and/or floats of second density d2, the transfer taking place as long as the product of the first average density dl by the first height hl is greater than the product of the second average density d2 by the second height h2 by the first height hl.

Advantageously, the digestion process according to the invention further comprises a step of mixing the volume of material 14.

Advantageously, the digestion process according to the invention further comprises a step of injecting digestate into the volume of material 14 and/or into the volume 17.

[0088] It will appear more generally to those skilled in the art that various modifications can be made to the embodiments described above, in light of the teaching which has just been disclosed to them. In the claims which follow, the terms used should not be construed as limiting the claims to the embodiments set forth in the present description, but should be construed to include all equivalents which the claims are intended to cover by their wording and the prediction of which is within the reach of those skilled in the art based on their general knowledge.

Claims (9)

1. Digester (10, 200, 210, 220, 230, 240) intended for the implementation of a sludge methanization treatment to generate biogas (11) and a digestate (12), the digester (10, 200 , 210, 220, 230, 240) comprising: - an enclosure (13) intended to contain a volume of material (14), the volume of material (14) comprising the digestate (12), the digestate comprising on its surface foams and/or floats (16) coming from sludge or generated during the methanization treatment, the enclosure (13) defining a first volume (14) equal to the volume of material and a second volume (17) arranged above the first volume (14); - a roof (18) intended to close the enclosure (13); - a tank (19) near the enclosure (13) and intended to collect the digestate (12); - a dome (22) placed on a portion of the roof (18), and intended to collect the biogas (11), the digester being characterized in that it comprises a device for evacuating (32) moss and/or floating (16) of the digestate (12) comprising: - a first tank (33) arranged in the enclosure (13), the first tank being immersed in the volume of material (14) and delimited by a first wall (100), the first tank (33) being intended to be supplied in digestate (12) and in foams and/or floats (16) from the volume of material (14) by overflow above the first wall (100); - a second tank (34) connected to the atmosphere and located outside the enclosure (13), comprising: o a first zone (35) delimited by a second wall (103); and o a second zone (36) in communication with the reservoir (19); - a conduit (37) connecting the first tank (33) via a first orifice (101) to the first zone (35) of the second tank (34) via a second orifice (102), - the first zone (35) being intended to be supplied with digestate (12) and foams and/or floats (16) from the first tank (33) via the conduit (37); the second zone (36) of the second tank (34) being intended to be supplied with digestate from the first zone (35) of the second tank (34) by overflow above the second wall (103); the second orifice (102) being located at an altitude greater than or equal to that of the first orifice (101); the upper end of the first wall (100) being located at a first height (hl) above a reference point of the first orifice (101) and the upper end of the second wall (103) being located at a second height (h2) above the reference point of the first orifice (101) and the upper end of the second wall (103) being at a lower altitude than that of the upper end of the first wall (100); the first height (hl) and the second height (h2) being predefined so that a first mixture of variable proportions of digestate and foams and/or floating in the first tank (33) having a first average density (dl) is transferred by gravity in the first zone (35) containing a second mixture of variable proportions of digestate and foams and/or floats of second density (d2), the transfer taking place as long as the product of the first average density (dl) by the first height (hl) is greater than the product of the second average density (d2) by the second height (h2) by the first height (hl). 2. Digester (200, 210, 220, 230, 240) according to claim 1, further comprising a mixing device (20) of the volume of material (14) disposed in the first volume (14), the mixing device ( 20) being configured to set in motion the volume of material (14). 3. Digester (200, 210, 220, 230, 240) according to claim 2, in which the mixing device (20) comprises: -One or more chimneys (23) extending into the enclosure (13) along a first axis (24), preferably at the periphery of the enclosure (13), each chimney (23) having an upper end (61) and a lower end (62); - One or more first agitators (25), each being preferably positioned under the lower end (62) of one of the chimneys (23), the first agitator(s) (25) being configured to set the volume in motion of material (14) in rotation around a vertical central axis (60), substantially parallel to the first axis (24) and in translation along the first axis (24) from the upper end (61) towards the lower end ( 62) of said chimney (23). 4. Digester (200, 210, 220, 230, 240) according to any one of claims 2 or 3, wherein the mixing device (20) comprises one or more second agitators (27), each being arranged in the enclosure (13), preferably in the bottom of the enclosure (13), and again preferably at the periphery of the enclosure (13), the second agitators (27) being configured(s) to set in motion the volume of material ( 14) in rotation around a vertical central axis (60), substantially parallel to the first axis (24). 5. Digester (200, 210, 220, 230, 240) according to any one of claims 1 to 4, further comprising a device for injecting (21) digestate (12) into the second volume (17), preferably arranged in the center of the roof (18), and/or in the volume of material (14). 6. Digester (220, 240) according to claim 5, in which the digestate injection device (21) comprises: - A first injector (29) fixed to the roof, preferably in the center of the roof, and in fluid connection with the second volume (17) and configured to inject digestate (12) into the second volume (17); - A first recirculation loop (30) between the first volume (14) and the first injector (29); - A first recirculation pump (31) configured to recirculate digestate (12) in the first recirculation loop (30) from the first volume (14) to the first injector (29). 7. Digester (230, 240) according to any one of claims 5 or 6, in which the digestate injection device (21) further comprises: - A second injector (39, 49) fixed to a side wall of the enclosure (13) at a first height (53, 54) and in fluid connection with the enclosure (13) and configured to inject digestate (12) in the enclosure (13) at the first height (53, 54); - A second recirculation loop (50) between a second height (52) of the enclosure (13), lower than the first height (53, 54) and the second injector (39, 49); - A second recirculation pump (51) configured to recirculate digestate (12) in the second recirculation loop (30) from the second height (52) of the enclosure (13) and towards the second injector (39, 49 ). 8. Digester (240) according to claim 7, in which the first recirculation loop (30) and the second recirculation loop (50) are grouped into a single recirculation loop, the first recirculation pump (31) and the second recirculation pump (51) forming a single recirculation pump configured to recirculate digestate (12) towards the first injector (29) and/or towards the second injector (39, 49). 9. Digester (10, 200, 210, 220, 230, 240) according to any one of claims 1 to 8, in which the roof (18) is made of metal.