ITVR20120091A1 - PLANT AND PROCEDURE FOR THE DISPOSAL OF THE LOAD OF NITROGEN OF ORGANIC WASTE IN ZOOTECHNICAL BREEDS. - Google Patents

Description

â € œPLANT AND PROCEDURE FOR THE DISPOSAL OF THE NITROGEN LOAD OF ORGANIC WASTE IN ZOOTECHNICAL FARMERSâ €

TECHNICAL FIELD OF INVENTION

The present invention refers to a plant and a process to be used in zootechnical farms, both of cattle, pigs and other animals, for the reduction of the nitrogen load of the related organic waste.

STATE OF THE PRIOR ART

Livestock farms are very often faced with the problem of the high percentage of nitrogen present in the organic waste of farmed animals.

The nitrogen component present in the wastewater, consisting mainly of NH4 and nitrates, is in fact a serious problem for the farmer. In fact, he is forced, through a substantial economic and time expenditure, to break down this component, in order to be able to spread such wastewater on agricultural land.

In fact, in the so-called â € œNitrates Directiveâ €, that is to say in the Community Directive 91/676 / EEC, the percentage of these compounds that can be present in organic waste of animal origin is regulated by determining stringent limits, so that they can be disposed of through their distribution on agricultural land.

The techniques currently used for reducing the nitrogen load in wastewater are essentially: separation, nitro / de-nitro, stripping, flotation, photocatalysis.

However, these methods have the disadvantage of being rather expensive in terms of both the construction of the plant and its maintenance, as is the case with the stripping and photocatalysis techniques, and above all they do not involve recycling of the nitrogen removed from the wastewater itself. .

This last aspect constitutes an important advantage, also from an economic point of view, for the company itself. The nitrogen recovered from animal sewage, in fact, can for example be used as fertilizer for organic farming.

Some types of biological purification of the nitrogen load of animal waste, through the use of microalgae, are for example those reported in the literature by Pizarro et al. in 2002, from Bhatnagar et al. in 2011, by Levine et al. in 2011.

However, the data reported in the literature refer only to experiments conducted in the laboratory.

To date, there is no system capable of carrying out this type of biological wastewater purification that can be inserted in a company context.

AIMS OF THE INVENTION

An object of the present invention is to improve the state of the prior art.

Another object of the present invention is to provide a plant for the disposal of the nitrogen load of organic waste from livestock farms which is advantageous in economic terms.

A further object of the present invention is to provide an effective plant for the disposal of the nitrogen load of organic waste from livestock farms.

This task and these purposes are achieved by the plant for the disposal of the nitrogen load of organic waste from livestock farms according to the attached claim 1.

Another object of the present invention is to provide a process for the disposal of the nitrogen load of organic waste from livestock farms which is advantageous in economic terms.

A further object of the present invention is to provide an effective process for the disposal of the nitrogen load of organic waste from livestock farms.

This aim and these aims are achieved by the process for the disposal of the nitrogen load of organic waste from livestock farms according to the attached claim 18.

The dependent claims refer to preferred and advantageous forms of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

These and further advantages will be better understood by every person skilled in the art from the following description and the attached drawings, given as a non-limiting example, in which:

Figure 1 is a schematic view of the plant for the disposal of the nitrogen load of organic waste from livestock farms according to the present invention.

FORMS OF IMPLEMENTATION OF THE INVENTION

With reference to the attached figure 1, the present invention refers to a plant for the disposal of the nitrogen load of organic waste from livestock farms, indicated as a whole with 1.

This plant 1 exploits the presence of indigenous microalgae to reduce the nitrogen load of organic waste of animal origin.

These microalgae, in fact, transform the nitrogen absorbed by the sewage into â € œnobleâ € forms of nitrogen, such as proteins, chlorophyll, and other substances useful for the growth of the microalgae themselves.

Once this â € œtransformationâ € of nitrogen has taken place, the collected microalgae can be used in various ways, also depending on their final contents. In particular, microalgae can be used as (a) fish feed; (b) fertilizer for organic farming; (c) food supplement in feed, especially if rich in proteins; (d) source of high commercial value molecules, such as carotenoid pigments, proteins, polysaccharides, fatty acids; (e) source of oils for biofuel production; (f) additives in matrices to be subjected to biodigestion for biogas production.

Experiments conducted in the laboratory have shown that these microalgae are able to lower the nitrogen levels of organic waste by a percentage higher than 90%, compared to the original nitrogen content of the waste itself.

Plant 1 is a modular system, consisting of at least three tanks 2, 3, 4 placed in series as described in detail below.

These at least three tanks 2, 3, 4 are connected by means of a piping system 5.

These at least three tanks 2, 3, 4 are offset altimetrically.

In particular, plant 1 comprises a first tank 2, height H from the ground, into which organic waste 6 of animal origin from livestock farming is introduced.

The animals raised on such a livestock farm may be cattle or pigs or other animals suitable for that type of farming.

The organic waste 6 comprises a solid part and a liquid part.

This first tank 2 includes the organic wastewater 6 and â € œfreshâ € water, which is mixed with the wastewater itself.

The system 1 includes a first pipe 7 for transporting the â € œfreshâ € water, as indicated by the arrows 7â € ™.

In this first tank 2, the solid part of the wastewater 6 decants leaving the liquid part of the same on the surface which, together with the â € œfreshâ € water, extracts the nitrogen component contained in the wastewater itself. Therefore the liquid part of the waste contains the nitrogen component of the same.

In this first tank 2 the dilution and mixing phases of the wastewater 6 with â € œfreshâ € water can be repeated several times until all the nitrogen extractable from the solid part has been extracted.

In the first tank 2 the ratio between the solid part and the liquid part is substantially between 1: 1 and 1: 2. The system 1 includes a conduit 8, connecting the first tank 2 and a second tank 3 of height Hâ € ™ â € ™ from the ground. The latter contains the liquid part of the organic waste 6, transported into it by the first tank 2 via the duct 8. The second tank 3 includes â € œfreshâ € water deriving from the pipe 7.

The duct 8 comprises an inlet filter 9, capable of preventing solid particles of the solid part of the wastewater 6 from being accidentally transported to the second tank 3.

The duct 8 comprises gate means 10. The gate means 10 allow to regulate the flow from the first tank 2 to the second tank 3. The gate means 10 are positioned in a point suitable for this purpose between the inlet and the ™ duct outlet 8.

The height Hâ € ™ of the first tank 2 is greater than the height Hâ € ™ â € ™ of the second tank 3: the latter is therefore positioned below the first tank 2.

Therefore, the liquid part is transported from the first tank 2 to the second tank 3, through the duct 8, by gravity and, in a regulated manner, by the gate means 10. In this way, the presence of pumps or other forced transport systems between one tank and another.

While the first tank 2 is essentially a mixing tank for organic waste 6, the second tank 3 can be defined as a dilution tank.

In the second tank 3 the liquid part remains for a predefined time. In this way, the second tank 3 contains a solid part deposited on its bottom and a liquid part decanted of any further solid residues.

The decanted liquid part, which will come out of the second tank 3, is also sufficiently clear to allow the subsequent reactions necessary for the disposal of the nitrogen load to take place as better described below.

The plant according to the present invention comprises a third culture tank 4, of height Hâ € ™ â € ™ â € ™.

The plant 1 comprises a conduit 11, connecting the second tank 3 and the third tank 4.

The third tank 4 contains the decanted liquid part of the second tank 3, once the liquid part has been sufficiently diluted in the second tank 3, carried by the pipe 11.

Similarly to the duct 8, the duct 11 comprises an inlet filter 9, capable of preventing solid particles of the wastewater 6 from being accidentally transported to the third tank 4.

The conduit 11 comprises gate means 10. In this case, the gate means 10 allow to regulate the flow from the second tank 3 to the third tank 4. The gate means 10 are positioned in a point suitable for this purpose between the entrance and exit of the pipeline 11.

The piping system 5 therefore comprises the conduit 8 and the conduit 11.

The height Hâ € ™ â € ™ of the third tank 4 is less than the height H of the second tank 3.

Therefore, the decanted liquid part is transported from the second tank 3 to the third tank 4, through the conduit 11, by gravity and, in a regulated manner, by the gate means 10.

The third tank 4 includes a culture of native microalgae.

They are generally green unicellular algae, Chlorophyta, especially belonging to the genus Chlorella, Scenedesmus or related genera. These native microalgae, naturally present in the wastewater, are isolated from the wastewater itself in the laboratory, in order to set up monocultures of these microalgae.

These autochthonous microalgae allow the reduction of the nitrogen load contained in the decanted liquid portion of the organic waste 6.

Microalgae in the presence of â € œfreshâ € water and nitrates / ammonium grow exponentially by accumulating nitrogen in organic form in their biomass. In this way, the nitrogen is sequestered from the aqueous environment of the decanted liquid part of the organic waste 6 present in the third tank 4. The sequestration of nitrogen can reach a percentage of 98% compared to its original quantity.

The third tank 4 has predefined construction dimensions. In particular, the third basin 4 has a depth between 50 cm and 60 cm. In this way, adequate illumination is ensured over the entire thickness of the liquid part it contains, so as to allow efficient photosynthesis of the microalgae on which their growth depends.

The third tank 4 is therefore the microalgae culture tank.

The third tank 4 comprises a system for separating the microalgae from the deputy liquid resulting from the reduction of the nitrogen percentage of the decanted liquid part by said microalgae. This separation system comprises a filtration system 12 and a pumping system 13.

The filtration system 12 includes a removable filter 12â € ™ for the collection of microalgae. This filter 12â € ™ is mobile and separates from the pumping system 13.

The pumping system 13 comprises a pump 13â € ™. The 13â € ™ pump is housed in a 13â € ™ â € ™ housing.

Thanks to the pumping system 13, an outflow of the purified liquid from the tank 4 is created towards the duct 17. The purified liquid flows freely through the filtration system 12, while the microalgae are blocked on the surface of the removable filter 12â € ™. Parallel to the removable filter 12â € ™, and close to the housing 13â € ™ â € ™ of the pumping system 13, the third tank 4 comprises a mobile and removable counterwall 15 15 whose function is explained below.

The filtering system 12 represents an example of the filtering technologies available and usable in this plant, and can therefore possibly be replaced with alternative systems.

The microalgae are collected by filtration when the wastewater and / or the liquid part decanted in the tank 4 is purified from the nitrogen load.

The characteristics of the filtration 12 and pumping systems 13 depend on: 1) the volume of the liquid at the outlet, 2) the volumetric characteristics of the native microalgae selected for the present invention, 3) the need to re-introduce the purified liquid into circulation. In particular, the third tank 4 includes a step 14 for the containment of possible sediments, and the filter 12â € ™, removable for the collection of microalgae, is positioned between the step 14 and the pump 13â € ™.

The counterwall 15 is parallel to the filter 12â € ™ and removable for the collection of microalgae. The counterwall 15 is positioned in such a way as to block the flow of water during the collection of microalgae.

The steps, in detail, are the following: (a) the counterwall 15 is raised and the filter 12â € ™ is lowered; in this way, thanks to the pumping system 13, the purified liquid flows out of the tank 4 towards the duct 17; (b) the microalgae adhere to the filter with pores of smaller diameter than the cells; (c) the counterwall 15 is lowered; (d) lift and remove filter 12â € ™ with the attached microalgae for their collection.

Since the counterwall 15 is lowered, the flow of water is temporarily blocked, to allow the collection of algae.

Pump 13â € ™ recovers the purified liquid filtered by filter 12â € ™ and pumps it, putting it back into circulation through second pipes 17.

Overall, the third tank 4 is fed with water coming from the second tank 3, from the first pipe 7 and also from the recirculation through the second pipe 17. The first tank 2 and the second tank 3 can also be fed with water coming from the second pipe 17 .

The clarity of the liquid part in which the microalgae grow and the percentage of water present in at least one tank 2, 3, 4 are thus regulated.

The flow in the second pipe 17 is regulated by at least one gate means 10.

Through pump 13â € ™ it is possible to temporally separate the emptying phase of the third tank 4 from the re-introduction phase. That is, the liquid from the tank 4 passes through the conduit 17 into a temporary containment tank 18 (emptying). There is a re-introduction of liquid from the second tank 3 to the third tank 4 through the duct 11. At the same time, the re-introduction of liquid from the first tank 2 to the second tank 3 can take place through the duct 8.

From the containment tank 18 through the pipe 17 the purified water is used to dilute the tanks 4, 3 and 2.

This occurs precisely thanks to the presence, along the second pipe 17, of the temporary containment tank 18 of the purified water.

The present invention further relates to a process for the disposal of the nitrogen load of organic waste from livestock farms.

This process exploits the presence of indigenous microalgae to reduce the nitrogen load of organic waste of animal origin.

This process comprises a step of providing at least one tank 2, 3, 4.

The process according to the present invention comprises a step of connecting these at least three tanks 2, 3, 4 in series by means of a piping system 5.

This process comprises a step of positioning these at least three tanks 2, 3, 4 in an altimetrically staggered manner.

In particular, this process comprises the steps of providing a first tank 2 of height Hâ € ™ from the ground.

This procedure includes the steps of providing a second tank 3, of height Hâ € ™ â € ™ from the ground.

This process includes the steps of providing the microalgae cultivation tank 4, in which the microalgae cultivation tank 4 is a third tank 4 of height Hâ € ™ â € ™ â € ™ from the ground.

The process according to the present invention comprises a step of placing the first tank 2 in a raised position at height Hâ € ™, of placing the second tank 3 of height Hâ € ™ â € ™ in a lower position with respect to the first tank 2 and of placing the third tank 4 of height Hâ € ™ â € ™ â € ™ in a lower position than the second tank 3.

The process according to the present invention comprises a step of introducing organic waste 6 containing nitrogen of animal origin from livestock farming, comprising a solid part and a liquid part, into the first tank 2.

A phase of the procedure comprises supplying â € œfreshâ € water through a first pipe 7 and mixing the organic wastewater 6 with this â € œfreshâ € water, which is collected in the first tank 2.

In this first tank 2, the solid part of the wastewater 6 decants leaving the liquid part of the same on the surface.

The â € œfreshâ € water introduced into the first tank 2 and the liquid part of the wastewater 6 extract the nitrogen component of the wastewater.

It is possible to repeat this phase several times to supply â € œfreshâ € water and to mix until the complete extraction of the extractable nitrogen from the solid part.

The percentage of nitrogen extracted / extractable from the solid part is determined by routine laboratory analyzes.

The process according to the present invention comprises a step of transporting the liquid part from the first tank 2 to the second tank 3 through a duct 8.

The liquid part coming from the first tank 2 is diluted with â € œfreshâ € water coming from the first pipe 7 in the second tank 3, in a variable measure according to the type of waste.

The liquid part remains in the second tank 3 for a time necessary for the decanting of any further solid residues, with the obtaining of a decanted liquid part.

Once the decanted liquid part has been sufficiently diluted in the second tank 3, it is transported to the third tank 4 by means of a conduit 11.

The process according to the present invention comprises a step of providing native microalgae, of inoculating them and cultivating them in the third tank 4

These autochthonous microalgae allow the reduction of the nitrogen load contained in the decanted liquid portion of the organic waste 6, sequestrating the nitrogen from the aqueous environment of the decanted liquid part of the organic waste 6 present in the third tank 4.

The process according to the present invention further comprises a step of separating, in the third tank 4, the microalgae from the purified liquid by filtering the suspension contained in the third tank 4 by means of a filtration system 12, comprising a removable filter 12â € ™ for collecting the microalgae, obtaining purified water, and pumping the purified water by means of a pumping system 13, comprising a pump 13â € ™ housed in a housing 13â € ™ â € ™. The process according to the present invention comprises the possibility of replacing the filtration system 12 with other filtration systems suitable for the purpose of collecting algae.

This pumping allows to recover the purified liquid filtered by the filter 12â € ™ and to put it back into circulation through second pipes 17.

The process according to the present invention comprises a step of feeding purified liquid, through the second pipes 17, the tanks 2, 3, 4, thus ensuring the saving of â € œfreshâ € water coming from the first pipe 7.

Through pump 13â € ™ it is possible to temporally separate the emptying phase of the third tank 4 from the re-introduction phase. This occurs thanks to a phase of temporarily containing the purified water, along the second pipe 17, by means of a temporary containment system 18.

To verify the characteristics of the algal inoculum and its growth, it is possible to carry out nephelometric (turbidity) analyzes of the suspension contained in the third tank 4.

Depending on the quantity of wastewater to be treated, as well as the space available for the installation of this plant in the company, the invention presented will consist of modules of variable dimensions, which can be suitably multiplied in series or in parallel, in the respect for the fundamental characteristics of the present invention.

It can also be noted that at least one tank 2, 3, 4 includes â € œwaterâ € including both the purified liquid deriving from the filtering and pumping of the third tank 4, and â € œfreshâ € water from normal aqueduct pipes or of other origin.

The plant and the process according to the present invention are economically advantageous also because they provide for a water recycling system which compensates for the need to have high volumes for the cultivation of microalgae.

The solid fraction of the wastewater, remaining after the treatment, can be used according to the common agronomic spreading practices or placed in a biodigester for the production of biogas.

The microalgae remain in tank 4 until the liquid is deprived of the nitrogen load.

The invention thus conceived is susceptible of numerous modifications and variations, all of which are within the scope of the inventive concept.

Furthermore, all the details can be replaced by other technically equivalent elements, without thereby departing from the protection scope of the following claims.

Claims (25)

CLAIMS 1. Plant (1) for the disposal of the nitrogen load of organic waste (6) from livestock farms, comprising organic waste (6) containing nitrogen and at least one tank (2, 3, 4), in which said tank (2, 3, 4) comprises said organic wastewater (6) and water, characterized in that said at least one tank (4) contains a culture of native microalgae capable of reducing the percentage of nitrogen contained in said wastewater (6). 2. Plant according to claim 1, comprising a first tank (2), of height Hâ € ™ from the ground, comprising said organic wastewater (6), containing a solid part and a liquid part and water. 3. Plant according to claim 1 or 2, wherein in said first tank (2) said solid part and said liquid part have a ratio between 1: 1 and 1: 2. 4. Plant according to any one of the preceding claims, comprising a second tank (3), of height Hâ € ™ â € ™ from the ground, comprising said liquid part of said organic wastewater (6) containing said nitrogen and water, in which said part liquid contains an additional solid part and a decanted liquid part. 5. Plant according to any one of the preceding claims, comprising a duct (8) for connecting said first tank (2) with said second tank (3), suitable for the passage of said liquid part of said organic wastewater (6). 6. Plant according to any one of the preceding claims, wherein said at least one tank (4) containing said culture of native microalgae is a third tank of height Hâ € ™ â € ™ â € ™ from the ground comprising said decanted liquid part of said organic wastewater (6) from said second tank (3). 7. Plant according to any one of the preceding claims, in which said native microalgae are green unicellular algae, Chlorophyta, belonging to the genus Chlorella, Scenedesmus or similar genera, capable of reducing the percentage of said nitrogen contained in said decanted liquid part of said wastewater (6), producing a purified liquid. 8. Plant according to any one of the preceding claims, comprising and a conduit (11), in which said conduit (11) is for connection of said third tank (4) with said second tank (3). 9. Plant according to any one of the preceding claims, wherein said height Hâ € ™ is greater than said height Hâ € ™ â € ™, which is greater than said height Hâ € ™. 10. Plant according to any one of the preceding claims, in which said third tank (4) has a depth of between 50 cm and 60 cm. 11. Plant according to any one of the preceding claims, wherein said third tank (4) comprises a system for separating said microalgae from said purified liquid comprising a filtration system (12) and a pumping system (13). 12. Plant according to the preceding claim, wherein said filtration system (12) comprises a removable filter (12â € ™) for collecting said microalgae and obtaining said purified liquid, and in which said pumping system ( 13) includes a pump (13â € ™). 13. Plant according to any one of the preceding claims, wherein said third tank (4) comprises a step (14) for containing possible sediments, positioned before said filter (12â € ™). 14. Plant according to any one of the preceding claims, wherein said third tank (4) comprises a mobile counterwall (15), parallel to said filter (12â € ™) and positioned in such a way as to block the flow of purified liquid during collection of said microalgae. System according to any one of the preceding claims, comprising second pipes (17), in which said second pipes (17) circulate said purified liquid. Plant according to the preceding claim, wherein said second pipes (17) comprise a temporary containment system (18) for said purified liquid. System according to any one of the preceding claims, wherein said pipe system (5) and / or said pipe (8) and / or said pipe (11) and / or said first pipe (7) and / or said second pipes (17) comprise a filter (9) and / or gate means (10). 18. Process for the disposal of the nitrogen load of organic waste (6) from livestock farms, comprising the following steps: provide at least one tank (2, 3, 4), supply said organic waste (6) containing nitrogen, supply native microalgae, introduce said organic wastewater (6) and water into said at least one tank (2, 3, 4), inoculate and cultivate said native microalgae in said at least one tank (4), containing a suspension of said microalgae and said organic wastewater (6), in which said native microalgae determine the reduction of the nitrogen load contained in said organic wastewater (6 ) through its accumulation in their biomass. 19. Process according to claim 18, comprising the following steps: supplying a first tank (2) of height Hâ € ™ from the ground, supplying said water through a first pipe (7), in which said inlet step takes place through the introduction of said organic wastewater (6) into said first tank (2) with called water, mixing said organic wastewater (6) with said water, in which in said first tank (2) the separation of said organic wastewater (6) into a solid part, which is deposited in said first tank (2), and of a part liquid that contains the nitrogenous part of said organic waste (6). 20. Process according to claim 18 or 19, comprising the following steps: provide a second tank (3), height Hâ € ™ â € ™ from the ground, supplying said water through said first pipe (7), transporting said liquid part of said organic wastewater (6) into said second tank (3) through a conduit (8), diluting said liquid part of said organic wastewater (6) with said water, obtaining the decantation of further solid parts of said liquid part and a decanted liquid part. 21. Process according to any one of claims 18 to 20, comprising the following steps: provide said tank (4) for the cultivation of said microalgae, in which said tank (4) for the cultivation of said microalgae is a third tank (4) of height Hâ € ™ â € ™ â € ™ from the ground, supplying said water through said first pipe (7), transporting said decanted liquid part of said organic wastewater (6) and said water of said second tank (3) into said third tank (4) through a conduit (11), diluting said decanted liquid part of said organic wastewater (6) with said water, in which during the cultivation of said autochthonous microalgae in said third tank (4) the nitrogen component of said decanted liquid part of said organic wastewater (6) is absorbed into the biomass of said microalgae with obtaining a purified liquid. Method according to any one of claims 18 to 21, comprising a step of connecting said tanks (2, 3, 4) in series by means of a piping system (5). 23. Process according to any one of claims 18 to 22, comprising the following steps: position said first tank at said height Hâ € ™ greater than said height Hâ € ™ â € ™ of said second tank (3), positioning said second tank (3) at said height Hâ € ™ â € ™ greater than said height Hâ € ™ â € ™ â € ™ of said third tank (4). 24. Process according to any one of claims 18 to 23, comprising the following steps: separate, in said third tank (4), said indigenous microalgae from said liquid part, in which said separating step comprises a step of filtering said suspension contained in said third tank (4) by means of a filtration system (12) comprising a removable filter (12â € ™) for the collection of said microalgae, in which in said step of filtering, the separation of said microalgae from said purified liquid takes place. 25. Process according to any one of claims 18 to 24, comprising the following steps: pump, through a pumping system (13) including a pump (13â € ™), called purified liquid, recover said purified liquid through said pump (13â € ™), introduce said purified liquid into the circulation through second pipes (17), feeding said tanks (2 3, 4) with said purified liquid through said second pipes (17).