EP1019326A1

EP1019326A1 - Method and device for treating a heavily loaded liquid effluent in particular with nitrogen and with phosphorus

Info

Publication number: EP1019326A1
Application number: EP98942812A
Authority: EP
Inventors: Claude Joly
Original assignee: Bch Holding
Current assignee: FIBAC
Priority date: 1997-09-16
Filing date: 1998-09-03
Publication date: 2000-07-19
Also published as: CA2304832A1; FR2768429A1; US6776958B1; CN1189404C; CN1270573A; FR2768429B1; WO1999014162A1

Abstract

The invention concerns a device comprising: a mixing reactor for contacting the liquid effluent with the basic reagent, provided with an intake for said effluent and another intake for the basic reagent; an ammonia-extracting reactor (1), connected to said mixing reactor; and a tank for storing the treated liquid effluent derived from the ammonia-extracting reactor (1). The invention is, for example, applicable to pig slurry.

Description

Title: Process and device for treating a highly effluent liquid effluent, in particular nitrogen and phosphorus.

The present invention relates to a process for treating a liquid effluent highly charged in particular with nitrogen and phosphorus, as well as to a device for implementing this process.

Liquid effluents heavily loaded in particular with nitrogen and phosphorus, whether these are of urban, agricultural or industrial origin, pose a serious problem, particularly in the field of the environment. It should be remembered all the controversy that develops around the level of nitrate present in groundwater.

National and / or international laws are increasingly tending to prohibit any discharge of liquid effluents whose quantity of nitrogenous matter is above a threshold which tends to decrease under the action of different pressure groups. Similarly with regard to phosphorus, the legislation limits the quantities tolerated for spreading.

In addition, the above liquid effluents are often recovered by spreading, the foul smell of which is a source of conflict with the neighborhood.

Among the liquid effluents heavily loaded in particular with nitrogen and / or phosphorus, we must first mention pig manure as well as liquid sludge from treatment plants.

Admittedly, a certain number of methods and / or devices have already been proposed for reducing the gene caused by the spreading of such liquid effluents: but none of them is fully satisfactory, especially in relation to the prescriptions currently envisaged.

Thus one of the aims of the present invention is to provide a process for treating a liquid effluent highly charged in particular with nitrogen and phosphorus, which makes it possible to reduce the nitrogenous charge at least to the legally acceptable threshold. Another object of the present invention is to provide a process of this type which makes it possible to deodorize such liquid effluents.

A further object of the invention is to provide such a method which is simple to implement and low in cost. These aims, as well as others which will appear subsequently, are achieved by a process for treating a liquid effluent highly charged in particular with nitrogen and phosphorus which is, according to the present invention, characterized in that it comprises the steps following: a) adding a basic reagent to this liquid effluent to obtain a pH of between 8.5 and 13; and b) spraying the basified liquid effluent from step a) into an air stream.

Advantageously, the basic reagent added in step a) is quicklime or slaked lime in the form of powder, paste or liquid. This reagent can have a lime [Ca (OH) ₂ ] concentration up to 1000 g / liter of reagent.

Preferably, step b) is repeated a certain number of times for the same basified effluent: the number of passages is between 1 and 50.

Advantageously, at the start of step b) an anti-foam catalyst is added, the amount of which varies from 0 to 1 liter per cubic meter of liquid effluent to be treated.

According to a preferred embodiment, the method according to the present invention may include a third step or step c) of sieving the liquid effluent from step b).

As indicated above, the present invention also relates to a device for implementing the above method, which is of low cost. This device includes:

- a mixing reactor for bringing the liquid effluent into contact with the basic reagent, provided with an inlet for this effluent and another for the basic reagent; an ammonia extraction reactor, connected to the mixing reactor, and

- a storage tank for the treated liquid effluent from the ammonia extraction reactor.

Advantageously, the mixing reactor comprises a device for measuring the pH of the medium connected to a means located on the inlet of the basic reagent to automatically regulate the amount added.

Preferably, the ammonia extraction reactor or degassing reactor, comprises a lower part in particular collecting the basified liquid effluent and an upper part in which is located a spray boom provided with nozzles, connected to the lower part of the reactor and including a pump supply, openings being formed between the two parts to bring in outside air, an air suction fan being connected to this upper part. The sprayer boom nozzles are, for example, of the cyclone type. Advantageously, the upper part of the degassing reactor is connected to a demister.

The description which follows and which has no limiting character should be read with reference to the single appended figure which is a schematic vertical section of part of a device for implementing the method according to the present invention.

According to the invention, a method for treating a liquid effluent highly charged in particular with nitrogen and / or phosphorus comprises a first step or step a) of mixing a basic reagent with the liquid effluent to be treated. The pH of this effluent is thus brought to a value between 8.5 and 13. The basic reagent is essentially constituted by quicklime or slaked lime, in the form of powder, liquid or paste and which may have a concentration up to 1000 g of Ca (OH) ₂ equivalent per liter of reagent.

This addition makes it possible, by raising the pH, to transform the nitrogenous compounds which are present in the liquid effluent in the form of ammonium ion, symbolized by the name N-NH ⁺ ₄ , into gaseous ammonia (NH ₃ ) dissolved in l liquid effluent.

Furthermore, the presence of lime leads to the precipitation, in the form of calcium compounds, of the phosphate compounds present in this effluent in the form of orthophosphates. Likewise, the sulfur compounds which are released in the form of a smelly gas, sulfur dioxide (H ₂ S), are transformed into calcium sulphate, an inert product.

In a second step or step b) of ammonia extraction, the liquid effluent from the previous step is transferred and sprayed into an air stream: the gaseous ammonia (NH ₃ ) is entrained by the air . The transformation of ammonium ions into ammonia is all the more rapid as the pH is between 9.5 and

12.5. The temperature of maximum 70 ° C also increases the degassing.

At the start of this step b), an anti-foam catalyst can be added, the amount of which varies from 0 to 1 l / m ³ of liquid effluent to be treated. The method according to the invention optionally comprises a third step, or step c) of sieving, making it possible to separate the particles in suspension after decantation, before storing the treated liquid effluent.

The present invention also relates to a device for implementing the method described above.

This device comprises, firstly, a mixing reactor, not shown in the figure, in which the first step is carried out. This reactor has an inlet for liquid effluent and an inlet for the basic reagent. It is provided with a stirring means for mixing as intimately as possible the liquid effluent to be treated with the basic reagent.

This mixing reactor can also include means for regulating the flow placed on the inlet of the basic reagent which are connected to a device for measuring the pH of the medium in reaction. This basic reagent, which essentially consists of quicklime or slaked lime, is incorporated in timed sequences and repeated successively as many times as necessary until the desired pH is obtained: this can be done automatically. Each incorporation sequence comprises four phases:. measurement of the initial pH of the loaded liquid effluent,

. injection of the dilution liquid of the basic reagent for a determined time, for example 30 minutes, this liquid possibly being water, this operation being able to be carried out in masked time; . incorporation of the basic reagent diluted in the effluent to be treated for a determined time, for example in a sequence of 20 seconds each,. mixing of the effluent and the basic reagent, in particular by stirring. The duration of a sequence is generally between 30 minutes and 3 hours.

The device according to the present invention comprises, secondly, a degassing reactor designated as a whole by the reference 1 and connected to the mixing reactor. This degassing reactor 1 is composed of two parts:

- A lower part 2 intended to receive the mixture coming from the mixing reactor. This lower part can be, according to a preferred embodiment, composed of several tanks 2a, 2b, 2c, each connected to the same discharge pipe 3 to a spray boom 4; - An upper part 5 comprising the spray boom 4 which is provided with nozzles 6, for example of the cyclone type, which is connected to the lower part 2 of the reactor and is provided at this level with a pump 7: this pump 7 sucks , in the sprayer boom 4, the mixture present in the lower part 2. Openings 8 are formed between the lower part 2 and upper part 5 to allow suction of outside air, a suction fan not shown being connected to this upper part: there is thus the formation of an air stream. As for the suction fan, it causes an air circulation which is charged with ammonia by crossing the sheet of droplets of the mixture coming from the spraying boom 4.

This ramp 4 may also include an inlet for an antifoam product: the purpose of this is to maintain regular fluidity with the basified liquid effluent.

The product from the nozzles is collected at the bottom and recycled to the spraying boom: the number of cycles can reach 50, to obtain a given level of fixed ammonia nitrogen extraction.

The treated liquid effluent from step b) of degassing is sent to storage tanks, optionally after sieving to remove in particular the phosphate compounds. As for the air sucked into the upper part, it is sucked out of the degassing reactor and is sent to a demister 9 in order to rid it of the liquid droplets with which it is responsible.

This ammonia-laden air is returned to the atmosphere if the concentration is below the authorized discharge standards, or treated in a washing tower or by any other means allowing the ammonia to be captured or eliminated.

When the air loaded with ammonia is treated, the air thus purified can be recycled to the openings formed between the lower and upper part of the degassing reactor.

To remove 80% of the ammoniacal nitrogen contained in pig manure, the device according to the present invention makes it possible to treat approximately 1 to 4 m ³ of manure per hour; the air flow must be between 6,000 and 15,000 m ³ / h.

To remove 60% of the ammoniacal nitrogen, this device makes it possible to treat approximately 2 to 8 m ³ / h of pig manure, with the same air flow rate as above. To remove 40% of the ammoniacal nitrogen, this device makes it possible to treat approximately 3 to 10 m ³ / h of pig manure, the air flow being the same.

Claims

1. Method for treating a liquid effluent highly charged in particular with nitrogen and phosphorus, characterized in that it comprises the following stages: a) adding a basic reagent to this liquid effluent to obtain a pH of between 8.5 and 13; and b) spraying the basified liquid effluent from step a) into an air stream.

2. Method according to claim 1, characterized in that the basic reagent added in step a) is quicklime or slaked lime in the form of powder, paste or liquid.

3. Method according to claim 2, characterized in that the lime concentration [Ca (OH) ₂ ] is at most 1,000 g / liter of reagent.

4. Method according to claim 3, characterized in that step b) is repeated a number of times for the same basified effluent.

5. Method according to claim 4, characterized in that the number of passages is between 1 and 50.

6. Method according to claim 1, characterized in that at the start of step b) an anti-foam catalyst is added, the amount of which varies from 0 to 1 l / m ³ of liquid effluent to be treated.

7. Method according to claims 1 to 5, characterized in that it also comprises a step c) of sieving the liquid effluent from step b).

8. Device for implementing the method according to claims 1 to 7, characterized in that it comprises - a mixing reactor for bringing the liquid effluent into contact with the basic reagent, provided with an inlet for this effluent and another for the basic reagent;

an ammonia extraction reactor (1), connected to the mixing reactor, and

- a storage tank for the treated liquid effluent from the ammonia extraction reactor (1).

9. Device according to claim 8, characterized in that the mixing reactor comprises a device for measuring the pH of the medium connected to a means located on the inlet of the basic reagent to automatically regulate the amount added.

10. Device according to claim 9, characterized in that the extraction reactor (1) of ammonia or degassing reactor, comprises a lower part (2) in particular collecting the basified liquid effluent and an upper part (5 ) in which is located a spray boom (4) provided with nozzles (6), connected to the lower part (2) to said reactor (1) and comprising a feed pump (4), openings (8) being formed between the two parts to bring in outside air, an air suction fan being connected to said upper part (5).

11. Device according to claim 10, characterized in that the spraying boom (4) comprises nozzles (6) of the cyclone type.

12. Device according to claim 10, characterized in that the upper part (5) of the degassing reactor (1) is connected to a demister (9).

13. Device according to claim 12, characterized in that it comprises a washing tower connected to the demister or any other means making it possible to capture or eliminate the ammonia.