EP1478802A2 - Method for ozone treatment of used paper - Google Patents

Abstract

The invention concerns a novel method for ozone treatment of used paper which consists in transforming used paper into pulp in an aqueous medium, screening then de-inking said paper by liquid flotation, the method further comprising an ozone treatment step carried out at latest prior to the liquid flotation step.

Description

 Process for treating used paper with ozone.

The invention relates to a method for treating used paper. There is currently a great demand in the world for the recycling of used paper, in particular to limit the exploitation of forests. Worn paper is collected and processed to make new sheets of paper or new paper or cardboard packaging, for example.

The current process for treating used paper for recycling begins with pulping of the recovered paper to be recycled. One or more sieves of this paste are then carried out to remove coarse particles such as paper clips, staples, coarse ink particles, etc.

One or more flotation steps are then carried out to more completely remove the ink used to print the old paper. In fact, used papers are generally printed. The printing ink consists of organic or mineral dyes and organic binders which, when dried, trap the dye particles and keep them on the paper.

In addition, used papers are often coated with glues or adhesives, for example binding glues and adhesives ensuring the closure of the envelopes.

Worn papers are also soiled with food and the like; the paper pulp obtained therefore contains microorganisms such as bacteria, fungi, yeasts, as well as enzymes such as the enzyme catalase.

To allow the recycling of old paper, it is necessary to remove all foreign bodies, such as paper clips, staples, traces of food and others, eliminate the printing ink and glues and adhesives as well as microorganisms and in particular the enzyme catalase, these latter polluting the circuits of the facility in which the papers are processed.

For this purpose, at the present time, various chemical products are added during the pulping of the paper or immediately thereafter. This improves the results of the different steps.

Soda is introduced in particular to swell the paper fibers and allow better separation of the solids. Peroxide hydrogen and / or chlorinated oxidizing products are also added to destroy microorganisms and to improve deinking. Complexing agents, such as sodium silicate, the mode of action of which is not well known, are also added to further facilitate deinking. They form complexes with binders and dyes which are then more easily removed.

The function of hydrogen peroxide and / or chlorinated products is not only to destroy the microorganisms contained in the pulp but also to purify the circuits of the installation. However, since hydrogen peroxide is destroyed by the catalase enzyme present in the paper pulp, this leads to significant overconsumption of this compound during bleaching.

Once these pulping, sieving and flotation steps have been carried out, very fine particles of ink may still remain in the paper pulp.

We then proceed to a series of kneading followed by flotation of the pulp, to mechanically remove the fine ink particles or at least coat them in the mass of the paper pulp so as to obtain a homogeneous "whiteness".

Used paper to be recycled generally consists of a mixture of papers of different types: newspapers, glossy papers, magazines or higher quality papers.

The differences in the quality of the papers mean that, once the preceding processing steps have been carried out, a paper pulp is obtained which is capable of producing a paper whose "whiteness" may not be satisfactory for the end use. In this case, it is possible to implement a step of bleaching the dough obtained. This bleaching step is carried out, as for new paper pulps, by treatment with oxidants such as hydrogen peroxide or chlorinated products or with reducing agents such as sodium dithionite. Used papers can also contain papers that have been treated with optical brighteners (optical brighteners are fluorescent compounds making the paper appear whiter due to an optical phenomenon) these fluorescent compounds have been suspected of being carcinogenic; one may therefore want to carry out a defluorescence of the paper pulp, and here again, hydrogen peroxide is used. The pulp is then transformed into sheets of paper by known methods.

It is known to use ozone for the treatment of used paper. However, the ozone treatments are carried out after the flotation stages, that is to say during the possible stages of bleaching and defluorescence. In addition, ozone is still used there in addition to other chemicals, namely hydrogen peroxide, chlorinated products, soda, and complexing agents already present in the process.

The method of the prior art, in these different variants, has drawbacks.

First of all, this process is very polluting due to the many chemicals used which are found in the effluents discharged by used paper processing plants.

Furthermore, there is a significant overconsumption in this process of hydrogen peroxide due to the presence of the enzyme catalase and sometimes of metals which degrade the hydrogen peroxide.

Finally, the flotation step for deinking purposes may not be sufficient, and as we have seen, it is then necessary to implement several kneading steps followed by flotation steps to perfect it. It is necessary here to emphasize the distinction between: the deinking step, which aims to eliminate the printing ink present on the used papers to be treated and makes it possible to obtain a corresponding whiteness close to that of the original papers and the 'proper bleaching step which is carried out on both pulp from used paper and on new pulp, that is to say obtained directly from cellulose. Bleaching as such consists in eliminating the lignin present in the pulp (new or recycled). The deinking step does not need to be implemented in the case of new paper pulps.

The invention aims to overcome the drawbacks of the method of the prior art by proposing a method for treating used paper which makes it possible to reduce or even eliminate the overconsumption of hydrogen peroxide and to improve deinking. This allows a shorter treatment process comprising fewer or no kneading steps followed by flotation steps intended to perfect the deinking. The invention also proposes, in a variant, a method for treating waste paper which makes it possible to significantly reduce the pollution of the effluents discharged by the treatment plants.

To this end, the invention provides a method for treating used paper of the type comprising the successive stages of: a) pulping used paper in an aqueous medium, b) at least one sieving to remove coarse particles, c) at least one flotation for deinking the dough, characterized in that it further comprises a step d) of ozonation carried out at the latest before step c) of flotation. Advantageously, step d) of ozonation is carried out at a consistency of the pulp of used paper of between 0.5 and 5%.

Preferably, step d) of ozonation is carried out at a consistency of the pulp of used paper of 0.5 to 3%.

According to a preferred embodiment of the process of the invention, steps a), b), c) and d) are carried out in water, without adding chemicals other than ozone to the step d).

According to another embodiment of the method according to the invention, steps a), b), c) and d) are implemented in the presence of soda, hydrogen peroxide and / or chlorinated products, of silicate. sodium and / or complexing agents.

In these two modes of implementation, step d) is preferably implemented after step b) of sieving.

Advantageously, step d) of ozonation is implemented in a two-phase tubular contactor of the gas-liquid type. In this case, according to a first variant, step d) of ozonation is implemented in the tubular contactor operating in wave regime.

According to a second variant, step d) of ozonation is implemented in the tubular contactor operating in plug mode.

Preferably, step d) of ozonation is carried out with an air-ozone or oxygen-ozone gas mixture comprising between 50 and 200 g of ozone per m 3 of gas mixture.

Advantageously, step d) of ozonation is implemented in a two-phase gas-liquid tubular contactor into which the ozone is introduced in the form of a gaseous mixture of air-ozone or oxygen-ozone at a speed greater than 0 , 5 m / s and less than or equal to 10 m / s while the used paper is introduced at a speed greater than 0.5 m / s and less than or equal to 10 m / s.

However, most advantageously, step d) of ozonation is implemented in a two-phase tubular contactor into which the ozone is introduced in the form of a gaseous air-ozone or oxygen-ozone mixture at a speed between 0.5 and 2 m / s while the used paper pulp is introduced at a speed of between 0.5 and 2 m / s.

The invention will be better understood, and other details, advantages and characteristics of it will appear better on reading the description which follows, made with reference to the appended figures in which:

FIG. 1 schematically represents an enlarged view of a particle of printing ink bonded to the surface of used paper,

FIG. 2 schematically represents an enlarged view of the ink particle of FIG. 1, on the same scale, after the deinking step of the method of the prior art,

- Figure 3 schematically shows an enlarged view of the ink particle of Figure 1, on the same scale, after the deinking step of the process of the invention.

FIG. 4 schematically represents a sectional view of a two-phase gas-liquid tubular contactor in segregated regime,

FIG. 5 schematically represents a sectional view of a two-phase liquid-gas tubular contactor in wave mode,

- Figure 6 schematically shows a sectional view of a two-phase gas-liquid tubular contactor in plug mode, - Figure 7 schematically shows a sectional view of a two-phase gas-liquid tubular contactor in dispersed bubble mode,

- Figure 8 shows in the form of bar graphs the number of ink dots remaining, depending on their sizes, in a pulp of used paper after the sieving step (Figure 8A), the ozonization step (FIG. 8B), and the flotation step (FIG. 8C), according to a first mode of implementation of the method of the invention, and

- Figure 9 shows in the form of bar graphs the number and size of the ink dots remaining in a used paper pulp after the sieving step (Figure 9A), flotation (Figure 9B) and ozonation (Figure 9C), implemented according to the method of the prior art. The process for treating used papers to be recycled according to the invention comprises, like the process for treating used papers of the prior art, a step of pulping the mass of papers to be recycled in an aqueous medium. The paper pulp then undergoes several solid-solid separation steps in order to remove undesirable elements such as paper clips, staples, coarse ink particles.

To this end, at least one sieving step is carried out.

Then, one or more flotation steps make it possible to remove very fine ink particles. In the process of the prior art, these steps are carried out in an aqueous medium in the presence of sodium hydroxide to adjust the pH and cause the paper fibers to swell in order to allow easier detachment of the ink particles and other impurities, hydrogen peroxide and / or sodium hypochlorite in order to facilitate the elimination of ink particles, eliminate microorganisms, such as bacteria, fungi and yeasts as well as enzymes such as the enzyme catalase in order to sanitize not only the paste itself but also the circuits of the installation in which the process is implemented. Complexing agents such as sodium silicate are also added to complex the metals, for example from dyes in printing inks so that they can then be removed with hydrogen peroxide or the chlorinated products already mentioned. Any other chemical can be added, as known in the art.

The process for treating used paper of the invention differs from the process of the prior art in that, at the latest before the flotation steps, a step for ozonizing the paper pulp is implemented.

This ozonization step makes it possible to improve the efficiency of the flotation steps for deinking the pulp, moreover it destroys the microorganisms and above all the enzyme catalase.

Thus, the deinking step by flotation being made more efficient, the number and the duration of the subsequent processing steps intended to perfect the deinking, for example by implementing a series of kneading followed by flotation, are reduced compared to l prior art or even deleted.

In addition, since ozone destroys the catalase enzyme which decreases the activity of hydrogen peroxide, there is no longer overconsumption of hydrogen peroxide in cases where the treatment step with hydrogen peroxide is maintained.

The high reactivity of ozone allows it to degrade the unsaturated products with which old paper is impregnated. The following products are thus found to be rich in unsaturated and aromatic groups:

- dyes, in particular printing inks,

- optical brighteners to improve the whiteness of papers,

- glues, commonly known in the art as "stickies", which are present, for example as an adhesive for binding, for example blocks of paper or as an adhesive for envelopes, and

- ink binders used to fix the printing dyes on the paper, when the latter is dried.

All these products are easily degraded by ozone in an aqueous medium or in another solvent.

Although the most important unsaturated product in the products to be treated is often lignin in different forms, it is important to note here that the ozone used in the process of the invention will be used to react with the unsaturated products permeating the papers. worn and little with the lignin present because it is "covered" by these products and others such as mineral fillers.

The destruction by ozone of these products impregnated on the surface of the fibers in fact results in modifications of the wettability properties of the paper fibers. Consequently, significant changes appear during the flotation of inks and charges. In fact, printing inks consist, in the liquid state, of particles of carbon or of another dye dispersed in a liquid binder. When the binder dries, it coats the carbon or other particles and attaches them to the surface of the sheet of paper.

Figure 1 schematically shows an enlarged sectional view of a particle of dried printing ink on the surface of the paper. The carbon particle 2 is enveloped and bound to the surface of the paper 3 by the dried binder 1.

2 shows a schematic sectional view of the ink particle of Figure 1, on the same scale, after the steps of pulping, sieving and flotation according to the method of the prior art. As seen on Figure 2, the carbon particle 2 is still coated and bonded to the surface of the paper 3 by the binder l 'which has decreased in thickness.

Thus, in the prior art, it is necessary to separate, by mechanical action, that is to say by kneading, the binder 1 "from the surface of the paper 3 to release the carbon particle 2 and then proceed to a step flotation to remove binder and carbon particles from the pulp.

When the process of the invention is applied, that is to say when the ozonization step has been carried out before the flotation step, less ink particles remain adhering to the surface of the paper. . However, if we consider the ink particles that still adhere to the surface of the paper, for each of these ink particles, as seen in Figure 3, which is a schematic sectional view of the same particle of ink as that shown in FIG. 1, on the same scale, but after the flotation steps for deinking according to the method of the invention, the binder 1 "is more strongly degraded and coats" the carbon particle 2 "less well.

The mechanical action necessary to detach this particle of ink 2 from the surface of the paper 3 will be less than that necessary to separate the particle of ink 2 represented in FIG. 2. The number of mixing-flotation steps necessary for deinking totally the paper to be recycled according to the process of the invention will be less.

In addition, ozone destroys microorganisms and especially the catalase enzyme.

As the enzyme catalase destroys the activity of the hydrogen peroxide used in the process of the prior art, this allows a more efficient use of the hydrogen peroxide. Its overconsumption is reduced, it can even be zero for certain end uses of paper.

Ozone also makes it possible to clean up the circuits of the installation in which the used paper treatment process is implemented.

It has also surprisingly been found that ozone can be used without adding any of the reagents commonly used in the process of the prior art.

The method of the invention, in a particularly advantageous embodiment therefore consists in pulping the mass of paper to be recycled, in water, in carrying out the steps of solid-solid separation by sieving then in the steps of flotation, always only in water and without addition of no reagent, provided that an ozonation step is used at the latest before the flotation steps.

This process using only ozone without other chemical reagents has great advantages, its simplicity and its economy, moreover, it is a process for treating used paper whose effluents are very little polluting.

In the two embodiments of the method of the invention, the ozonization step must be carried out at the latest before the flotation step for deinking. It can be carried out before, during or just after the pulping step or after the sieving step.

Preferably, it will be carried out after the sieving step in order to allow good contact between the ozone and the paste to be treated, for greater efficiency of the ozone; coarse particles and undesirable elements can be easily removed by sieving, so ozone is used more efficiently and without overconsumption to remove fine ink particles, purify the system circuits and / or react with certain additives.

The effectiveness and extent of degradation of the products to be removed from used paper for the same duration of contact depends on the extent and effectiveness of the contact of ozone with the products to be degraded. . In other words, the efficiency of the ozonation reaction depends on the rate of dissolution of the ozone in the pulp.

As mentioned earlier, ozone has already been used in paper pulp manufacturing processes to bleach virgin pulp. At present, these ozonization processes take place at a solids concentration of between 8 and 40 g of solids per 100 g of dough.

Paper pulps can be likened to a liquid medium, generally an aqueous medium, in which solid particles are in suspension.

During the ozonation reaction, we are then in the case of a two-phase mixture: a gas phase and a liquid phase containing solids. As the chemical ozonation reaction is rapid, it is necessary to have a very rapid rate of dissolution of the gas in the liquid phase containing solids for the ozone to react with the solids.

When working at atmospheric pressure, due to the high concentration of solids in the pulp and the high reactivity of ozone, risks of heterogeneous treatment exist. Another process then proposes, to increase the rate of dissolution of ozone in the liquid-solid phase, to conduct the ozonation reaction under pressure in apparatuses of the centrifugal pump type, which requires compressing the ozone.

This leads to the problems already mentioned, namely the fact that the paper fiber is subjected to significant mechanical stresses which can deteriorate it and the need to compress the ozone which entails the use of compressors which are expensive to purchase and to interview.

It has now been discovered that all of these drawbacks are overcome when the ozonization step is carried out on low or very low consistency paper pulps.

In the foregoing and in the following, the terms "low consistency paper pulp" denote a paper pulp whose paper concentration is between 0.5 and 5% by weight relative to the total weight of the pulp.

In the foregoing and in the following, the terms "very low consistency paper pulp" denote a paper pulp whose paper concentration is approximately 1% by weight relative to the total weight of the pulp. For such pulps, it is possible to use two-phase gas-liquid tubular contactors making it possible to obtain very high values of speed of dissolution of the gas in the paper pulp. The invention proposes to implement the ozonization step in a two-phase tubular contactor of the gas-liquid type and to introduce paper pulp at low or very low consistency.

The tubular contactor for implementing the method of the invention can be a horizontal or vertical tubular contactor operating in co-current of liquid phase containing solids.

The gas can be introduced by a simple pipe or by a more sophisticated system, for example a static mixer.

The rate of dissolution of ozone in the pulp is a function of the gas-liquid mass transfer coefficients and more particularly of the interfacial area between the two phases.

The goal here is to obtain a good gas-paste emulsion.

Depending on the respective introduction rates of the gas and the paste, the reactor will operate in segregated mode, in wave mode, in plug mode or in dispersed bubble mode. FIG. 4 represents a diagrammatic section of a horizontal tubular contactor T operating in segregated regime in which the gas phase is denoted 4 and the dough is denoted 6. In FIG. 4, the interfacial area is represented by the contact surface 5 between the gas phase 4 and the paste 6. This contact surface 5, when the tubular contactor T is in segregated mode, as shown in FIG. 4, can be assimilated to a flat surface.

In this case, the interfacial area corresponding to the contact surface 5 is less important than in the cases represented in FIGS. 5 to 7 which will be discussed below. For this reason, the ozone dissolution rate is less favorable.

Such a segregated regime is obtained when the respective rates of introduction of the gas phase and of the paste are less than 1 m / s, more particularly greater than 0.5 m / s and less than 1 m / s. The contact surface between the gas phase and the liquid phase containing solids is improved when the contactor T operates in wave regimes, as shown in FIG. 5.

As seen in Figure 5, the contact surface denoted 5 'between the gas phase 4 and the paste, forms waves. It is increased in this area. The dissolution of the gas therefore takes place more quickly in this case than in the case shown in FIG. 4, that is to say in a segregated regime.

The speed of dissolution of ozone, and therefore of the reaction of ozone with the paste, is further improved when, as shown in FIG. 6, the tubular contactor T operates in plug mode. As can be seen in FIG. 6, when the tubular contactor T operates in plug mode, the paste 6 is animated by a movement which makes it touch the two internal horizontal walls of the contactor.

The gas phase 4 therefore has a contact surface denoted 5 "high with the paste 6 when the contactor operates in such a plug regime. The contactor T operates in wave mode or in plug mode when the respective speeds of introduction of the gas phase and the paste are between 1 and 2 m / s.

The best results are obtained when the contactor is in a dispersed bubble flow regime, as shown in FIG. 7. In this case, the paste 6 forms bubbles which are dispersed in the gas phase 1 and the contact surface 5 ′ "between the gas phase 4 and the paste 6 is very high.

Such a dispersed bubble regime is obtained for respective introduction speeds of the gas and the paste greater than 2 m / s and which can range up to 10 m / s.

However, to obtain such operation in a dispersed bubble regime, it is necessary to use very high gas pressures and this is not preferable in the process of the invention, since it is necessary to use a gas compressor with the associated purchase and maintenance costs. In addition, the drawback linked to the mechanical stresses exerted on the pulp, and in particular on the paper fiber, is found here.

Therefore, for the reasons explained above, although the ozonization step can be implemented in the contactor T operating in segregated mode, in wave mode, in plug mode or in dispersed bubble mode, it will be preferably implemented in wave mode or in plug mode, that is to say with gas introduction speeds of between 0.5 and 2 m / s and pulp introduction speeds of between between 0.5 and 2 m / s.

The introduction speeds mentioned above and in what follows are the speeds obtained when the contactor T is empty. In other words, the gas introduction rate will be calculated as a function of the internal section of the contactor used so as to obtain a gas introduction speed of between 0.5 and

2 m / s when the contactor does not contain paste.

In the same way, the speed of introduction of the dough will be calculated according to its rate of introduction into the empty contactor and according to the internal section of the contactor.

To obtain a high reaction rate, it is advantageous to use a gas mixture containing ozone in high concentration in a carrier gas such as for example air. Indeed, as we have already said, ozone is very reactive and the quantities of ozone to consume are generally low. For example, in the case of paper pulps, they are less than 20 kg / t of pulp.

Thus, it has been determined that an ozone-air gas mixture containing between 50 and 200 g of ozone per m 3 of gas mixture is entirely suitable. However, an oxygen-ozone or nitrogen-ozone gas mixture or any other mixture of ozone in a carrier gas compatible with ozone may also be used.

In order to better understand the invention, we will now describe several examples of implementation. These examples are given purely by way of non-limiting illustration.

EXAMPLE 1 Treatment of used paper according to the process of the invention in the presence of the usual reagents

Pulping step

1.5 kg of waste paper consisting of a mixture of old newspapers and magazines is mixed with 13.5 I of water and the usual amounts of the prior art of hydrogen peroxide, soda and sodium silicate .

The mixture is stirred in a pulper sold by the company Lamort for 20 min. The pH is then close to 10.5.

Sieving step

The paper pulp obtained is then sieved through sieves, according to the usual methods for the profession.

Ozonation stage

The ozonation is carried out at a consistency of 3% in a glass reactor, the ozone is introduced in the form of a gaseous oxygen-ozone mixture containing 150 g of ozone per m ³ of gaseous mixture, until 10 kg of ozone per tonne of dry paper is consumed.

Flotation step The paste obtained is diluted to a consistency of 1% and then transferred to a Lamort-type flotation cell. Flotation is carried out for 6 min and then extended by 4 min. A foaming agent is added.

During all these stages the temperature remained close to 40 ° C.

After each step, a pulp sample was taken and made into a sheet of paper. The whiteness of this sheet of paper was measured with UV according to ISO standard (2420).

The fluorescence of the pastes is measured according to an identical method, by inserting in the optical path a filter eliminating UV (application of the procedure described in "TAPPI T 452 appendix C"). The results are given in Table 1 below:

TABLE 1

The results of Table 1 show that when the method of the invention according to its first variant, that is to say comprising an ozonization step, is implemented with the chemical reagents usual in the profession the sheet of paper obtained ultimately has improved whiteness and decreased fluorescence.

The number and size of the black dots per m ² of surface was also measured on each sheet.

The results are shown in Figure 8.

As can be seen from FIG. 8, with the method of the invention according to its first variant, the number of black dots remaining after the flotation is very small. This means that the ozonization step, when introduced before flotation improves the efficiency of the flotation step itself, that is to say deinking.

The number of black dots per m ^{2 as} well as the size in microns of these black dots were by image analysis.

EXAMPLE 2 Implementation of the process of the invention without adding any other chemical reagent than ozone

The procedure was as in Example 1 but without adding hydrogen peroxide, soda and sodium silicate. The pH is around 7.5.

The same measurements of whiteness with UV and without UV as well as of fluorescence were carried out on the sheets of paper obtained after the sieving, ozonation and flotation operations, respectively. The results are given in Table 2 below:

TABLE 2

Again, there is a marked decrease in fluorescence and a marked increase in whiteness.

COMPARATIVE EXAMPLE 3

By way of comparison, the method of the prior art has been implemented, in which the ozonation is carried out after the flotation step. To do this, we have proceed in the same way as in Example 1 but proceeding to the ozonation step only after the flotation step.

The whiteness was measured with and without UV, the fluorescence and number of black dots per m ² of sheets of paper obtained by this process as well as their size in microns, on each sheet of paper obtained after the sieving step, after 1 'flotation step and after the ozonation step.

The results of the whiteness measurements with and without UV and of fluorescence are given in Table 3 below:

TABLE 3

The results of Table 3 show, when compared with the results of the whiteness measurements with and without UV and of fluorescence carried out on the sheets of paper obtained in Example 1, that with the process of the invention, one obtains sheets of paper having in the end a higher whiteness and a lower fluorescence in the case of the sheets treated according to the process of the invention than in the case of the process of the prior art. The results of the measurements of the number of black dots per m ² present on the sheets of paper obtained according to the method of the prior art as described in the present example as well as their sizes are given in FIG. 9.

By comparing the results of these measurements with those obtained with the method of the invention as described in Example 1, it can be seen that the method of the invention allows better deinking than the method of the prior art. COMPARATIVE EXAMPLE 4

The procedure was as in Example 2, without adding any chemical reagent other than ozone but by implementing the ozonization step after the flotation step.

The whiteness with and without UV as well as the fluorescence of the sheets of paper obtained with the pulps obtained after sieving, after flotation and after ozonation are given in Table 4 below:

TABLE 4

By comparing the results of the measurements given in Table 4 above with those of the measurements given in Table 2 of Example 2, it can be seen that by implementing the process of the invention without adding any reagent other than the ozone, with the process of the invention, better whiteness with UV and better defluorescence of the paper pulp obtained from UV papers are obtained.

EXAMPLE 5

The test of Example 2 was repeated using a horizontal tubular stainless steel contactor having an internal diameter of 4.5 cm and a length of 100 m supplied with a pulp of used paper having a consistency of 2.5%. .

The rate of introduction of the paper pulp is chosen so as to obtain pulp speeds (in empty contactor) of between 1 and 2 m / s. The same speeds are used for the gas mixture consisting of a mixture of oxygen and ozone having an ozone content of 100 g / m3 of mixture.

Under these conditions, the pressure drops are 2 to 3 bars. The ozone transfer capacity is then 1.5 to 3 kg / t of pasta for a residence time of one and a half minutes.

The same results as in Example 2 were obtained.

All these measurements show that the process of the invention makes it possible to obtain recycled paper sheets having better whiteness, better defluorescence and better deinking, with fewer subsequent processing steps, without overconsumption of hydrogen peroxide, and even without adding any reagent other than ozone, than those obtained according to the prior art.

Of course, the invention is in no way limited to the embodiments described and illustrated which have been given only by way of examples.

On the contrary, the invention includes all the technical equivalents of the means described and their combinations if these are carried out according to the spirit.

Claims

1. A method for treating used paper of the type comprising the successive steps of: a) pulping used paper in an aqueous medium, b) at least one screening of the pulp to remove coarse particles, c) at least one flotation for deinking the dough, characterized in that it further comprises a step d) of ozonation carried out at the latest before step c) of flotation.

2. Method according to claim 1, characterized in that step d) of ozonation is implemented at a consistency of the pulp of used paper of between 0.5 and 5%.

3. Method according to claim 1 or 2, characterized in that step d) of ozonation is carried out at a consistency of the pulp of used paper of between 0.5 and 3%.

4. Method according to any one of the preceding claims, characterized in that steps a), b), c) and d) are carried out in water, without adding chemicals other than ozone to step d).

5. Method according to any one of claims 1 to 3, characterized in that steps a), b), c) and d) are carried out in the presence of soda

NaOH, hydrogen peroxide H ₂ 0 ₂ , sodium silicate Na ₂ Si0 ₃ .

6. Method according to any one of the preceding claims, characterized in that step d) is implemented after step b) of sieving.

7. Method according to any one of the preceding claims, characterized in that step d) of ozonation is implemented in a contactor.

(T) two-phase tubular gas-liquid type.

8. Method according to claim 7, characterized in that step d) of ozonation is implemented in the contactor (T) in wave mode.

9. Method according to claim 7, characterized in that step d) of ozonation is implemented in the contactor (T) in plug mode.

10. Method according to any one of the preceding claims, characterized in that step d) of ozonation is implemented with a mixture (4) gaseous air-ozone or oxygen-ozone comprising between 50 and 200 g of ozone per m ³ of gas mixture.

11. Method according to any one of the preceding claims, characterized in that step d) of ozonation is implemented in a gas-liquid biphasic tubular contactor (T) in which the ozone is introduced in the form of '' a gas-air-ozone or oxygen-ozone gas mixture (4) at a speed greater than 0.5 m / s and less than or equal to 10 m / s and the used paper pulp (6) is introduced at a speed greater than 0.5 m / s and less than or equal to 10 m / s.

12. Method according to any one of the preceding claims, characterized in that step d) of ozonation is implemented in a two-phase tubular contactor (T) into which the ozone is introduced in the form of a mixture (4) gaseous air-ozone or oxygen-ozone at a speed between 0.5 and 2 m / s while the pulp of used paper is introduced at a speed between 0.5 and 2 m / s.