WO2016096768A1 - Method for glycolysis of polyethylene terephthalate in two reaction steps - Google Patents

Abstract

The invention relates to a method for glycolysis of PET in two reaction steps, comprising at least the following steps: a) a dissolution step comprising a reaction section fed by at least PET, ethylene glycol, a fraction of the solid flow coming from step b) and a fraction of the effluent from step c), the mass ratio of ethylene glycol to PET feeding into said reaction section being between 1 and 50, said reaction section being operated at a temperature between 100 and 300 °C and at an absolute pressure between 0.1 and 6 MPa; b) a liquid-solid separation step of the effluent from step a) into a liquid flow and a solid flow; c) a glycolysis step fed by at least the liquid flow coming from step b) comprising a reaction section, operated in the presence of a heterogeneous catalyst, at a temperature between 100 and 300 °C, at a pressure between 0.1 and 6 MPa, and at a total PPH between 0.1 and 100 h^-1 and producing a glycolysis effluent; d) a purification step fed by at least a fraction of the glycolysis effluent from step c) and producing at least one effluent containing BHET.

Description

 PROCESS FOR GLYCOLYSIS OF POLY (ETHYLENE TEREPHTHALATE) IN TWO

 REACTIONAL STEPS

TECHNICAL FIELD OF THE INVENTION

 The invention relates to the production by glycolysis of bis (2-hydroxyethyl) terephthalate (BHET) from poly (ethylene terephthalate) (PET) in two reaction steps.

PRIOR ART

 The chemical recycling of PET has been the subject of many studies aimed at decomposing PET recovered as waste into monomers that can be used again as a load of a polymerization process. By monomers is meant any chemical compound containing at least one repeat unit of the type -O-CH 2 -CH 2 -O- and / or -O-CO-C 6 H 5 -CO-O- such as dimethyl terephthalate (DMT) or bis (2-hydroxyethyl) terephthalate (BHET). EP 0723951 discloses a process for preparing BHET from PET in the presence of a transesterification catalyst in a depolymerization step, followed by BHET purification steps. The depolymerization reactor must therefore be dimensioned so as to obtain 100% conversion of PET to oligomers and BHET in order to maximize the yield of BHET and to minimize losses of PET. Indeed, only the oligomers are recycled mixed with unconverted PET and ethylene glycol (EG, or glycol) in the depolymerization reactor. The catalyst being injected in dispersed or dissolved form, it is found in the products at the end of the reaction.

Application EP 1227075 describes a process for the depolymerization of PET in two reaction steps, the first step for depolymerizing PET in the presence of ethylene glycol, and the second step for transesterification of the liquid residue of the first step in the presence of methanol to to produce dimethyl terephthalate (DMT) and ethylene glycol. Apart from the fact that the separation of the solid at the end of the first depolymerization step may cause the loss of non-depolymerized PET, this implementation involves the necessity of separating a large quantity of alcohol (excess methanol and glycol produced) at the outlet of the transesterification step. In addition, this process produces DMT and not BHET. The document FR 1386373 describes a process for the depolymerization of polyethylene terephthalate in two reaction stages, a first stage in which the solid is dissolved, followed by a second stage in which the liquid effluent of the first stage is completely depolymerized. The effluent from the second stage is partly recycled to the first stage. This document is silent as to the use of catalyst in the reaction steps and does not describe the fate of the solid residue in the first step nor an intermediate separation step between the two reaction steps. However, this residue contains not only solid impurities, such as PVC, but also undissolved PET. There is also implementation of a low molecular weight ester which is not the case of the present invention.

The document DE 19646378 discloses a depolymerization of PET in two successive reactors, each reactor being equipped with a recirculation pump for recycling a portion of the effluent to the reactor inlet. The effluent of the first reactor is liquid, which implies sufficiently advanced depolymerization in the first reactor to completely solubilize the PET. In addition, this document does not address the difficulty of handling the solid impurities that may be present in the PET feed (PVC or other, for example). OBJECT AND INTEREST OF THE INVENTION

 The subject of the invention is a method for glycolysis of PET in two reaction stages comprising at least the following steps:

a) a dissolution step comprising a reaction section fed at least by PET, ethylene glycol, a fraction of the solid stream from step b) and a fraction of the glycolysis effluent from step c), the mass ratio ethylene glycol on PET feeding said reaction section being between 1 and 50, said reaction section being operated at a temperature between 100 and 300Ό, at an absolute pressure between 0.1 and 6 MPa;

b) a liquid-solid separation step of the effluent of step a) into a liquid stream and a solid stream;

c) a glycolysis step fed at least by the liquid stream from step b) comprising a reaction section, operated in the presence of a heterogeneous catalyst, at a temperature between 100 and 300Ό, at a pressure between 0 , 1 and 6 MPa, and a total PPH of 0.1 to 100 hr ^-1 and producing a glycolysis effluent;

d) A purification step fed by at least a fraction of the glycolysis effluent from step c) and producing at least one effluent containing BHET.

An advantage of the invention is to reduce the size of said step a) while minimizing losses of PET in undissolved form by setting up an external circulation loop facilitating the recycling of the solid fraction of the effluent from step a) of dissolution.

Another advantage lies in the coupling of the dissolution step a) and the separation step b) with the recycling of the solid fraction which makes it possible to send to the second reaction stage, that is to say the step c) of glycolysis, a free flow of solid particles, which makes it possible to perform this second step in a fixed bed, allowing a better conversion than one or more reactors stirred in series.

In a particular arrangement of the invention implementing a heterogeneous catalyst comprising at least 70% by weight of a solid solution of at least one spinel, the method according to the invention has the advantage of producing a BHET freed from impurities. in particular catalytic impurities resulting from PET polymerization processes, not requiring subsequent purification steps in step c) of glycolysis.

DETAILED DESCRIPTION OF THE INVENTION

 In the remainder of the disclosure, PET is poly (ethylene terephthalate), BHET (bis (2-hydroxyethyl) terephthalate and EG ethylene glycol.

Step a) Dissolution

The method according to the invention comprises a step a) of dissolution comprising a reaction section fed at least by PET, ethylene glycol, a fraction of the solid stream from step b) and a fraction of the effluent of step c), the weight ratio ethylene glycol on PET feeding said reaction section being between 1 and 50, preferably between 3 and 20, and very preferably between 3 and 15., said reaction section being operated at a temperature of between 100 and 300Ό, preferably between 180 and 300Ό, preferably between 180 and 250 ^ and very preferably between 180 and 230 ° C., at a pressure of between 0.1 and 6 MPa, preferably between 0.1 and 2 MPa, and preferably between 0.1 and 0.5 MPa.

PET is a polyester-type polymer obtained by the polycondensation of terephthalic acid with ethylene glycol.

The PET feeding the process according to the invention can come from any source of PET, in particular the recycling of plastic waste. It may also include impurities such as plasticizers, dyes, other polymers (PVC for example), fibers, paper. Prior to its feeding, the PET is reduced in chips, preferably in chips whose equivalent diameter is less than 10 mm, preferably less than 5 mm. The equivalent diameter is defined as the ratio 6V / S, where V is the volume of the particle and S is its external surface. At the end of step a), between 20 and 100%, preferably between 30 and 90% of the solid material introduced is dissolved. This percentage corresponds to (1 - ratio of the solid flow rate leaving step a) to the solid flow rate entering step a) x100.

Said step a) produces a liquid-solid effluent comprising dissolved PET and undissolved PET, ethylene glycol, PET oligomers, bis (2-hydroxyethyl) terephthalate (BHET) and various impurities consisting of the additives employed. during the manufacture of PET articles, or resulting from the pre-sorting of the PET feedstock in the process according to the invention including, for example, polyvinyl chloride (PVC) in solid form.

Said reaction section of said step a) comprises at least one reactor. Advantageously, said reaction section is operated in the presence of a catalyst. When said reaction section is operated in the presence of catalyst, said catalyst is injected with the PET at a flow rate representing between 0.1 and 10% of the mass flow rate of PET, preferably between 0.1 and 5%. Said catalyst may be identical to the catalyst used in step c) glycolysis, or be a depolymerization catalyst known to those skilled in the art. Said reaction section can be operated in continuous or sequential mode (batch, according to the English terminology). In a preferred arrangement, it may include several reactors in series. In another preferred arrangement, it may comprise several reactors operated in "batch" mode in parallel. The reactor or reactors of said reaction section may advantageously comprise internal static mixer type in order to improve the dissolution operation. They may also comprise agitation mobiles, or be agitated by an external circulation loop of liquid.

Step b) liquid-solid separation

According to the invention the effluent of step a) is separated in a step b) into a liquid flow and a solid flow.

Step b) liquid-solid separation is implemented in any liquid-solid separation means known to those skilled in the art. In particular, said step b) can be carried out in a hydrocyclone, a centrifuge, a static decanter, a press filter, a belt filter, a vacuum filtration, assisted settling or not, taken alone or in combination. By assisted decantation is meant decantation carried out in the presence of additives, such as a flocculant. The liquid stream from step b) is free of solid particles. By free, it is meant that this liquid stream comprises less than 0.1% by weight of solid particles. It comprises ethylene glycol, dissolved PET, PET oligomers, bis (2-hydroxyethyl) terephthalate (BHET) and dissolved impurities. The solid stream comprises the solid fraction of the effluent of step a). It also comprises up to 90% by weight of liquid, advantageously up to 80% by weight, very advantageously up to 60% by weight, depending on the means used to perform the liquid-solid separation. A fraction of the solid stream is recycled to the dissolution step a), which makes it possible to produce an external circulation loop around said step a) and to recycle the undissolved PET. The non-recycled fraction of the solid stream is advantageously removed from the process (purge), which makes it possible to control the content of impurities in said solid stream, and thus in the dissolution step a). This external circulation loop, which recycles the solid fraction of the effluent of the dissolution step a), makes it possible to reduce the size of the equipment of said step a) while minimizing the losses of PET in undissolved form. Indeed, it is not necessary for said step a) to have a residence time sufficient to dissolve all the PET in solid form, the undissolved fraction being recycled via the external circulation loop to undergo again step a ) of dissolution. In addition, the coupling of the dissolution step a) and the separation step b) with the recycling of the solid fraction makes it possible to send to the second reaction step, that is to say the step c ) of glycolysis, a free flow of solid particles, which makes it possible to perform this second step in a fixed bed.

Step c) glycolysis

The method according to the invention comprises a step c) of glycolysis fed at least by the liquid stream from step b) comprising a reaction section, operated in the presence of a heterogeneous catalyst, at a temperature of between 100 and 300.degree. preferably between 180 and 300%, preferably between 180 and 250% and very preferably between 180 and 230%, at a pressure of between 0.1 and 6 MPa, preferably between 0.1 and 2 MPa, and preferably between 0.1 and 0.5 MPa, and a total PPH between 0.1 and 100 h ^-1 , preferably between 1 and 20 h ^-1 , preferably between 2 and 10 h ^-1 . PPH (weight per weight per unit) hour) represents the feed mass flow rate of said step c) divided by the mass of catalyst used in said step c).

Advantageously, step c) is not fed with any additional methanol, ethanol or other alcohol or polyalcohol.

Said heterogeneous catalyst may be any heterogeneous catalyst for glycolysis of PET.

In a particular arrangement, said heterogeneous catalyst is a heterogeneous catalyst comprising at least 50% by weight relative to the total mass of the catalyst, preferably at least 70% by weight, advantageously at least 80% by weight, very advantageously at least 90% by weight, and even more advantageously at least 95% mass of a solid solution consisting of at least one spinel of formula Z _x Al ₂ 0 _{(3 + x)} in which x is between 0 (excluded bound) and 1, and Z is chosen from Co, Fe, Mg, Mn, Ti, Zn, and comprising at most 50% by weight of alumina and oxide of the Z element. arrangement, said heterogeneous catalyst advantageously contains at most 10% mass of dopants selected from silicon, phosphorus and boron alone or in mixture. For example, and in a nonlimiting manner, said solid solution may consist of a mixture of spinel ZnAl ₂ 0 ₄ and spinel CoAl ₂ 0 ₄ , or consist of a mixture of spinel ZnAl ₂ 0 ₄ spinel MgAl ₂ O ₄ and spinel FeAl ₂ O ₄ , or consist only of spinel ZnAI ₂ 0 ₄ .

This particular arrangement has the advantage of excellent conversion of PET by glycolysis to BHET. In addition, the heterogeneous catalyst of this particular arrangement has the surprising property of capturing the impurities, in particular the dyes, the additives and the catalytic substances used for the polymerization and present in the PET treated in the process according to the invention, such as antimony, magnesium, manganese, zinc, titanium, phosphorus, which simplifies the subsequent steps of purification of BHET for reuse in a polymerization process.

According to the invention, at least a fraction of the effluent of the glycolysis step c), called the glycolysis effluent, feeds the purification step d). The residual fraction is advantageously recycled to the dissolution step a). When a fraction of the glycolysis effluent is recycled to the dissolution step a), the ratio of the flow rate of the residual fraction recycled to step a) to the flow rate of the fraction supplying step d) is advantageously between 0.1 and 5, preferably between 0.1 and 3.

Said reaction section comprises at least one fixed bed or fluidized bed reactor, advantageously of fixed bed type. Said reactor is advantageously doubled in order to operate in permutation ("swing" according to the English terminology), so as to allow the operation on one of the reactors while the other is in phase of regeneration or replacement of catalyst . Very advantageously, said reaction section comprises only reactors of fixed bed type. The fixed bed implementation, which allows a higher conversion than one or a series of reactors in series, is made possible by the coupling of the dissolution step a) and the separation step b). by eliminating the problems of clogging by the solid particles of PET, said solid particles having been removed from the liquid flow from step b) and feeding step c). Step d) Purification

 The method according to the invention comprises a purification step d) fed by at least a fraction of the glycolysis effluent from step c) of glycolysis and producing at least one effluent containing BHET.

The fraction of the glycolysis effluent resulting from the glycolysis step c) feeds a filter or an adsorbent bed in order to eliminate all the hot insoluble solid particles such as polymerization catalyst fines (based on Sb or Zn). ), impurities. The filter or the adsorbent bed may comprise alumina, activated carbon, activated earth, taken alone or as a mixture.

In a first preferred arrangement, the effluent freed of solid particles feeds a water wash section, with a first washing at δΟΌ to precipitate the oligomers that are separated, then a cold water wash in which it is brought into contact with water whose temperature is at most 20 ° C so as to precipitate the BHET, the residual oligomers and the PET, then a separation section on a rotary filter or band filter, advantageously with a spray a solvent, advantageously water, advantageously under vacuum. The liquid phase containing the water and the glycol is separated and recycled to the dissolution step a).

This liquid phase feeds a drying section of the glycol to separate the water from the glycol, for example under light vacuum or by membrane separation. This implementation avoids vaporizing the glycol solvent which can thus be returned to the dissolution step a). Water in the liquid phase can be used as a hot utility.

The solid phase comprising BHET, precipitated oligomers and PET feeds a hot water wash section so as to dissolve the BHET without dissolving the PET and the oligomers. A liquid / solid separation is carried out after washing with hot water so as to recover on the one hand a liquid phase containing BHET, and on the other hand a solid phase comprising, besides PET, the oligomers and impurities. This solid phase can contain up to 80% weight of liquid according to the separation techniques used. A fraction of this phase is removed from the process so as to avoid the accumulation of impurities according to the usual practices of the skilled person in the case of recycling, while the residual fraction is advantageously recycled to the dissolution step a). The removed fraction can be burned to generate hot utilities.

The liquid phase containing the BHET is sent to a crystallization section in which it is brought into contact with water at a temperature of at most 20 ° so as to crystallize the BHET. The effluent from the crystallization section is separated into a solid phase which can be dried in order to obtain the BHET in powder form, and a liquid phase containing dissolved BHET and water which is advantageously recycled in the section of washing with cold water effluent rid of solid particles.

In a second preferred arrangement, the solids-free effluent feeds a hot water wash section so as to maintain the liquid phase BHET while precipitating the PET and the oligomers. A liquid / solid separation is carried out after washing with hot water so as to recover on the one hand a liquid phase containing BHET, and on the other hand a solid phase comprising, besides PET, the oligomers and impurities. This solid phase can contain up to 80% weight of liquid according to the separation techniques used. A fraction of this phase is removed from the process so as to avoid the accumulation of impurities according to the usual practices of the skilled person in the case of recycling, while the residual fraction is advantageously recycled to step a) of dissolution. The removed fraction can be burned to generate hot utilities.

The liquid phase containing the BHET is sent to a distillation section for separating a water / glycol stream and a BHET / glycol stream. The water / glycol stream is separated in a subsequent distillation section for separating the water from the glycol for recycling, and in particular for recycling the glycol to the dissolution step a).

In this arrangement, BHET is obtained in liquid form in solution in ethylene glycol and can be directly reused in a polymerization step.

The arrangements presented are known to those skilled in the art and do not limit the process according to the invention. The purification step of the effluent containing BHET resulting from the glycolysis step can therefore comprise at least one separation operation intended to recycle a portion of the non-consumed flows such as water and ethylene glycol in excess of in order to obtain a liquid and / or solid fraction containing BHET that can be used in a polymerization unit to produce PET.

Description of figures

Figure 1 shows a block diagram of the method according to the invention.

A filler (1), which is a mixture of ethylene glycol and PET previously reduced in size, a fraction (6) of the effluent of step (C), and a solid stream (3) from the step (B) feed the dissolution step (A). The effluent (2) of step (A) feeds a separation step (B) separating the effluent (2) into a liquid stream (4) and a solid stream (3). The liquid flow (4) feeds a step (C) of glycolysis. The effluent from step (C) is separated into two fractions, one (6) being recycled to the dissolution step (A), and the other (7) feeding a not shown purification step. Figure 2 shows a possible arrangement for purification step d).

The fraction (7) of the effluent of the glycolysis step c) feeds a liquid / solid separation section (D). The effluent freed from the solid particles (8) feeds a cold water washing section (E) in which it is brought into contact with water (9) whose temperature is at most 20 ° C. The liquid phase (1 0) feeds a light vacuum glycol drying section (F). The glycol solvent (12) can be returned to the dissolution step a). The vaporized water (1 1) can be used as a hot utility. The solid phase (13) comprising BHET, precipitated monomers and PET feeds a hot water wash and separation section (G) into which it is contacted with hot water (14). A fraction (16) of the solid phase is removed from the process, while the residual fraction (17) is advantageously recycled to the dissolution step a). The liquid phase (15) is sent to a crystallization, separation and drying section (H) to produce powdered BHET (19) and a hot water effluent comprising dissolved BHET (18). The stream (18) may advantageously be recycled to the dissolution stage a).

Fig. 3 shows another possible arrangement for step d) of separation. The fraction (7) of the effluent of the glycolysis step c) feeds a liquid / solid separation section (D). The solids-free effluent (8) feeds a hot water wash and separation section (G) into which it is contacted with hot water (14). A fraction (16) of the solid phase is removed from the process, while the residual fraction (17) is advantageously recycled to the dissolution step a). The liquid phase (15) is sent to a distillation section (I) for separating a water / glycol stream (21) and a BHET / glycol stream (20). The water / glycol stream (21) is separated in a distillation section (J) for separating the water (22) from the glycol (23) for recycling, and in particular for recycling the glycol to step a ) of dissolution.

EXAMPLES

Example 1 (compliant)

The method is implemented, the general scheme of which is presented in FIG. 1.25 t / h of a PET feed (1) feeds a perfectly stirred reactor (A) of 1 1 m ³ . The reactor is also fed with a solid stream (3) and a fraction of the glycolysis effluent (6).

The PET feed (1) also comprises EG with an EG / PET ratio of 5.1. The mass ratio EG / PET at the inlet of the reactor (A), taking into account the flows (3), (1) and (6), and of 10.

The reactor (A) is operated at a temperature of 250 ° C. The dissolution rate of the PET (1 - mass flow rate of solid PET in the flow (2) / mass flow rate of PET feeding the reactor (A)) is 40%.

The stream (2) is treated by centrifugation (B) so as to separate a solid stream (3) recycled upstream of the reactor (A) and a liquid stream (4) containing less than 0.1% mass of solid particles.

This stream (4) feeds a fixed bed piston reactor (C), which contains 2 m ³ of ZnAl ₂ 0 ₄ spinel catalyst. This reactor is operated at a temperature of 250%. The glycolysis effluent (5) is separated into two fractions (6) and (7), the ratio of flow rates (6) / (7) being equal to 1.

The overall conversion rate of the PET, equal to 1 - (PET dissolved in the stream (7)) / (PET in the stream (1)) is 90%.

Example 2 (consistent): Usefulness of the scheme for the lifetime of the fixed bed

 This example aims to demonstrate the relevance of the current scheme, with an effective liquid / solid separation before the fixed catalyst bed.

The process data is as follows:

 - Flow of PET to be treated: 10 kt / year for an operating time of 8000 h / year;

 EG / PET ratio in the feed of the reaction section of the dissolution step: (mass);

- Density of the input mixture of the glycolysis step: 900 kg / m3;

 Viscosity of the mixture at the inlet of the glycolysis step: 1 cP;

The reaction section of the glycolysis step is operated at a PPH of 2 h ^-1 at a superficial velocity of 3 mm / s This section is operated in fixed bed, with a catalyst in the form of beads of 2 mm in diameter and a catalyst bed vacuum of 40%.

When the process is operated according to the invention, the pressure drop in the reactor remains low: of the order of 40 mbar for the catalytic bed. In the absence of effective liquid / solid separation, it can be estimated that with a feed containing 0.5% by weight of impurities (density of the order of 1200 kg.m-3), the catalyst bed is rapidly clogged. Thus, in two days of operation, the reactor is plugged (5 bar of pressure drop). Even with an alternative operation, such an increase in pressure drop is unacceptable.

Claims

A method of glycolysis of PET in two reaction steps comprising at least the following steps:

a) a dissolution step comprising a reaction section fed at least by PET, ethylene glycol, a fraction of the solid stream from step b) and a fraction of the glycolysis effluent from step c), the mass ratio ethylene glycol on PET feeding said reaction section being between 1 and 50, said reaction section being operated at a temperature between 100 and 300Ό, at an absolute pressure between 0.1 and 6 MPa;

b) a liquid-solid separation step of the effluent of step a) into a liquid stream and a solid stream;

c) a glycolysis step fed at least by the liquid stream from step b) comprising a reaction section, operated in the presence of a heterogeneous catalyst, at a temperature between 100 and 300Ό, at a pressure of between 0, 1 and 6 MPa, and a total PPH of between 0.1 and 100 h ^-1 and producing a glycolysis effluent;

d) A purification step fed by at least a fraction of the glycolysis effluent from step c) and producing at least one effluent containing BHET.

The method of claim 1 wherein, prior to its feeding in step a), the PET is reduced to chips whose equivalent diameter is less than 10 mm.

Process according to one of claims 1 to 2 wherein the mass ratio ethylene glycol on PET feeding said reaction section of said step a) is between 3 and 20.

Process according to one of claims 1 to 3 wherein said reaction section of said step a) is carried out in the presence of a catalyst, said catalyst being injected with the PET at a flow rate representing between 0.1 and 10% of the mass flow rate from PET. Method according to one of claims 1 to 4 wherein said step b) is carried out in a hydrocyclone, a centrifuge, a static decanter, a press filter, a belt filter, vacuum filtration, assisted settling or no, taken alone or in combination.

Method according to one of claims 1 to 5 wherein a fraction of the solid stream from step b) is removed from the process.

Process according to one of Claims 1 to 6, in which a fraction of the glycolysis effluent feeds the purification step d) and the residual fraction is recycled to the dissolution step a), the ratio of the flow rate of the fraction residual recycled from the glycolysis effluent recycled to step a) the flow rate of the fraction of the glycolysis effluent feeding step d) being between 0.1 and 5.

Method according to one of claims 1 to 7 wherein said reaction section of said step c) is implemented in a fixed bed.

Process according to one of claims 1 to 8 wherein said heterogeneous catalyst of said step c) is a heterogeneous catalyst comprising at least 50% mass of a solid solution consisting of at least one spinel of formula Z _x Al ₂ O _{( 3+} x ₎ wherein x is between 0, 0 being excluded, and 1, and Z is selected from Co, Fe, Mg, Mn, Ti, Zn, and comprising at most 50% by weight of alumina and oxide of element Z.

10. The method of claim 9 wherein said heterogeneous catalyst contains at most 10% mass of dopants selected from silicon, phosphorus and boron alone or in mixture.