WO2007000176A1 - Process for gently cooling and crystallizing melamine from a melamine melt or from the gaseous phase - Google Patents

Process for gently cooling and crystallizing melamine from a melamine melt or from the gaseous phase Download PDF

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Publication number
WO2007000176A1
WO2007000176A1 PCT/EP2005/006945 EP2005006945W WO2007000176A1 WO 2007000176 A1 WO2007000176 A1 WO 2007000176A1 EP 2005006945 W EP2005006945 W EP 2005006945W WO 2007000176 A1 WO2007000176 A1 WO 2007000176A1
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Prior art keywords
melamine
liquid
organic phase
process according
cooling
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PCT/EP2005/006945
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French (fr)
Inventor
Willi Ripperger
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Casale Chemicals S.A.
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Priority to PCT/EP2005/006945 priority Critical patent/WO2007000176A1/en
Publication of WO2007000176A1 publication Critical patent/WO2007000176A1/en

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    • CCHEMISTRY; METALLURGY
    • C07ORGANIC CHEMISTRY
    • C07DHETEROCYCLIC COMPOUNDS
    • C07D251/00Heterocyclic compounds containing 1,3,5-triazine rings
    • C07D251/02Heterocyclic compounds containing 1,3,5-triazine rings not condensed with other rings
    • C07D251/12Heterocyclic compounds containing 1,3,5-triazine rings not condensed with other rings having three double bonds between ring members or between ring members and non-ring members
    • C07D251/26Heterocyclic compounds containing 1,3,5-triazine rings not condensed with other rings having three double bonds between ring members or between ring members and non-ring members with only hetero atoms directly attached to ring carbon atoms
    • C07D251/40Nitrogen atoms
    • C07D251/54Three nitrogen atoms
    • C07D251/62Purification of melamine

Definitions

  • the present invention relates to a process for gently cooling and crystallizing melamine from melamine melt or from the gaseous phase.
  • the present invention concerns a process for the continuous cooling and crystallization of solid melamine from the gaseous phase or from melamine melts as they develop in technical processes used to produce melamine .
  • Melamine is technically produced using two processes through the decomposition of urea at about 400 0 C and in the presence of ammonia: either by converting urea in the presence of a catalyst at low pressure (up to 2 MPa) or at high pressure (7-15 MPa) in a purely thermal reaction.
  • the various processes are described in "Ullmann' s Encyclopedia of Industrial Chemistry, Vol. A 16, 5 th Edition, pages 171 - 185 (1990)".
  • the reaction gas contains apart from melamine also ammonia, carbon dioxide and decomposition products of the urea that has not been converted into melamine.
  • the melamine - after prior separation from catalyst dust and melem - is desublimated into fine-grained melamine through the addition of cold reaction gas from the gaseous phase.
  • the disadvantage with this process is that too high a cooling gas quantity is required in order to precipitate the melamine from the gaseous phase and that a very finegrained melamine is obtained. Since in this process after the melamine desublimation no further cleaning step follows, high demands are placed on conducting the reaction in order to prevent the formation of by-products.
  • the melamine is precipitated from the gaseous phase by means of quenching with an aqueous melamine suspension.
  • the disadvantage of a water quenching step is that during quenching a portion of the melamine is hydrolyzed into oxotriazines, thus necessitating recrystallization of the melamine as well as a complex waste water treatment.
  • Another disadvantage consists in the fact that after separation of the melamine a water vapor-containing NH 3 /CO2 gas develops, which cannot be subjected to a urea rinsing process .
  • melamine develops in the reactor as a melamine melt at about 400 0 C and pressure of 7 to 15 MPa.
  • the melt contains still more or less high portions of ammonia and carbon dioxide as well as contaminations of the melamine formed in by-reactions, e.g. ureidomelamine, melam, melem etc.
  • the problem is that at 400 0 C melamine is only stable if high ammonia pressure exists.
  • the melamine melt coining from the reactor however must be decompressed and brought to lower pressures and be cooled to temperatures below 350 0 C, preferably to 200 to 300 0 C.
  • the cooling process of the melamine melt and conversion of the by-products such as melam or ureidomelamine can take place based on two process options:
  • the technical problem underlying the present invention is that of providing a process for the continuous and gentle cooling and crystallization of the melamine from a melamine melt or from the gaseous phase without thermal decomposition or hydrolysis of the melamine during the cooling and crystallization operations, so has to overcome the above disadvantages mentioned with reference to the prior art.
  • a process of the above-identified type which is characterized in that a melamine melt, as it develops in technical, non-catalytic high-pressure processes used for melamine production, or a hot reaction gas from a catalytic process containing the gaseous melamine in addition to ammonia, carbon dioxide and unreacted urea, is decompressed or introduced directly into a liquid, organic phase.
  • Polyvalent alcohols such as ethylene glycol, propylene glycol, glycerin and/or other higher alcohols and/or mixtures of said alcohols as well as ethanol amines having the general formula R n N (C 2 HsOH) 3 _ n , wherein R represents an aliphatic radical or an H atom, are suited as the liquid, organic phase.
  • Ethanol amines such as mono-, di- and triethanol amine, methyl diethanol amine and/or their mixtures are especially suitable.
  • the liquid, organic phase can also consist of mixtures of the two aforementioned groups of compounds.
  • the temperature of the liquid, organic phase is maintained during the cooling and crystallization steps, i.e. during the so-called quenching, preferably between 20 0 C and 350 0 C, the pressure can be atmospheric pressure or be slightly below the pressure used for the respective production process. Furthermore the quantity of the liquid, organic phase required for quenching can be selected such that the entire melamine dissolves in the liquid phase or forms a suspension of the melamine and liquid phase. In the first case, in a subsequent process step the melamine is crystallized out of the liquid phase, e.g. by means of cooling, and separated, in the latter case the melamine can be separated from the liquid phase without cooling directly by means of hydrocyclones and/or centrifuges.
  • the process is furthermore characterized in that, after the melamine separation step, the liquid phase is returned to the quenching step. Due to the good water solubility of the afore-mentioned liquid, organic phases, the melamine can be freed from all residue by washing it with water after separation in the centrifuges .
  • Figure 1 shows a block diagram illustrating the melamine cooling and crystallization process from a melamine melt or from the gaseous phase, according to the present invention.
  • any melamine melt coming from a technical high-pressure process can be used.
  • the reaction conditions referred to in the description of the process do not represent a restriction; they only serve the explanation and understanding of the process. Those skilled in the art will know that the respective operating conditions have to be adjusted to the physical and chemical properties of the employed liquid, organic phase.
  • This step preferably occurs by means of spraying the melamine melt into the prepared liquid, organic phase present in quencher 1 by means of one or more nozzles (of conventional type and thus not shown in figure 1) in order to achieve the quickest possible cooling.
  • the melamine melt is fed through the spraying nozzles in the lower portion 2 of the quencher 1. It is, however, likewise possible to finely disperse the melamine melt on top of the quencher by means of a nozzle (simple or dual nozzle) and add the liquid, organic phase with additional atomizing cone nozzles. It is important that the contact between the melamine melt and liquid, organic phase occurs quickly and intensively.
  • the temperature in the quencher 1 is maintained between 20 0 C and 350 0 C, temperatures between 100 0 C and 250 0 C being particularly advantageous, on one hand in order to ensure sufficient solubility of the melamine in the organic phase, on the other hand in order to prevent decomposition reactions of the liquid phase.
  • Optimal are temperatures that - depending on the pressure conditions in the quencher 1 and stripper 7 - are below the boiling point of the employed liquid, organic phase.
  • the pressure in the quencher depends on the pressure used for the process.
  • High-pressure plants generally operate at a reactor pressure of 7 to 17 MPa, a pressure difference of 0.1 - 0.5 MPa between the melamine reactor and the quencher is enough to achieve sufficiently fine dispersion of the melamine in the quencher.
  • the pressure in the quencher needs to be selected correspondingly lower; in this case additionally the feed of the reaction gases and the liquid phase through nozzles on top of the quencher, as described above, is preferable.
  • the circulating quantity of the liquid, organic phase added in the quencher via the pump 5 in the present example is either selected such that the solution leaving the quencher contains 5-8% by weight melamine at an outlet temperature of 100 0 C or at higher quench temperatures accordingly more (up to 40% by weight) .
  • the temperature and recycle ratio can be adjusted such that a melamine suspension develops, from which the suspended melamine is separated together with the crystallized melamine by means of hydrocyclones and/or centrifuges after cooling.
  • the residence time of the melamine solution or the melamine suspension in the quencher can be adjusted such that deammonation products of the melamine such as melam and melem are converted back into melamine. Since compared to a water quench higher temperatures can be employed in the process according to the invention, these components are converted back to melamine considerably more quickly.
  • residence times of 10-60 minutes, preferably 10 to 30 minutes are sufficient .
  • the melamine-containing solution or suspension is decompressed by means of a relief valve 6 into the NH 3 stripper 7. At a pressure of 0.1-2 MPa in the stripper, the remaining dissolved gases are driven out of the solution or suspension and further treated in the washing column 8.
  • the clear solution or suspension drawn from the bottom of the NH 3 stripper by means of the valve 9 is cooled in the cooling unit 10, wherein melamine is largely crystallized out.
  • the hydrocyclone 11 the majority of the precipitated melamine crystals is separated and washed in the centrifuge 12 with a condensate free of residue.
  • the dryer 13 the melamine is dried.
  • the residue of the liquid, organic phase contained in the washing water of the centrifuge is recovered in a separate column (not shown) and recycled to the quencher 1 via the pump 5.
  • the melamine can initially be separated by centrifuges without a washing step and be freed from the adhering residue of the organic phase in a subsequent separate apparatus, e.g. band filter 14, by means of washing.
  • the resulting melamine has an even grain size distribution without larger fine dust portions.
  • An ammonia-saturated melamine melt with a starting content of 9500 ppm melam and 500 ppm melem with a temperature of 400 0 C and a pressure of 12 MPa was decompressed from one autoclave into a second autoclave, which contained ethylene glycol of 250 0 C at a pressure of 7 MPa. After a residence time of 30 minutes under these conditions, the resulting solution of melamine was cooled in ethylene glycol, and the crystallized melamine as well as the mother liquor were analyzed.
  • the crystallized melamine was free from oxotriazines, the melam content had dropped to below 1000 ppm, the melem content was ⁇ 100 ppm.
  • a melamine-containing gas at 350 0 C having the composition of 2% by volume melamine, 6% by volume carbon dioxide and 92% by volume ammonia was introduced into 150 0 C hot ethylene glycol at atmospheric pressure. From the resulting melamine/ethylene glycol solution having a melamine content of 6.5% by weight the melamine was crystallized out by cooling it to 50 0 C. After washing the melamine had a purity level of 99.8%, in the mother liquor no oxotriazines or decomposition products of the ethylene glycol could be found.

Abstract

Process for cooling and crystallizing solid melamine from the gaseous phase or from melamine melts as they develop in technical processes used to produce melamine, characterized in that the melamine-containing process gases or melamine melts are introduced into a liquid, organic phase at high pressure, said phase comprising polyvalent alcohols such as ethylene glycol, glycerine or their homologous series or of amines such as ethanol amines. Mixtures of both groups of compounds are suitable as well. The advantage of this process is that the hot melamine is cooled very quickly without forming thermal decomposition products and that during quenching no reaction of the melamine with the solvent occurs as in the case with a water quench. Additionally not only the formation of higher deammonation products such as melam and melem is prevented while reducing the pressure from the reactor, but also higher deammonation products of the melamine possibly still contained in the melt, such as melam and melem, are partially converted back into melamine.

Description

Title: PROCESS FOR GENTLY COOLING AND CRYSTALLIZING MELAMINE FROM A MELAMINE MELT OR FROM THE GASEOUS PHASE
* * * * *
DESCRIPTION
Field of application
In its more general aspect, the present invention relates to a process for gently cooling and crystallizing melamine from melamine melt or from the gaseous phase.
In particular, the present invention concerns a process for the continuous cooling and crystallization of solid melamine from the gaseous phase or from melamine melts as they develop in technical processes used to produce melamine .
Prior art
Melamine is technically produced using two processes through the decomposition of urea at about 4000C and in the presence of ammonia: either by converting urea in the presence of a catalyst at low pressure (up to 2 MPa) or at high pressure (7-15 MPa) in a purely thermal reaction. The various processes are described in "Ullmann' s Encyclopedia of Industrial Chemistry, Vol. A 16, 5th Edition, pages 171 - 185 (1990)".
In the catalytic low-pressure processes the melamine leaves the reactor in a gaseous state, the reaction gas contains apart from melamine also ammonia, carbon dioxide and decomposition products of the urea that has not been converted into melamine. In the BASF process the melamine - after prior separation from catalyst dust and melem - is desublimated into fine-grained melamine through the addition of cold reaction gas from the gaseous phase. The disadvantage with this process is that too high a cooling gas quantity is required in order to precipitate the melamine from the gaseous phase and that a very finegrained melamine is obtained. Since in this process after the melamine desublimation no further cleaning step follows, high demands are placed on conducting the reaction in order to prevent the formation of by-products.
In the catalytic processes by Chemie Linz and DSM, the melamine is precipitated from the gaseous phase by means of quenching with an aqueous melamine suspension. The disadvantage of a water quenching step is that during quenching a portion of the melamine is hydrolyzed into oxotriazines, thus necessitating recrystallization of the melamine as well as a complex waste water treatment. Another disadvantage consists in the fact that after separation of the melamine a water vapor-containing NH3/CO2 gas develops, which cannot be subjected to a urea rinsing process .
With the non-catalytic high-pressure processes melamine develops in the reactor as a melamine melt at about 4000C and pressure of 7 to 15 MPa. Depending on the process conditions, the melt contains still more or less high portions of ammonia and carbon dioxide as well as contaminations of the melamine formed in by-reactions, e.g. ureidomelamine, melam, melem etc. The problem is that at 4000C melamine is only stable if high ammonia pressure exists. To cool and obtain the melamine, the melamine melt coining from the reactor however must be decompressed and brought to lower pressures and be cooled to temperatures below 3500C, preferably to 200 to 3000C. Quick cooling to prevent NH3 separating from the melamine can technically only be conducted with significant effort. If this cooling process does not take place quickly enough, the separation of ammonia leads to the development of higher molecular condensation products such as melam and melem, which interfere with the subsequent processing of the melamine. Effective quenching is therefore the prerequisite for obtaining melamine in a sufficient purity (> 99.8%).
Technically, the cooling process of the melamine melt and conversion of the by-products such as melam or ureidomelamine can take place based on two process options:
a) by quenching with an aqueous, alkalized melamine suspension or solution (Nissan process, US 3,637,686, DE 10229100A, WO 0029393), or
b) by quenching with liquid ammonia (US 5514796, US 02007061, WO 00/55142) .
Quenching with an aqueous, alkalized melamine suspension or solution automatically leads to a stronger hydrolysis of the melamine into oxotriazines and hence to a loss in yield of 2-6% (DE 100 30 453 Al) . Due to the formation of hydrolysis products, a portion of the mother liquor must be continuously removed and subjected to further treatment, creating a waste water problem.
The processes for "dry" precipitation with liquid or cold ammonia have not taken hold in practice so far. The reasons for this are manifold: for one, the heat transfer between the cold gas and hot melamine melt is not optimal enough to prevent the formation of deammonation products during the decompression step. Secondly, the amounts of gas created during cooling of the melamine melt and requiring treatment represents an economic disadvantage. Moreover the melamine precipitated by an ammonia quench is very fine-grained; its meal-like consistency makes further handling more difficult. The disadvantages of the "dry" precipitation processes are described in detail for example in EP 1035117.
Summary of the invention
The technical problem underlying the present invention is that of providing a process for the continuous and gentle cooling and crystallization of the melamine from a melamine melt or from the gaseous phase without thermal decomposition or hydrolysis of the melamine during the cooling and crystallization operations, so has to overcome the above disadvantages mentioned with reference to the prior art.
Said problem is solved according to the invention by a process of the above-identified type, which is characterized in that a melamine melt, as it develops in technical, non-catalytic high-pressure processes used for melamine production, or a hot reaction gas from a catalytic process containing the gaseous melamine in addition to ammonia, carbon dioxide and unreacted urea, is decompressed or introduced directly into a liquid, organic phase. Polyvalent alcohols such as ethylene glycol, propylene glycol, glycerin and/or other higher alcohols and/or mixtures of said alcohols as well as ethanol amines having the general formula RnN (C2HsOH) 3_n, wherein R represents an aliphatic radical or an H atom, are suited as the liquid, organic phase. Ethanol amines such as mono-, di- and triethanol amine, methyl diethanol amine and/or their mixtures are especially suitable. The liquid, organic phase can also consist of mixtures of the two aforementioned groups of compounds.
The temperature of the liquid, organic phase is maintained during the cooling and crystallization steps, i.e. during the so-called quenching, preferably between 200C and 3500C, the pressure can be atmospheric pressure or be slightly below the pressure used for the respective production process. Furthermore the quantity of the liquid, organic phase required for quenching can be selected such that the entire melamine dissolves in the liquid phase or forms a suspension of the melamine and liquid phase. In the first case, in a subsequent process step the melamine is crystallized out of the liquid phase, e.g. by means of cooling, and separated, in the latter case the melamine can be separated from the liquid phase without cooling directly by means of hydrocyclones and/or centrifuges. The process is furthermore characterized in that, after the melamine separation step, the liquid phase is returned to the quenching step. Due to the good water solubility of the afore-mentioned liquid, organic phases, the melamine can be freed from all residue by washing it with water after separation in the centrifuges .
It was surprisingly found that by means of quenching gaseous melamine or a melamine melt with the above- mentioned organic compounds and/or their mixtures, such quick cooling of the gaseous melamine or of the melamine melt occurs that no deammonation products are formed. Surprisingly even at high quenching temperatures no hydrolysis products developed from the reaction with the OH-groups of the alcohols as occurs when quenching with water. Surprising was also the high solubility of the melamine in the listed liquid, organic phases, which represents a great procedural advantage over a suspension process.
Further characteristics and the advantages of the invention shall become clearer from the following description of an embodiment thereof, made for indicating and not limiting purposes, with reference to the attached figure.
Brief description of the figure
Figure 1 shows a block diagram illustrating the melamine cooling and crystallization process from a melamine melt or from the gaseous phase, according to the present invention.
Detailed description of a preferred embodiment of the invention
In the following, the process according to the present invention using the example of a melamine melt obtained with a non-catalytic high-pressure process is described in more detail with reference to Fig. 1.
In the process according to the invention any melamine melt coming from a technical high-pressure process can be used. The same applies accordingly for gaseous melamine from a catalytic process. The reaction conditions referred to in the description of the process do not represent a restriction; they only serve the explanation and understanding of the process. Those skilled in the art will know that the respective operating conditions have to be adjusted to the physical and chemical properties of the employed liquid, organic phase.
Feeding the melamine melt coming from the melamine synthesis reactor and which has been largely freed from CO2 and excess NH3, into the quencher 1. This step preferably occurs by means of spraying the melamine melt into the prepared liquid, organic phase present in quencher 1 by means of one or more nozzles (of conventional type and thus not shown in figure 1) in order to achieve the quickest possible cooling. Preferably, the melamine melt is fed through the spraying nozzles in the lower portion 2 of the quencher 1. It is, however, likewise possible to finely disperse the melamine melt on top of the quencher by means of a nozzle (simple or dual nozzle) and add the liquid, organic phase with additional atomizing cone nozzles. It is important that the contact between the melamine melt and liquid, organic phase occurs quickly and intensively.
The temperature in the quencher 1 is maintained between 200C and 3500C, temperatures between 1000C and 2500C being particularly advantageous, on one hand in order to ensure sufficient solubility of the melamine in the organic phase, on the other hand in order to prevent decomposition reactions of the liquid phase. Optimal are temperatures that - depending on the pressure conditions in the quencher 1 and stripper 7 - are below the boiling point of the employed liquid, organic phase.
The pressure in the quencher depends on the pressure used for the process. High-pressure plants generally operate at a reactor pressure of 7 to 17 MPa, a pressure difference of 0.1 - 0.5 MPa between the melamine reactor and the quencher is enough to achieve sufficiently fine dispersion of the melamine in the quencher. With the catalytic low-pressure processes the pressure in the quencher needs to be selected correspondingly lower; in this case additionally the feed of the reaction gases and the liquid phase through nozzles on top of the quencher, as described above, is preferable.
Depending on the selected pressure and temperature conditions in the quencher and the amount of gases still contained in the melamine melt (NH3, CO2, HNCO) , a portion of these components degases, collects in the upper section of the quencher 1 equipped with liquid separators and is decompressed by means of the pressure retention valve 3 in the washing column 4 and further treated, e.g. by washing it with water.
The circulating quantity of the liquid, organic phase added in the quencher via the pump 5 in the present example is either selected such that the solution leaving the quencher contains 5-8% by weight melamine at an outlet temperature of 1000C or at higher quench temperatures accordingly more (up to 40% by weight) .
Alternatively the temperature and recycle ratio can be adjusted such that a melamine suspension develops, from which the suspended melamine is separated together with the crystallized melamine by means of hydrocyclones and/or centrifuges after cooling. The residence time of the melamine solution or the melamine suspension in the quencher can be adjusted such that deammonation products of the melamine such as melam and melem are converted back into melamine. Since compared to a water quench higher temperatures can be employed in the process according to the invention, these components are converted back to melamine considerably more quickly. As a function of the melam and melem contents of the melamine melt, residence times of 10-60 minutes, preferably 10 to 30 minutes, are sufficient .
From the quencher 1 the melamine-containing solution or suspension is decompressed by means of a relief valve 6 into the NH3 stripper 7. At a pressure of 0.1-2 MPa in the stripper, the remaining dissolved gases are driven out of the solution or suspension and further treated in the washing column 8.
The clear solution or suspension drawn from the bottom of the NH3 stripper by means of the valve 9 is cooled in the cooling unit 10, wherein melamine is largely crystallized out. In the hydrocyclone 11 the majority of the precipitated melamine crystals is separated and washed in the centrifuge 12 with a condensate free of residue. In the dryer 13 the melamine is dried. The residue of the liquid, organic phase contained in the washing water of the centrifuge is recovered in a separate column (not shown) and recycled to the quencher 1 via the pump 5.
So as to keep the portion of organic phase low in the washing water, the melamine can initially be separated by centrifuges without a washing step and be freed from the adhering residue of the organic phase in a subsequent separate apparatus, e.g. band filter 14, by means of washing.
The overflow from the hydrocyclone 11, which still contains fine-grained melamine crystals, is returned into the quencher 1 via the pump 5. By using hydrocyclones prior to the actual melamine separation through centrifugation, the resulting melamine has an even grain size distribution without larger fine dust portions.
The following examples demonstrate the chemical principles of the process according to the invention by way of example of ethylene glycol as the liquid, organic phase, without hereby limiting the suitability and use of the others afore-mentioned components.
Example 1
An ammonia-saturated melamine melt with a starting content of 9500 ppm melam and 500 ppm melem with a temperature of 4000C and a pressure of 12 MPa was decompressed from one autoclave into a second autoclave, which contained ethylene glycol of 2500C at a pressure of 7 MPa. After a residence time of 30 minutes under these conditions, the resulting solution of melamine was cooled in ethylene glycol, and the crystallized melamine as well as the mother liquor were analyzed.
In the mother liquor no decomposition products of ethylene glycol could be found.
Likewise the crystallized melamine was free from oxotriazines, the melam content had dropped to below 1000 ppm, the melem content was < 100 ppm.
Example 2
A melamine-containing gas at 3500C having the composition of 2% by volume melamine, 6% by volume carbon dioxide and 92% by volume ammonia was introduced into 1500C hot ethylene glycol at atmospheric pressure. From the resulting melamine/ethylene glycol solution having a melamine content of 6.5% by weight the melamine was crystallized out by cooling it to 500C. After washing the melamine had a purity level of 99.8%, in the mother liquor no oxotriazines or decomposition products of the ethylene glycol could be found.

Claims

1. Process for the continuous cooling and crystallization of solid melamine from the gaseous phase or from melamine melts as they develop in technical processes used to produce melamine, characterized in that a melamine- containing process gas or an ammonia-saturated melamine melt from a high-pressure process is brought in contact with a liquid, organic phase and/or is quenched, wherein it cools off without forming decomposition or hydrolysis products, is converted into a solution or suspension of melamine in said liquid, organic phase, from which through further cooling and crystallization melamine is obtained, and the liquid, organic phase is returned to the process.
2. Process according to claim 1, characterized in that the liquid, organic phase consists of polyvalent alcohols or mixtures thereof, especially of ethylene glycol, propylene glycol, glycerine or mixtures thereof.
3. Process according to claim 1, characterized in that the liquid, organic phase consists of ethanol amines having the general formula RnN(C2H5OH)n-S, wherein R represents a hydrogen atom or an aliphatic radical, especially methyl diethanol amine, mono-, di- or triethanol amine or mixtures of these compounds.
4. Process according to claim 2 or 3, characterized in that the cooling or quenching of melamine-containing process gases or a melamine melt occurs at temperatures between 1000C and 3500C, preferably at temperatures of 1000C to 3000C.
5. Process according to at least one of the preceding claims, characterized in that quenching of a melamine melt occurs with a liquid, organic phase at a pressure of 1 to 13.5 MPa, preferably 3 to 8 MPa.
6. Process according to at least one of the preceding claims, characterized in that the melamine solution or suspension developing in the quencher is decompressed of 0.1-0.5 MPa before separating or further crystallizing the melamine in a separator and that hereby gases still contained therein such as ammonia, carbon dioxide and decomposition products of the unreacted urea are removed from the solution or suspension.
7. Process according to at least one of the preceding claims, characterized in that the ammonia concentration in the liquid phase of the quencher does not increase to above 40% by weight, preferably is kept below 20% by weight.
8. Process according to at least one of the preceding claims, characterized in that the melamine, which has been dissolved in the liquid, organic phase, is crystallized out through cooling crystallization, that the developing melamine crystals together with suspended melamine are separated by means of hydrocyclones and centrifuges, the mother liquor is returned to the process and the separated melamine crystals are washed in a separate unit with water.
9. Process according to at least one of the preceding claims, characterized in that the residence time of the precipitated or dissolved melamine in the quencher depending on the selected temperature and pressure conditions is adjusted such that existing by-products such as melem and melam are converted back to melamine.
PCT/EP2005/006945 2005-06-28 2005-06-28 Process for gently cooling and crystallizing melamine from a melamine melt or from the gaseous phase WO2007000176A1 (en)

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Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO1997034879A1 (en) * 1996-03-21 1997-09-25 Dsm N.V. Method for the preparation of melamine
WO2000040566A1 (en) * 1998-12-31 2000-07-13 Kemira Agro Oy Process for the separation of a component from a gaseous medium and a device for carrying out the process
EP1138676A1 (en) * 2000-03-27 2001-10-04 Casale Chemicals SA Process for producing melamine at high pureness
DE10229100A1 (en) * 2001-11-16 2003-07-31 Agrolinz Melamin Gmbh Linz Production of melem-free melamine from a melamine melt comprises separating off-gases, quenching the melt with an aqueous alkali solution and crystallizing melamine from the resulting alkaline melamine solution
WO2004074265A1 (en) * 2003-02-24 2004-09-02 Dsm Ip Assets B.V. Method for crystallising a melamine melt
US20050131228A1 (en) * 2001-11-16 2005-06-16 Frank Schroder Method for roducing melem-free melamine and queching agents

Patent Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO1997034879A1 (en) * 1996-03-21 1997-09-25 Dsm N.V. Method for the preparation of melamine
WO2000040566A1 (en) * 1998-12-31 2000-07-13 Kemira Agro Oy Process for the separation of a component from a gaseous medium and a device for carrying out the process
EP1138676A1 (en) * 2000-03-27 2001-10-04 Casale Chemicals SA Process for producing melamine at high pureness
DE10229100A1 (en) * 2001-11-16 2003-07-31 Agrolinz Melamin Gmbh Linz Production of melem-free melamine from a melamine melt comprises separating off-gases, quenching the melt with an aqueous alkali solution and crystallizing melamine from the resulting alkaline melamine solution
US20050131228A1 (en) * 2001-11-16 2005-06-16 Frank Schroder Method for roducing melem-free melamine and queching agents
WO2004074265A1 (en) * 2003-02-24 2004-09-02 Dsm Ip Assets B.V. Method for crystallising a melamine melt

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