DE102009007644A1 - Separating material mixtures, particularly solutions, suspensions and emulsion, involves dividing main vaporization and degasification, where main vaporization and degasification are performed in separate mixing kneader - Google Patents

Abstract

Material mixtures separation involves dividing main vaporization and a degasification, where the main vaporization and the degasification are performed in separate mixing kneader (4,12). The material mixture is concentrated before the main vaporization. The concentrated mixture is fed into a pre-concentrating kneading machine and evaporated residual content of volatile components, where the material mixture is concentrated over a discharge (8).

Description

The The invention relates to a method for continuous treatment of polymer solutions in a degasser with a continuous Product and gas room.

STATE OF THE ART

The industrial production of polymers, in particular the manufacture of homo- and co-polymeric elastomers, carried out by polymerization reactions in the so-called solution polymerization process, wherein for better mixing through the use of solvents lowered the viscosity in the stirred tank reactor becomes. From the resulting polymer solution, the solvent must be separated. The removal of this diluent takes place today in the coagulation and stripping process, with large Amounts of energy in the form of stripping steam (wet process) are used. After this step, the polymer must be replaced by a mechanothermal Drying consuming to be separated from the stripping medium. The distance the stripping medium is carried out in two stages via a mechanical Squeezing and atmospheric drying. While These processes are very much energy in the form of water vapor and a lot of washing water is needed, resulting in high wastewater volumes and, due to the large open aggregates, high emissions leads. In parallel, the stripping agent and the solvent must again very expensive to be separated from each other. The existing one Procedure is thus a very energy efficient, one of high emission and investment costs characterized ineffective Technology. The existing technology is aware of the risks are low and the catalyst systems as well as the processing are tailored to this technology.

In the US Pat. No. 3,683,511 describes a method which has been specially developed for the degassing of polybutadiene-containing polymer solutions and solutions where more than 50% of butadiene is polymerized in the polymer. According to the invention, the removal of the solvent is achieved by adding water into the extruder.

Similar solutions are also used in the US 4,909,898 A and the EP 0 262 594 B1 presented. In this publication, the polymer solution is placed in the mixer / kneader zone and the solvent is evaporated at the temperature at which the surface of the heat transfer surface has a higher temperature than the boiling temperature of the lowest-boiling solvent. In this case, a immiscible with the polymer liquid is also added, in this case water.

In the US 6 150 498 A and the EP 0 910 588 B1 A method for degassing EPDM and similar polymers such as polyethylene, polypropylene, ethylene propylene rubber and polystyrene with a thermal dryer is presented. In this case, the thermal dryer consists of a horizontal shell and a rotating shaft within the shell, disc elements which are arranged on the shaft and having stationary counter-pins which are mounted on the inside of the shell. The application of such a technology is limited to polymer solutions that can absorb greater amounts of dissipation energy, otherwise the polymer will overheat or the degassing performance will be insufficient.

Next the energetic aspects and the high emissions are above all the high cost of water separation for the modern water-sensitive anionic polymerization and the processing of extremely temperature-sensitive products Driving force to modernize the process.

task

task It is the object of the present invention to reduce the energy or water vapor and to reduce water consumption around the energy balance of the process improve as well as the efficiency of new polymerization to increase. In parallel, temperature-sensitive Special polymers are made using existing technology not or only with the addition of special antioxidants produced are. The new polymer solution processing method (dry process) has the goal of making the process more energy efficient, greener and to make it more flexible.

Solution of the task

to Solution of the task leads that at least one additive is metered to control the product temperature, so that the temperature always below the polymer damage temperature remains.

It is a method and a device for continuous Treatment of a polymer solution by direct evaporation solvent, monomer, catalyst, initiator or reaction residues from the polymerization of elastomer-containing polymer solutions in mixing kneaders with one or two stirrer shafts. It will a low viscosity polymer solution firstly in an evaporation loop, secondly, in an evaporative mixing mixer and thirdly in one Degassing kneader treated. This method is especially suitable for temperature-sensitive polymers up to 160 ° C may be treated.

Prefers is the low-viscosity polymer solution first to pre-concentrate in a vaporization loop with contact heat and then as a viscous polymer solution in an evaporative mixer to dose that the viscosity in this unit is sufficient, by majority about friction the evaporation energy ready to put over 90% of the polymer solution supplied fluids (eg solvent) to evaporate. The registered thermal and mechanical energy is directly used for the evaporation of the solvent, the pressure level is set so that the maximum polymer temperature due the evaporative cooling of the solvent is not exceeded becomes.

Out This evaporation kneader is a polymer with about 10% residual moisture (For example, solvent) discharged and in a degassing dosed to get there to the final desired Residual moisture (eg residual solvent concentration) evaporated to become.

to Improvement of the degassing process will be small amounts of one Fluids (eg water) are dosed into the degassing and through evaporating on the surface of the polymer for a Surface renewal registered mechanical energy discharged again, so that the polymer temperature is set exactly can be (for example, overheating and thermal damage to avoid. In parallel, the resulting fluid vapor helps (z. As water vapor) in the vapor space as stripping partial pressure lowering and can, in contrast to the contaminated hot air drying (hot air) of the existing process, complete with the solvent be condensed.

The found method is suitable for high temperature sensitive and less sensitive polymers, such as for the direct evaporation of Butadien- and butylstämmigen Elastomers such as BR, SBR, SBS, SIS, SBM HBR, NBR or EPDM-derived Elastomers and for evaporation of copolymer solutions, which are directly co-polymerized or from two polymer solutions be mixed before direct evaporation, such. B. polymer solutions from mixed SBS and SBR solutions, so difficult to mix Elastomers and plastomers.

by virtue of of the closed system of the dry process can over 98% of the solvent in the circulation without expensive water separation returned to the polymerization and the solvent emissions or the polluted wastewater and exhaust gas quantity are enormously reduced.

opposite The cited prior art makes it possible for the invention elastomer-containing polymer solutions by means of extruders or kneaders especially pure polybutadiene solutions, directly and without further Auxiliary components to any residual solvent contents to degas.

The mixing kneaders with which the present invention has been tested are one or two-wave, the same or in opposite directions and are in the patents DE 2 349 106 C . EP 0 517 068 A1 . EP 0 853 491 . DE 101 50 900 C1 ( PTC / EP 02/11578 ; WO 03/035235 A1 ) described in detail. They are produced up to a size of 25,000 liters of free volume and can be used for direct evaporation.

Further Embodiments of the invention are in the subclaims described.

figure description

Further Advantages, features and details of the invention will become apparent the following description of a preferred embodiment as well as from the drawing; this shows in her single figure a block diagram representation of a process structure of a inventive multi-stage system for continuous thermal Separation of mixtures, in particular for the treatment of polymer solutions.

Any polymer solution 1 Becomes first an evaporator 2 fed. In this evaporator 2 it may, for example, be an evaporation tube loop. In the evaporator 2 takes place a pre-concentration. The low-viscosity, mostly directly from the solvent polymerization polymer solution having about 5 to 50% polymer content is concentrated by a thermal treatment to about 20 to 80%. The vaporized volatiles (vapors) are withdrawn from the evaporator and a condenser 3 fed.

The concentrated polymer solution then passes out of the evaporator 2 in an evaporation kneader 4 , This is preferably a horizontal mixing kneader with one or more horizontally arranged kneading shafts, on which there are corresponding kneading elements. This kneading shafts is a drive 5 assigned.

The concentrated polymer solution may be attached to one or more Make successive or simultaneous dosing. there should the metered amount of the polymer solution in each case by a predetermined product temperature can be controlled.

The evaporation kneader 4 again sits a Brüdendom 6 to deduct the volatile constituents, which in turn are in a condenser 7 condensed and discharged.

The now in the evaporation kneader 4 concentrated polymer solution is via a polymer discharge 8th continuously discharged. It should be from the evaporation kneader 4 discharged polymer solution by a pressure build-up, preferably by a gear pump 9 be brought to a pressure of more than 10 bar. If necessary, a liquid or gaseous additive is metered into the pressurized polymer solution and placed in a mixing tube 10 , a static or dynamic mixer mixed as homogeneously as possible in the polymer solution. This mixture is then in the present embodiment by a nozzle plate 11 in a downstream degassing kneader 12 vented for degassing, whereby an increase of the particle surface takes place by a sudden evaporation of the volatile constituents and the additives. This happens analogously to the so-called popcorn effect.

In the degassing kneader produces a plug flow for the polymer solution, which gives a continuous active surface renewal subject and thereby mechanical dissipation energy in the polymer solution is absorbed.

During degassing, the polymer solution temperature in the degassing kneader is maintained below the polymer degradation temperature by the addition of readily volatilizable, non-polymer soluble additives in the degasifier at one or more locations. This is through the arrows 13 shown. The whole thing is controlled by temperature measuring instruments, over which also the corresponding metered amount of additive for evaporative cooling is controlled.

On the degassing kneader 12 another brother dome is sitting 14 on, in turn, the volatile constituents are discharged from the degassing.

To the degassing kneader 12 closes another polymer discharge 15 at, wherein the now finished polymer composition by a further pressure build-up, preferably by a further gear pump 16 , is brought to a pressure of more than 10 bar.

This polymer mass then passes into a cutting device 17 in which it is preferably granulated or brought to some other desired shape. This granulate is then discharged. LIST OF REFERENCE NUMBERS 1 polymer solution 2 Evaporator 3 capacitor 4 Verdampfungskneter 5 drive 6 vapor dome 7 capacitor 8th polymer discharge 9 gear pump 10 mixing tube 11 nozzle plate 12 Entgasungskneter 13 arrow 14 vapor dome 15 discharge 16 gear pump 17 cutter

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - US 3683511 A [0003]
• - US 4909898 A [0004]
• EP 0262594 B1 [0004]
• - US 6150498 A [0005]
• - EP 0910588 B1 [0005]
• - DE 2349106 C [0016]
• - EP 0517068 A1 [0016]
• EP 0853491 [0016]
• - DE 10150900 C1 [0016]
• - EP 02/11578 [0016]
• WO 03/035235 A1 [0016]

Claims (9)

A process for the continuous treatment of polymer solutions in a degasser with a continuous product and gas space, characterized in that at least one additive for controlling the product temperature is metered added, so that the temperature always remains below the polymer damage temperature. Method according to claim 1, characterized in that that the additive is introduced at several points in the degasser is or the product in several places in the product and gas space is applied with additive. Method according to claim 1 or 2, characterized that on the discharge a degree of filling is set so that an efficient surface renewal takes place for degassing in the degasser. Method according to at least one of the claims 1 to 3, characterized in that for determining the degree of filling the torque of the degasser is used. Method according to at least one of the claims 1 to 4, characterized in that by the choice of the speed the surface renewal and thus the residual solvent content be set. Method according to at least one of the claims 1 to 5, characterized in that the additive among such Dosed process conditions are added so that it evaporates a cooling effect is created which adjusts the product temperature and the vaporized additive as a carrier gas and partial pressure reduction uses. Method according to Claim 6, characterized that the towing gas is directed counter to the flow direction of the product becomes. Method according to claim 6 or 7, characterized that the velocity of the vapors (towing gas or vaporized Solvent) over the cross section of the Brüdendoms is so influenced that no product in the Brüdenweg arrives. Method according to at least one of the claims 1 to 8, characterized in that used as an additive water becomes.