EP2007510A1 - Continuous process for performing a chemical reaction in which a gaseous phase is added to a charge stream comprising one or more solid phases which have been dissolved or dispersed in water - Google Patents

Abstract

Proposed is a continuous process for performing a chemical reaction in which a gaseous phase is added to a charge stream comprising one or more solid phases which have been dissolved or dispersed in water, which is characterized in that - a rotor/stator apparatus is used, which has a rotor (1) and a stator (2) which, with their surfaces facing one another, form a shear zone (3) which is adjoined by a mixing zone (4) having an orifice (7) leading to the exterior, a feed being connected upstream of the shear zone (3) and an outlet being connected downstream of the mixing zone (4), - the charge stream comprising one or more solid phases dissolved or dispersed in water is added to the rotor/stator apparatus via the feed (5) into the shear zone (3), - in the shear zone (3), an elevated pressure of at least 1 bar is built up, - the gaseous phase is introduced into the mixing zone (4) via its external orifice and mixed into the charge stream under the elevated pressure of at least 1 bar built up in the shear zone (3) or with a further pressure increase to obtain a reaction mixture, said mixture being fed via the outlet (6) to a holding zone in which the reaction takes place and downstream of which is connected a pressure regulation valve, by means of which the pressure in the mixing zone (4) is regulated.

Description

A continuous process for carrying out a chemical reaction in which a gaseous phase is added to a feed stream containing one or more solid phases dissolved or dispersed in water

description

The invention relates to a continuous process for carrying out a chemical reaction in which a gaseous phase is added to a feed stream containing one or more solid phases dissolved or dispersed in water.

Numerous chemical reactions rely on the reaction of one or more solid, water-dispersed or dissolved phases with a gaseous phase. In this case, the gaseous phase must be optimally mixed into the one or more solid phases containing aqueous phase.

Numerous mixing apparatuses are known for the continuous dispersion of solids in liquids, for example the mixing apparatuses of IKA, Lipp Mischtechnik or Buckau-Wolf. Many versions of the mixing equipment of these companies are not able to build up pressures of more than 1 bar. This is usually achieved when required by downstream pumps, which means a considerable additional technical effort.

For the addition of gases in liquids stirred tanks are often used, with special gas inlet systems for bubbling the gases or with piping systems in which static mixers are connected downstream of the place of gas addition. In order to improve the solubility of the gases in the aqueous phase, it is necessary to work under pressure, which necessitates technically complex solutions, in particular if solids have to be added at the same time.

It was accordingly an object of the invention to provide a simple technical process for the preparation of a reaction mixture and a subsequent reaction in which to a feed stream containing one or more solid, dissolved or dispersed in water phases, added a gaseous phase and a excellent phase mixing is ensured.

The object is achieved by a continuous process for carrying out a chemical reaction in which a gaseous phase is added to a feed stream containing one or more solid phases dissolved or dispersed in water, which is characterized in that a rotor / stator device is used, with a rotor and a stator, which form with their mutually facing surfaces a shear zone, which adjoins a mixing zone with an opening of the mixing zone to the outside, wherein the shear zone upstream of a feed and the mixing zone Downstream of the outlet, the feed stream containing one or more solid phases dissolved or dispersed in water is added to the rotor / stator device via the feed into the shear zone, in which the shear zone an overpressure of at least 1 bar is built up, in the mixing zone through the opening to the outside, the gaseous phase is mixed into the feed stream under the built-up in the shear zone pressure of at least 1 bar or with further pressure increase, to obtain a reaction mixture which is fed via the outlet of a residence time zone in which the reaction takes place and a pressure regulating valve is connected downstream, via which d he pressure in the mixing zone is regulated.

For the process according to the invention, it is generally possible to use devices in which, in a shear zone, the feed stream containing one or more solid phases dissolved or dispersed in water is brought to an overpressure of at least 1 bar and submerged in a subsequent mixing zone the previously established in the shear zone pressure or with further pressure increase, a gaseous phase can be added, wherein the solubility of the gas in the liquid phase is significantly increased, excellent mixing and short reaction times can be achieved.

Advantageously, a rotor / stator device can be used, as described for dispersing, distributing and homogenizing in DE 197 20 959 and known under the name Supraton®: rotor and stator form a conical shear gap between the mutually associated surfaces, whose width can be adjusted by the axial displacement of the rotor and / or stator and to which an annular space adjoins.

The device has an axial feed port for the supply of the mixture to be treated to the shear gap and a radial outlet port for the discharge of the same from the annulus.

Due to the conical geometry of the rotor and stator, overpressures of more than 1 bar can be built up by this pumping action. This rotor / stator device is advantageously used for the preparation of mixtures starting from an aqueous, one or more solid phases, containing phase and a gaseous phase by using as feed for the aqueous phase containing one or more solid phases of the axial feed nozzle and as a supply for the gaseous phase, the opening of the annular space around the rotor and the stator, which is provided as an emptying nozzle, is used to the outside. In the annular space is a homogeneous mixing of the gaseous phase in the one or more solid phases containing aqueous phase under an overpressure of at least 1 bar.

The feed stream, containing one or more solid phases dissolved or dispersed in water, can advantageously be supplied via a powder attachment on the inlet side of the rotor / stator apparatus, as is available, for example, under the name Vortex® from Buckau-Wolf, be supplied to the axial feed nozzle.

The optimum mixing of the gaseous phase into the feed stream containing one or more solid phases dissolved or dispersed in water takes place in that the material leaving the shear gap is thrown by the centrifugal forces into the annular space into which the gas to be admixed is metered. About a rotor / stator device downstream pressure control valve, the desired Ü- pressure in the annulus is adjusted, whereby the solubility of the gas in the liquid phase is significantly increased and thus short reaction times can be achieved.

The reaction mixture from the feed stream and the gaseous phase leaves the rotor / stator device via the radial outlet port and enters a residence time zone in which the chemical reaction takes place and the pressure regulating valve is connected downstream.

In a further preferred embodiment, the rotor / stator device in which in the feed stream, containing one or more solid, dissolved or dispersed in water phases, an overpressure of at least 1 bar is built, a tool containing, preferably on the rotor and / or the stator each having a sprocket, wherein between the facing sprockets through the gaps between the teeth of the sprockets, the shear zone is formed. In the annular space around the rotor and stator, homogeneous mixing of the gaseous phase into the aqueous phase containing one or more solid phases takes place under an overpressure of at least 1 bar.

In a further embodiment, a propeller system with a stator and a rotor with two or more fans can be used as the rotor / stator device. in which the shear zone is the area between the pairs of blades of the rotor and the stator, in which a pressure of at least 1 bar is built up and to which another area connects between at least one pair of blades of the rotor and the stator as a mixing zone and wherein the one another facing surfaces of the stator and wing pairs of the rotor are preferably structured. Such apparatuses are known, for example, the name Reflector® from Lipp Mischtechnik GmbH.

The reaction mixture from the feed stream and the gaseous phase leaves the rotor / stator device via the radial outlet port and enters a residence time zone in which the chemical reaction takes place and the pressure regulating valve is connected downstream.

This residence time zone may be formed as a tubular reactor.

It is also possible to form the residence time zone by a combination of tube reactor and stirred tank.

The pressure regulating valve can be followed by an apparatus for separating solids from the reaction mixture.

The feed stream containing one or more solid phases dissolved or dispersed in water may additionally contain one or more organic phases.

Preferably, the feed stream may contain a magnesium salt dissolved or dispersed in water and the gaseous phase added to the feed stream may be gaseous carbon dioxide.

The inventive method ensures a significantly improved solubility of a gaseous phase in an aqueous, one or more solid phases containing feed stream and thus an improved reaction rate of the reaction mixture prepared thereafter.

The process of the invention enables the preparation of mixtures of gas, water and one or more solids using a single, relatively small apparatus, the rotor / stator device. This eliminates the need for a nozzle or frit system that is easily clogged by solids. It is an optimal, homogeneous and rapid mixing of the reactants achieved, thereby allowing a quick reaction and thus low residence times and smaller, cheaper apparatus.

By the method according to the invention high conversions in the implementation of chemical reactions, in which a feed stream containing one or more solid, dissolved or dispersed in water phases, a gaseous phase is added, of over 90% or even more than 95th % can be achieved.

The invention will be explained in more detail below with reference to a drawing and exemplary embodiments.

The single figure shows the schematic representation of a preferred embodiment of a rotor / stator device for use in the method according to the invention.

The rotor / stator device comprises a rotor 1 and a stator 2 with mutually facing, conical surfaces forming a shear gap 3. The shear gap 3 is preceded by an axial feed port 5, a radial outlet port 6 downstream and it is enclosed by an annular space 4. The annular space 4 has an opening 7 to the outside.

Embodiment 1

An aqueous feed stream containing a solid phase was initially produced in a Supraton VortexOS 200 apparatus from Buckau-Wolf, in which 2.2 m ³ / h of demineralized water were added via the tangential connection of the apparatus and from above via a Dosing belt weigher 17.6 kg / h of Mg (OH) ₂ (Magnefin®H-10 from Martinswerk GmbH) was added. This aqueous feed stream was sucked in via the axial feed port of a rotor / stator device, as described in DE 197 20 959 and known under the trade name Supraton® and which was equipped with chamber tools consisting of sprockets on the rotor and the stator.

29 kg / h of gaseous carbon dioxide were metered into the annular space via the upper opening of the annular space, which is provided as an emptying nozzle, whereby optimum mixing with the aqueous feed stream containing magnesium hydroxide took place in the annular space. In the annulus, an overpressure of 1.5 bar was adjusted by means of a pressure control valve located at the end of a residence time line which connected to the radial outlet port of the rotor / stator device.

The reaction mixture was passed through a arranged at the bottom of the annulus radial outlet in a residence time, formed from a hydraulically guided 0.3 m ³ stirred tank, which was followed by a 4-meter-long DN 200 pipe and to which the pressure control valve connected.

After the pressure control valve, a sampling valve was attached.

About the sampling valve, a clear solution of Mg (HCO3) _{2 was} taken, which still contained 0.10 g / l of undissolved magnesium salts.

The conversion of the magnesium hydroxide used was thus 98.8%.

Embodiment 2

The procedure was as described for Embodiment 1, but the residence time line was modified as follows: no stirred reactor was used and the 4 meter long DN 200 pipe was replaced by a 10 meter long DN 150 pipe.

At the sampling point, a clear solution was obtained, which still contained 0.9 g / l of undissolved magnesium salts, corresponding to a conversion of 98.9% of magnesium hydroxide used.

Embodiment 3

The experiment was similar to the first embodiment, with the following modification of the residence time zone: no stirred reactor was used, but a 5 meter long DN 200 pipe in which a static mixer was installed in the middle to prevent sedimentation of solids.

At the sampling point a clear solution of Mg (HCO ₃ ) _{2 was} obtained, which still contained 0.12 g / l of undissolved magnesium salts, corresponding to a 98.5% conversion of magnesium hydroxide. Comparative Example 1

It was proceeded according to the embodiment 1, but the addition of the carbon dioxide was not in the rotor / stator device, but in the 0.3 m ³ - stirred tank by bubbling through a perforated pipe, which was attached to the bottom of the stirred tank.

At the sampling point, a slightly turbid solution was obtained which still contained 1.8 g / l of undissolved magnesium salts, corresponding to a conversion of 77.5%, based on the magnesium hydroxide used.

Comparative Example 2

The procedure was as for Comparative Example 1, but the addition of the carbon dioxide was carried out in the 0.3 m ³ stirred tank via a bottom mounted frit.

At the sampling point a slightly turbid solution was obtained, which still contained 2.1 g / l of undissolved magnesium salts, corresponding to a conversion of the magnesium hydroxide used of 73.8%.

Claims

claims

A continuous process for carrying out a chemical reaction in which a gaseous phase is added to a feed stream containing one or more solid phases dissolved or dispersed in water, characterized in that

a rotor / stator device is used, with a rotor (1) and a stator (2), which form a shear zone (3) with their surfaces facing each other, to which a mixing zone (4) with an opening (7) Mixing zone (4) connects to the outside, wherein the shear zone (3) upstream of a feed and the mixing zone (4) is followed by an outlet,

the feed stream containing one or more solid phases dissolved or dispersed in water is added to the rotor / stator device via the feed (5) into the shearing zone (3),

in the shear zone (3) an overpressure of at least 1 bar is built up,

into the mixing zone (4) the gaseous phase is mixed into the feed stream below the opening in the shear zone (3) of at least 1 bar or under further pressure increase, thereby obtaining a reaction mixture,

- Which is supplied via the outlet (6) of a dwell time zone in which the reaction takes place and

- A pressure control valve is connected downstream, via which the pressure in the

Mixing zone (4) is controlled.

2. The method according to claim 1, characterized in that the shear zone (3) by a conical shear gap with by axial displacement of the rotor (1) and stator (2) adjustable gap width, the mixing zone (4) through an annular space, the feed (5 ) is formed as an axial nozzle and the outlet (6) as a radial nozzle.

3. The method according to claim 1, characterized in that the rotor / stator device includes a tool, preferably on the rotor and the stator each having at least one sprocket and that the shear zone (3) is formed as a gap between the sprockets of the rotor and the stator, to which an annular space adjoins, in which the gaseous phase is mixed under an overpressure of at least 1 bar.

4. The method according to claim 1, characterized in that the rotor / stator device is a propeller system with a stator and a rotor with two or more pairs of wings, wherein the shear zone (3) is the area between the pairs of wings of the rotor and the stator, in which a pressure of at least 1 bar is established and to which a further region between at least one pair of vanes of the rotor and the stator as a mixing zone (4) connects and wherein the facing surfaces of the stator and vanes of the rotor are preferably structured.

5. The method according to any one of claims 1 to 4, characterized in that the feed stream additionally contains one or more organic phases.

6. The method according to any one of claims 1 to 5, characterized in that the addition of the feed stream via a powder attachment of the rotor / stator device takes place.

7. The method according to any one of claims 1 to 6, characterized in that the residence time zone is a tubular reactor.

8. The method according to claim 7, characterized in that the residence time zone additionally comprises a stirred tank.

9. The method according to any one of claims 1 to 8, characterized in that the pressure regulating valve is connected downstream of a device for the separation of solids.

10. The method according to any one of claims 1 to 9, characterized in that the feed stream contains a magnesium salt as a solid phase and that the gaseous phase contains carbon dioxide.