WO1996034239A1

WO1996034239A1 - Crystalline substances drying device

Info

Publication number: WO1996034239A1
Application number: PCT/EP1996/001726
Authority: WO
Inventors: Wolfgang Schmelter
Original assignee: Schering Aktiengesellschaft
Priority date: 1995-04-26
Filing date: 1996-04-25
Publication date: 1996-10-31
Also published as: NO974929L; HUP9802481A3; JPH11504752A; BR9608073A; CZ339897A3; DE19549494A1; NO974929D0; CA2219295A1; KR19990008067A; HUP9802481A2; DE19516254A1; AU5761396A; TR199701244T1; PL322970A1; MX9708022A; EP0824662A1; DE19680284D2; IS4592A; CN1182476A

Abstract

A device is disclosed for drying solutions of substances. Drying is performed by means of microwave radiation. Agitators R 1 and R 2 in the drying chambers TK 1 and TK 2 also aid the drying process. The energy from a generator G reaches each of the drying chambers TK 1 and TK 2 through a microwave coupler 1 subdivided by a parting surface into a front and a rear part. A control unit S regulates both the amount of energy supplied and the speed of rotation of the agitators.

Description

Device for drying crystalline

Substances

The invention relates to a device for drying material solutions, crystalline substances with residual moisture, and also solids with residual moisture, suspensions, emulsions and / or colloids. Drying is carried out using microwaves and a mechanical stirrer. The invention further comprises a method for producing sugar-containing ultrasound contrast agents using a device according to the invention. The application claims German priority of April 26, 1995 with the official file number 195 16 254.

Various process engineering procedures are known for drying solutions, in particular sugar solutions. The essential process steps of these technical systems are determined by dryers, mills and agitators. The solutions are tempered, the liquid is driven off and the solids are mechanically processed. The drying progress is not determined with this method, but the power of the microwave energy is regulated by the surface temperature. The central element of such microwave dryers are the transmitter, conductor and heating chamber. From the publication by Erich Pehl, microwave technology, waveguides and line components; Volume 1, p. 173; Heidelberg, are the basis of calculation for antennas, i.e. Transmitters, known, over which the length L1 for a conical taper of a round tube can be calculated according to the relationship L1 = n • λ / 2 (n = integer with L1 »λ). Transformation elements are recommended for the transitions from rectangular waveguides to round waveguides or conical taper of round waveguides. This is reflected in the Meinke Gundlach publications; Taschenbuch der Hochfrequenztechnik, fourth edition, Volume 2, pp. 40 ff, Berlin, Heidelberg New York Tokyo, 1986 and H. Pύchner, Warmth by Microwaves, Fundamentals, Components, Circuitry, Philips Technical Library 1964.

The temperature is controlled by supplying thermal energy with the aid of microwave radiation of 0.5-15 GHz, preferably 0.91 5 and 2.45 GHz. The disadvantage of these design solutions is that they are O 96-34239

Applicators come to local overheating. As a result, the products to be dried are partially decomposed thermally. This overheating occurs particularly in the area of product accumulations on splashes of the material on conductive and non-conductive surfaces on the inner surfaces of the applicator.

It is therefore the task of drying crystalline substances which are present in solution or have a residual moisture without local overheating occurring and thus the product being destroyed. In particular, changing material properties and varying diffusion properties should not pose a problem during drying.

The object is achieved by a device for drying (i) material solutions, (ii) crystalline substances with residual moisture, (iii) solids with residual moisture, (iv) suspensions, (v) emulsions and / or (vi) colloids, the Device comprises at least one, preferably cylindrical and prismatic drying chamber (TK 1 and TK 2), preferably evacuable and temperable, in which an agitator is arranged, the device comprising at least one microwave coupler (1),

(a) the microwave coupler is connected to the drying chamber (TK1 or TK2);

(b) a separating surface (2) is arranged in the microwave coupler and is oriented essentially perpendicular to the longitudinal axis L of the microwave coupler;

(c) the microwave coupler is conical, the cone opening with the larger cross section facing the drying chamber; and (d) the microwave coupler has the following proportions:

1, 4 <L1 / D2 <9.0 and

2.0 <L1 / L2 <7.0; the values L1, L2, D1 and D2 are characterized as follows: L1 = a • λ / 2 a = 6, 7, 8, 9, 10, 1 1, 12, 13 or 14; L1 = partial length of the longitudinal axis L, which points from the opening surface (2) in the direction away from the drying chamber (TK1 or TK2), L2 = partial length of the longitudinal axis L, which points from the parting surface (2) towards the drying chamber (TK1 or TK2), and

D2 = diameter of the microwave coupler (1) at the level of the separating surface (2), and D1 = diameter of the microwave coupler (1) at the level of the opening to the drying chamber ((TK1 or TK2).

The device preferably comprises several drying chambers, most preferably two drying chambers. At least one microwave coupler is connected to each drying chamber. A plurality of microwave couplers are preferred per drying chamber. In addition, the drying chamber has at least one stirring system. The microwave coupler and the stirring systems can be controlled by known control units. The microwave couplers (taper) are conical, the larger cross section facing the drying chamber and the smaller cross section connected to the generator. A separating surface is arranged between the two cone openings, the position of which is determined according to the proportions and dimensions mentioned above. The diameter of the separating surface should not be less than 120 mm. The distance between the large cone opening and the parting surface should be at least 100 mm. The surface of the separating surface has a minimal absorption coefficient, so that the splashes of the solutions do not spread on the surface.

Microwave drying usually also includes a stirring method. Known agitators can be used here.

A device according to the invention is preferred in which the material of the separating surface has a minimal absorption coefficient. In this way, local thermal heating can be successfully avoided. A device according to the invention is preferred in which the (i) material solutions, (ii) crystalline substances with residual moisture, (iii) solids with residual moisture, (iv) suspensions, (v) emulsions and / or (vi) colloids comprise sugar. Monosaccharides are more preferred. Even more preferred are material solutions, crystalline substances with residual moisture or solids with residual moisture that comprise a contrast agent. An ultrasound contrast agent is most preferred. Such ultrasound contrast media are described in European publications EP-A 0 052 575 (filing date 17.1 1 .81) and EP-A 0 365 467 (filing date 6.4.89). The manufacturing processes are also described in detail in these publications. A device according to the invention is more preferred in which the stirrer (R 1) comprises a stirrer shaft to which at least one L-shaped stirring blade is fastened; the stirring blade is characterized by the following proportions and dimensions:

(0.9 <B1 <1, 3) • π • (TK1) exp (-1/2) 1, 5 <B2 / B1 <2.5 (0.65 <B3 <1, 35) • λ / 2 ; The values B1, B2 and B3 are characterized as follows:

B1 = the width of the long leg of the stirring blade (3); B2 = the length of the short leg including the width of the long leg, and

B3 = the width of the short leg of the stirring blade (3),

the blades have an angle to the plane of rotation, the cross section of the blades is triangular and has a lower blade surface, a rear blade surface and a rear surface, the rear blade surface points in the direction of the short leg, the angles being characterized by the following values:

α-angle between the back of the stirring blade and the axis of rotation has the

Value 5 ° to 15 °; ß-angle between the bottom of the blade and the plane of rotation has the value 2 ° to 10 °; and γ-angle between the blade surface and the plane of rotation has the

Value 25 ° to 40 °.

The combination of the special microwave coupler and the stirring blades successfully prevents thermal decomposition of the products. The amount of microwave energy added can be controlled in a targeted manner depending on the drying progress and the changes in the physical properties of the material inside the product. In this way, the increased diffusion resistances associated with the consolidation are successfully compensated. Baking and overheating of the product is successfully avoided. The drying process is targeted. The result is a product that meets the high demands placed on pharmaceutical products. The device according to the invention has the advantage that by the special embodiment of the microwave coupler, in particular by the defined size and position of the separating surface of the coupler in connection with specifically designed stirrers of the drying process - preferably under vacuum - by measuring the amount of condensate and a control system which determines that it is exceeded Temperature limits in the interior of the product to be dried are prevented, caking and thermal destruction of the product are reliably avoided and drying of the product up to a defined value is made possible. The drying progress is determined by the amount of condensate in the amount of liquid evaporated. The diffusion resistance of the product increases with increasing solids content compared to the solvent to be separated. With the lower evaporating solvent flow, less energy is dissipated with constant energy supply. The temperature of the product rises. When energy is supplied by means of microwave radiation, this temperature rise occurs primarily inside the product and is difficult or impossible to measure on the surface.

This physical process is reproducible with the progress of drying and is taken into account in the control system in such a way that the deviation of the inside temperature from the outside temperature of the product is determined under identical drying conditions at different points of progress (condensate amounts of the separated solvent, certain solvent content). Different sizes and types of product agglomerates or product agglomerations must be taken into account. The product temperature determined in this way is a controlled variable for the control unit, which in turn determines the energy supply of the microwave radiation.

A device according to the invention is preferred in which the

Drying progress is determined and controlled in which the

Diffusion resistance of the product is used as a control variable depending on the drying progress.

A device according to the invention is preferred in which the stirrer (R2) projecting into the drying chamber (TK2) has at least one stirring blade and additionally has one or more loosening agitator blades which are staggered one above the other and which are arranged at a distance (A- |. A _n ) from the lower rotational plane of the agitator (R2) and have the leg width (B4) and include the following proportions and dimensions:

B4 = 0.3 • B 1 to 0.8 • B 1

A-) - A _n = 60 mm to 100 mm.

When examining the individual angles with respect to the plane of rotation, it was found that some angles are more preferred. This results in a device according to the invention in which the loosening agitator blades have angles to the plane of rotation; the cross-section of the loosening stirring blades is trapezoidal and the cross-section of the loosening stirring blades is determined by the angles with the following values: ε-angle between the underside of the stirring blade and the plane of rotation has the value 5 ° to 15 °; φ angle between the beveled top of the blade and the plane of rotation has the value 20 ° to 45 °; and δ-angle between the back of the impeller and the axis of rotation has the value 5 ° to 15 °.

A device according to the invention is particularly advantageous in which the special shape and arrangement of the stirring blades of the stirrer in the first drying chamber and the additional loosening stirring blades in the second drying chamber work together in a sensible manner. The specific cross-sectional shape and arrangement of the stirring blades ensures optimal loosening and mixing of the product. The mix is therefore not only pushed back and forth by the stirring blades, but the drying process is accelerated and optimally designed by means of the stirrers. A particularly advantageous effect is achieved with a device according to the invention by tempering the jacket of the drying chambers in a known manner, so that, depending on the progress of consolidation and the course of the change in toughness, the shear forces between the inner surface of the drying chamber and the product are positive by slightly increasing or decreasing the wall temperature to be influenced. The invention further comprises a method for drying (i) material solutions, (ii) crystalline substances with residual moisture, (iii) solids with residual moisture, (iv) suspensions, (v) emulsions and / or (vi) colloids, the method comprises the following steps: aa) preparation of the solution, bb) optionally filtration, cc) microwave drying by means of a device for drying (i) material solutions, (ii) crystalline substances with residual moisture, (iii) solids with residual moisture, (iv) suspensions, (v) emulsions and / or (vi) colloids, the device comprising at least one essentially cylindrical or prismatic drying chamber in which an agitator is arranged, the device comprising at least one microwave coupler, (a) the microwave coupler is connected to the drying chamber;

(b) a separating surface is arranged in the microwave coupler which is oriented essentially perpendicular to the longitudinal axis L of the microwave coupler;

(c) the microwave coupler is conical, the cone opening with the larger one

Cross section to the drying chamber; and (d) the microwave coupler has the following proportions:

1, 4 <L1 / D2 <9.0 and

2.0 <L1 / L2 <7.0; The values L1, L2, D1 and D2 are characterized as follows:

L1 = a • λ / 2 a = 6, 7, 8, 9, 10, 11, 12, 13 or 14;

L1 = partial length of the longitudinal axis L, which of the

Faces in the direction away from the drying chamber,

L2 = partial length of the longitudinal axis L, which of the

Partition points towards the drying chamber, D2 = diameter of the microwave coupler at the level of the interface, and

D1 = diameter of the microwave coupler at the level of the opening to the drying chamber; d) final drying and e) comminution.

The filtration can be sterile or ultrafiltration or a combination of both.

The product resulting from the final drying has a residual moisture content of 1 percent by weight, preferably 0.5 percent by weight or less.

The product created by this process can be sold as a diagnostic.

A method according to the invention is preferred, wherein the material of the separating surface has a minimal absorption coefficient.

A method according to the invention is very advantageous, the (i) material solutions, (ii) crystalline substances with residual moisture or (iii) solids with residual moisture comprising sugar.

A method is preferred in which the sugar is a monosaccharide.

A method according to the invention is more preferred, the (i) material solutions, (ii) crystalline substances with residual moisture or (iii) solids with residual moisture comprising a contrast agent.

A method according to the invention is most preferred, the (i) material solutions, (ii) crystalline substances with residual moisture or (iii) solids with residual moisture comprising an ultrasound contrast agent.

A method according to the invention is advantageous, wherein the stirrer (R 1) comprises a stirrer shaft to which at least one L-shaped stirrer blade is attached; the stirring blade is characterized by the following proportions and dimensions: (0.9 <B1 <1, 3) • π • (TK1) exp (-1/2) 1, 5 <B2 / B1 <2.5 (0.65 <B3 <1, 35) ^« λ / 2 ; The values B1, B2 and B3 are characterized as follows: B1 = the width of the long leg of the stirring blade;

B2 = the length of the short leg including the

Width of the long leg, and

B3 = the width of the short leg of the stirring blade,

the stirring blades have angles to the plane of rotation, the cross section of the stirring blades being triangular and has one

Lower blade surface, one rear blade surface and one

Stirrer blade surface, the rear side of the stirrer blade points in the direction of the short leg, the angles being characterized by the following values:

Value 5 ° to 15 °; ß-angle between the underside of the blade and the plane of rotation has the

Value 2 ° to 10 °; and γ-angle between the blade surface and the plane of rotation has the

Value 25 ° to 40 °.

A method according to the invention is preferred, in which the stirrer (R2) projecting into the drying chamber (TK2) has at least one stirring blade and additionally one or more loosening stirring blades which are staggered one above the other and are at a distance (A-) ... A _n ) from the lower rotation plane of the stirrer (R2) are arranged and have the leg width (B4) and include the following proportions and dimensions:

B4 = 0.3 • B 1 to 0.8 • B 1

Ai - A _Π = 60 mm to 100 mm.

A method according to the invention is more preferred, wherein the loosening stirring blades have angles to the plane of rotation; wherein the cross section of the loosening blades is trapezoidal and the cross-section of the loosening blades is determined by the angles with the following values: ε-angle between the underside of the blade and the plane of rotation has the value 5 ° to 15 °; φ angle between the bevelled top of the stirring blade and the

The plane of rotation has the value 20 ° to 45 °; and

The o-angle between the back of the dial and the axis of rotation has the value 5 ° to 15 °.

Most preferred is a method according to the invention for drying (i) material solutions, (ii) crystalline substances with residual moisture, (iii) solids with residual moisture, (iv) suspensions, (v) emulsions and / or (vi) colloids comprises the following steps: a) preparation of the solution, b) optionally filtration, c) microwave drying by means of the device, d) final drying, e) comminution and f) agglomeration.

The purpose of the agglomeration is to convert a comminuted substance that is difficult to handle and transportable into a form that does not have these problems. However, the property of rapidly dissolving should not be impaired. The particles in the agglomerite bodies are held together by Van der Vaal forces.

The product obtained by this previously described method is the substance that is sold with great satisfaction. It is easy to incorporate the product in solutions. Then it can be injected into patients. It enables imaging diagnostics to be carried out on the human or animal body, a data material being created which allows the doctor to propose appropriate treatment therapy on the basis of his specific knowledge and specialist knowledge. A method according to the invention in which the material solution is used is more preferred Ultrasound contrast medium contains, most preferred is an ultrasound contrast medium which comprises a monosaccharide, in particular Contrast agents are preferred, which are described in detail in the publications EP-A 0 052 575 and EP-A 0 365 467 mentioned above. The Echovist and Levovist diagnostics include gaseous microparticles based on galactose, with and without palmitic acid.

A method according to the invention is very preferred, the material solution containing an ultrasound contrast agent.

A method according to the invention is most preferred, the ultrasound contrast medium comprising monosaccharides.

The device according to the invention is described below by way of example.

Figure 1 shows a schematic representation of the device.

FIG. 2 shows a schematic illustration of the microwave coupler.

FIG. 3 shows a top view of the stirring blades and a section through a stirring blade of the stirrer of the first drying chamber along the section A - A.

FIG. 4 shows a top view of the stirring blades and a section through a loosening stirring blade of the stirrer of the second drying chamber along the section B - B.

A device for drying solutions is shown schematically in FIG. In this case, these are sugary liquids, namely either Echovist or Levovist. The device consists of a first drying chamber TK 1 with a stirrer R1 and a second drying chamber TK 2 with a stirrer R2. Microwave couplers 1 with generators G and a control unit S are located on the ceiling of the drying chambers. A comminution machine of known type is arranged between the two drying chambers. The product to be dried is introduced into the first drying chamber TK 1 through an inlet opening, not shown. After the device has been switched on, corresponding generator microwave energy is introduced into the drying chamber TK 1 by the generator G via the microwave coupler 1. At the same time, the stirrer R 1 is set in rotation. The is based on these two activities Drying process. The surface temperature and the progress of drying are measured by known sensors, also not shown in the figure, and passed on to the control unit S. Depending on the progress of drying, this controls the amount of energy for the microwave coupler 1 of the drying chamber TK 1 and also the speed of the stirrer R 1 in the manner described above via an installed control program.

The drying process is then continued in the second drying chamber TK 2. Also in the second drying stage, the amount of energy for the microwave coupler 1 and for the speed of the stirrer R 2 is regulated in approximately the same way as described above.

FIG. 2 shows a microwave coupler 1. It has a conical design. The opening with the smaller cross-section faces the generator G and has a square design. The opposite opening, which is connected to the drying chamber, has a round cross section. The microwave coupler 1 is divided into two sectors by a separating surface 2. The surface of the separating surface 2 is perpendicular to the longitudinal axis of the microwave coupler 1 and is divided into two sectors by the separating surface 2. The surface of the separating surface 2 is perpendicular to the longitudinal axis of the microwave coupler 1. As a result, the longitudinal axis is divided into two partial lengths. The partial length L 1 points from the separating surface 2 to the generator G or away from the drying chamber TK 1 or TK 2. The partial length L 1 extends from the separating surface 2 to hm to the drying chamber TK1 or TK 2. The sum of the partial lengths L 1 and L 2 gives the total length of the longitudinal axis L. The separating surface has a diameter D 2. The opening of the microwave coupler, which points to the drying chamber, has a diameter D 1. The relation of the individual lengths, namely L 1, L 2, D 1 and D 2 has been set out in the previous text of the description. Of course, those are in the figure 2 shown proportions are not binding, rather it is a schematic representation.

3 shows three stirring blades 3 of the stirrer R 1. The stirring blades 3 are L-shaped. The direction of rotation of the stirring blades is essentially parallel to the bottom surface of the drying chamber TK 1. A stirring shaft 8 of the stirrer R 1 is perpendicular to the bottom surface. The stirring blades are shown in FIG. 3 both in a top view and in section along the cutting plane A - A The width of the long leg of the Stirring blade 3 with B 1 and the width of the short leg with B 3. The length of the short leg has the designation B 2. The proportions of the length dimensions B 1, B 2 and B 3 have been explained in detail in the previous text. In this case too, the proportions shown are only to be understood schematically.

The cross section represented by section A - A of one of the stirring blades 3 has a triangular shape. Such a stirring blade 3 has three surfaces, namely a downward-facing stirring blade lower surface 5, an upward-pointing stirring blade surface 6 and an essentially sideways-pointing rear stirring blade surface 7. Three angles are essential for the specific orientation of the aforementioned three stirring blade surfaces, namely the angles α, ß and γ. The angle α is from the back of the stirring blade 7 and the axis of rotation; the angle β is formed by the bottom surface of the stirring blade 5 and the plane of rotation, and the angle γ is formed by the surface of the stirring blade 6 and the plane of rotation.

FIG. 4 shows the shape of loosening stirring blades 4 in a top view and in a section, the section being taken along the plane BB. The loosening stirring blades 4 are arranged with a stirring shaft 8 of the stirrer R 2 at a certain distance. The total distance is the sum of Aj to A _n . The loosening stirring blades 4 are perpendicular to the stirring shaft 8 and are arranged spirally around the stirring shaft 8. The width of one of the loosening stirring blades 4 is designated B 4. Section B - B shows the trapezoidal cross section of one of the loosening stirring blades 4. The angles ε, φ and ö are characteristic of the arrangement of the surfaces of the trapezoid. The angle ε is formed by the underside of the stirring blade and the plane of rotation. The angle φ results from the bevelled top of the stirring blade and the plane of rotation. The angle δ is formed by the back of the impeller blade and the axis of rotation. Directory of the reference symbols used

1 microwave coupler

2 dividing surface

3 stirrer blade

4 loosening blade

5 lower blade surface

6 stirring blade surface

7 back of the stirring blade

8 stirrer shaft

TK 1, TK 2 drying chamber

R 1. R 2 stirrer

G generator

S control unit

B 1, B 2, B 3, B 4 stirrer dimensions D 1, D 2 diameter

Claims

9604 239 15Patent claims

1. Device for drying (i) material solutions, (ii) crystalline substances with residual moisture, (iii) solids with residual moisture, (iv)

Suspensions, (v) emulsions and / or (vi) colloids where the

Device comprises at least one essentially cylindrical or prismatic drying chamber (TK 1 and TK 2) in which an agitator is arranged, the device comprising at least one microwave coupler

(D,

(a) the microwave coupler is connected to the drying chamber (TK1 or TK2);

(c) the microwave coupler is conical, the cone opening with the larger cross section facing the drying chamber; and

(d) the microwave coupler has the following proportions:

1, 4 <L1 / D2 <9.0 and 2.0 <L1 / L2 <7.0; The values L1, L2, D1 and D2 are characterized as follows:

L1 = a ^« λ / 2 a = 6, 7, 8, 9, 10, 1 1, 12, 13 or 14; L1 = partial length of the longitudinal axis L, which of the

Partition surface (2) points in the direction away from the drying chamber (TK1 or TK2), L2 = partial length of the longitudinal axis L, which points from the partition surface (2) towards the drying chamber (TK1 or TK2),

D2 = diameter of the microwave coupler (1) at the level of the separating surface (2), and D1 = diameter of the microwave coupler (1) at the opening to the drying chamber ((TK1 or TK2).

2. Device according to claim 1, wherein the material of the separating surface (2) has a minimum absorption coefficient.

3. Device according to claim 1 or 2, wherein the (i) material solutions, (ii) crystalline substances with residual moisture or (iii) solids with residual moisture comprise sugar.

4. The device of claim 3, wherein the sugar is a monosaccharide.

5. Device according to one of the preceding claims, wherein the (i) material solutions, (ii) crystalline substances with residual moisture or

(iii) Solids with residual moisture include a contrast agent.

6. The device according to claim 5, wherein the (i) material solutions, (ii) crystalline substances with residual moisture or (iii) solids with residual moisture comprise an ultrasound contrast agent.

7. Device according to one of the preceding claims, wherein the stirrer (R 1) comprises a stirring shaft (8) on which at least one L-shaped stirring blade (3) is attached; the stirring blade (3) being characterized by the following proportions and dimensions:

(0.9 <B1 <1 ^ 3) • π • (TK1) exp (-1/2)

1, 5 <B2 / B1 <2.5

(0.65 <B3 <1.35) ^« λ / 2; The values B1, B2 and B3 are characterized as follows:

B1 = the width of the long leg of the stirring blade (3);

B2 = the length of the short leg including the

Width of the long leg, and

B3 = the width of the short leg of the stirring blade (3),

the stirring blades (3) have angles to the plane of rotation, the cross section of the stirring blades (3) is triangular and has a lower stirring blade surface (5), a rear stirring blade surface (7) and a stirring blade surface (6), the rear stirring blade surface (7) points in the direction of the short leg, the angles being characterized by the following values are:

Value 25 ° to 40 °.

8. The device according to claim 7, wherein the stirrer (R2) protruding into the drying chamber (TK2) has at least one stirring blade (3) and additionally one or more loosening stirring blades (4) which are staggered one above the other and which are spaced apart (A- |. .. A _n ) are arranged from the lower plane of rotation of the stirrer (R2) and have the leg width (B4) and include the following proportions and dimensions:

B4 = 0.3 • B 1 to 0.8 • B 1

A-] - A _n = 60 mm to 100 mm.

9. The device according to claim 8, wherein the loosening blades (4) have angles to the plane of rotation; the cross section of the loosening stirring blades (4) is trapezoidal and the cross section of the loosening stirring blades (4) is determined by the angles with the following values: ε-angle between the underside of the stirring blade and the plane of rotation has the value 5 ° to 15 °; φ angle between the bevelled top of the stirring blade and the

The plane of rotation has the value 20 ° to 45 °; and δ-angle between the back of the dial and the axis of rotation has the value

5 ° to 15 °. 10. A method for drying (i) material solutions, (ii) crystalline substances with residual moisture, (iii) solids with residual moisture, (iv) suspensions, (v) emulsions and / or (vi) colloids, the method comprising the following steps : aa) preparation of the solution, bb) optionally filtration, cc) microwave drying by means of a device for drying (i) material solutions, (ii) crystalline substances with residual moisture, (iii) solids with residual moisture, (iv) suspensions, (v) Emulsions or (vi)

Colloids, the device comprising at least one essentially cylindrical or prismatic drying chamber (TK 1 and TK 2) in which an agitator is arranged, the device comprising at least one microwave coupler

0) -

(a) the microwave coupler is connected to the drying chamber (TK1 or TK2);

(d) the microwave coupler has the following proportions:

L1 = a ^» λ / 2 a = 6, 7, 8, 9,

10, 1 1, 12, 13 or 14; L1 = partial length of the longitudinal axis L, which of the

Treπnfläche (2) in the direction away from the

Drying chamber (TK1 or TK2) has L2 = partial length of the longitudinal axis L, which points from the parting surface (2) to the drying chamber (TK1 or TK2),

D2 = diameter of the microwave coupler (1) at the level of the separating surface (2), and

D1 = diameter of the microwave coupler (1) at the opening to the drying chamber ((TK1 or TK2). D) final drying and e) comminution.

1 1. The method according to claim 10, wherein the material of the separating surface (2) has a minimum absorption coefficient.

12. The method according to claim 10 or 11, wherein the (i) material solutions, (ii) crystalline substances with residual moisture or (iii) solids with residual moisture comprise sugar.

13. The method of claim 12, wherein the sugar is a Moπosaccharid.

14. The method according to any one of the preceding claims 10 to 13, wherein the (i) material solutions, (ii) crystalline substances with residual moisture or (iii) solids with residual moisture comprise a contrast agent.

15. The method according to claim 14, wherein the (i) material solutions, (ii) crystalline substances with residual moisture or (iii) solids with residual moisture comprise an ultrasound contrast medium.

16. The method according to any one of the preceding claims 10 to 15, wherein the stirrer (R 1) comprises a stirring shaft (8) on which at least one L-shaped stirring blade (3) is attached; the stirring blade (3) being characterized by the following proportions and dimensions:

B1 = the width of the long leg of the stirring blade (3); B2 = the length of the short leg including the

Width of the long leg, and

B3 = the width of the short leg of the stirring blade (3),

The stirring blades (3) are at an angle to the plane of rotation, the cross section of the stirring blades (3) is triangular and has a lower stirring blade surface (5), a rear stirring blade surface (7) and a stirring blade surface (6), with the rear stirring surface (7) pointing in the direction of the short leg, the angles being characterized by the following values-

ß-angle between the underside of the blade and the plane of rotation has the

17. The method according to claim 16, wherein the stirrer (R2) protruding into the drying chamber (TK2) has at least one stirring blade (3) and additionally one or more loosening stirring blades (4) which are staggered one above the other and which are spaced apart (A- | .. A _n ) are arranged from the lower plane of rotation of the stirrer (R2) and have the leg width (B4) and include the following proportions and dimensions:

18. The method according to claim 17, wherein the loosening agitator blades (4) have angles to the plane of rotation, wherein the cross section of the loosening agitator blades (4) is trapezoidal and wherein the cross section of the loosening agitator blades (4) is determined by the angles with the following values ε-angle between the Underside of the blade and the plane of rotation

φ angle between the beveled top of the blade and the plane of rotation has the value 20 ° to 45 °, and δ-angle between the back of the stirring blade and the axis of rotation has the value

5 ° to 15 °.

19. The method according to any one of claims 10 to 18 for drying (i) material solutions, (ii) crystalline substances with residual moisture, (iii) solids with residual moisture, (iv) suspensions, (v) emulsions or (vi) colloids, where that The method comprises the following steps: a) preparation of the solution, b) optionally filtration, c) microwave drying by means of the device, d) final drying, e) comminution and f) agglomeration.

20. The method according to any one of claims 10 to 19, wherein the material solution contains an ultrasound contrast agent.

21. The method of claim 20, wherein the ultrasound contrast agent comprises monosaccharides.