WO2023174825A1 - Drying device for polymer granules - Google Patents

Abstract

The invention relates to a trickling device (10) for a particulate material, the trickling device (10) having a feed region (20), a middle region (30), and a dispensing region (40), the feed region (20) being arranged above and directly adjacent to the middle region (30), the middle region (30) being arranged above and directly adjacent to the dispensing region (40), the trickling device (10) having an outer wall (50), the middle region (30) having a first axis of symmetry (60), a first body (70) being arranged at least in the middle region (30), the first body (70) extending over the entire length of the middle region (30), the first body (70) having a second axis of symmetry (60), the first axis of symmetry (60) and the second axis of symmetry (60) being coaxial, the distance between the outer wall (50) and the first body (70) in the middle region being constant, at least one first fluid feed (80) and an optional second fluid feed (90) being arranged in the middle region (30), the first fluid feed (80) and the optional second fluid feed (90) being designed to provide a uniform feed of fluid over the cross-section of the trickling device (10).

Description

Drying device for polymer granules

The invention relates to a device for drying polymer granules.

Corresponding devices are known from the prior art. In simple terms, the granules are fed in from above, while gas is passed through in countercurrent from below.

Polyamide conditioning is known from EP 2 671 902 B1.

From DE 39 23 061 C1 a method and a device for drying and tempering polyamide granules are known.

A continuous process for multi-stage drying and post-condensation of polyamide granules is known from WO 2009/153 340 A1.

From US 2009/0163694 A1 a process for the continuous drying of highly efficient aqueous aminoformaldehyde resin solutions is known.

However, it has been shown that in conventional systems a central, particularly rapid flow of granules occurs in the middle of the device. This effect becomes more noticeable at larger radii, so the larger the device becomes, the stronger the effect becomes. In return, the gas flow in this area is slow. This leads to different residence times for the granulate particles and thus to different drying times.

The product homogeneity of granules, also called chips, is very much determined by the residence time distribution of the granules and by the residence time distribution of the gas within the device. The gas can be fed to the granules in countercurrent or cocurrent. Particularly in the case of larger apparatus internal diameters with a diameter of more than 2 m, conventional construction according to the current design results in zones with slower flow and zones with faster flow. Capacities of more than, for example 100 t/d for polyamide could therefore only be served with two machines operated in parallel. However, it is desirable to make it possible to realize the drying stage, for example for polyamide, with a throughput of 200 t/d and more in one device.

The object of the invention is to create a flow profile for gas and granules that achieves particularly uniform drying.

This task is solved by the trickle device with the features specified in claim 1. Advantageous further developments result from the subclaims, the following description and the drawings.

The trickle device according to the invention is suitable for a particulate material. Such trickle devices are used as a drying device, condensation device, post-condensation device, conditioning device or as a silo device. The particulate material is particularly preferably a polymer granulate, in particular polyamide, polyethylene terephthalate, polylactide and their copolymers. In particular, the trickle device is used to process these polymers after their production. The trickle device has a feed area, a middle area and an output area.

The particulate material is fed into the feed area, then trickles through the middle area and then ends up at the bottom of the output area where it can be removed from the trickle device. The outlet for the particulate material is preferably arranged centrally on the underside. Therefore, the feed area is arranged above and immediately adjacent to the middle area and the middle area is arranged above and immediately adjacent to the output area.

The trickle device has an outer wall. The outer wall in the sense of the invention is to be understood as the outer boundary of the interior. The outer wall can have further supporting structures, insulation layers, heat transfer surfaces or the like on the outside, which, however, are not part of the outer wall in the sense of the term of the invention. The central area has a first axis of symmetry. For the For example, for a tubular outer wall, the central axis of the cylinder is the axis of symmetry. This runs vertically in the longitudinal direction through the central area. This would also be the case for a polygonal cross-section, for example a square, hexagonal or octagonal cross-section. A first body is arranged at least in the central region. The first body extends the entire length of the midsection, from top to bottom. The first body also has a second axis of symmetry. What was said about the cross section and axis of symmetry of the outer wall applies accordingly here. The first axis of symmetry and the second axis of symmetry are identical, so they lie exactly on top of each other. For example, if both have a circular cross section, the center of both circular cross sections is at the same position. The distance between the outer wall and the first body is constant in the middle area. This means that the first body can taper, for example, in which case the taper also takes place in parallel in the outer wall, so that the residence time distribution is not negatively influenced by the constant distance. At least a first fluid feed and an optional second fluid feed are arranged in the middle area or in the output area. An arrangement in the output area is preferably carried out as directly as possible below the central area. The fluid feeds serve to supply a fluid, in particular a gas, into the interior. On the one hand, this allows the particulate material to be fluidized. However, it is preferred that no fluidization is effected, but only drying. On the other hand, in the case of drying, a dry gas, for example nitrogen or dry air, is supplied in order to dry the particulate material. The first fluid feed and the optional second fluid feed are designed to supply fluid across the surface across the cross section of the trickle device. A flat supply in the sense of the invention is to be understood as a supply of fluid across the cross section, in particular perpendicular or inclined to the axis of symmetry, with several supply points being present along the radial course.

Examples of flat supply of fluids are, for example, several annular elements with several supply points along the respective ring, with the different rings each having different radii. The elements for surface distribution can also not be ring-shaped; for example, they can be similar polygons of different sizes, for example hexagons with one common center. Alternatively, the fluid feed can also be designed in a spiral shape. Furthermore, the flat feed can have an inclination, in particular the fluid feed is inclined so that it is arranged higher on the outside than in the middle. Alternatively, the flat supply can be carried out by double cone gassing, in which the fluid supply from the side is created by conical design of the jacket, a slot-shaped supply. As a result, the fluid is supplied with a downward and inward velocity component, so that a flat distribution of the fluid is created. Furthermore, the conical shape can already be part of the narrowing to a material removal arranged at the lower end. This embodiment is particularly preferred for a fluid feed arranged at the lower end. The double cone gassing is particularly preferably supplemented by an additional simultaneous fluid feed at the lower end of the first body. The fluid can be fed in over the entire surface or in a structured manner, for example through side nozzles. If two fluid feeds arranged one above the other are used, the upper one is preferably not designed as a double cone gassing.

In particular, the fluid feed does not have to be arranged flat, i.e. perpendicular to the axis of symmetry. In particular, the fluid feed can be designed such that it is higher on the outside, which is directed towards the outer wall, than on the side directed towards the first body. This is particularly preferred if the fluid feeds are firmly connected to the first body, but not to the outer wall, since this optimizes the flow of force.

The first fluid feed and the second fluid feed are arranged one above the other. Preferably the first fluid feed is arranged in the upper 20% of the central region and the second fluid feed is arranged in the lower 20% of the central region.

The particulate material is in contact with the outer wall and with the first body. Of course, this also leads to heat transfer between the particulate material and the outer wall or the first body. The particulate material may typically have a particle size of 1 to 5 mm. For example, the average particle size can be 2.5 mm.

In a further embodiment of the invention, the outer wall has a constant first cross section over the central region. In the context of the invention, this is to be understood as meaning that the central region, for example and preferably, has a round cross section with a radius r. The central region then has this round cross section with the radius r at every position along the longitudinal axis, resulting in the basic shape of a hollow cylinder. In this case, the outer wall in the middle area would be a pipe with a constant diameter r. In this embodiment, the first body has a constant second cross section over the central region, analogous to the outer wall.

In a further embodiment of the invention, the diameter of the first body is at least as large as ten times the particle size of the particulate material, the particle size used being the size at which 50% of all particles are below the particle size (dpso).

In a further embodiment of the invention, the diameter of the first body is 0.1 to 0.2 times the diameter of the outer wall.

In a further embodiment of the invention, the first body and the outer wall consist of the same material, in particular stainless steel.

In a further alternative embodiment of the invention, the outer wall consists of a first material, for example stainless steel, and the first body consists of a second material, for example Plexiglas. The first material and the second material particularly preferably have a comparable roughness.

In a further embodiment of the invention, the ratio of the diameter of the outer wall to the diameter of the first body in the central region is in the range 5:1 to 10:1. This ratio is particularly preferably 8:1. This creates an optimum between equalization and reduction of the volume used for the particulate material.

In a further embodiment of the invention, the length of the first body, in particular the length of the straight part of the first body, corresponds exactly to the length of the central region.

In a further embodiment of the invention, the first fluid feed and the second fluid feed are at a distance from the outer wall, the distance between the first fluid feed and the outer wall or the second fluid feed and the outer wall being at least 10 times, preferably 20 times Particle size of the particulate material corresponds, with the particle size used being the size at which 50% of all particles are below the particle size (dpso). Likewise, the first fluid feed and the second fluid feed have a distance from the first body, the distance between the first fluid feed and the first body or the second fluid feed and the first body being at least 10 times, preferably 20 times, the particle size of the particulate material, whereby the particle size used is the size at which 50% of all particles are below the particle size (dpso). If the first fluid feed and the second fluid feed consist of different elements, for example annular elements, these elements preferably also have a distance from one another which is at least 10 times, preferably 20 times, the particle size of the particulate material, the particle size being the Size is used where 50% of all particles are below the particle size (dpso).

In a further embodiment of the invention, the first fluid feed and the second fluid feed have a distance from the outer wall, the distance between the first fluid feed and the outer wall or the second fluid feed and the outer wall corresponding to a maximum of 120 times the particle size of the particulate material, where The particle size used is the size at which 50% of all particles are below the particle size (dpso). Likewise, the first fluid feed and the second fluid feed are at a distance from the first body, wherein the distance between the first fluid feed and the first body or the second fluid feed and the first body corresponds to a maximum of 120 times the particle size of the particulate material, the size being used as the particle size at which 50% of all particles are below the particle size ( d _P so). If the first fluid feed and the second fluid feed consist of different elements, for example annular elements, these elements are preferably also at a distance from one another which is at most 120 times the particle size of the particulate material, the size being 50 being used as the particle size % of all particles are below the particle size (d _P so), corresponds.

In a further embodiment of the invention, the first fluid feed and the second fluid feed have a distance from the outer wall, the distance between the first fluid feed and the outer wall or the second fluid feed and the outer wall corresponding to 80 times the particle size of the particulate material, where as Particle size the size is used at which 50% of all particles are below the particle size (d _P 5o). Likewise, the first fluid feed and the second fluid feed have a distance from the first body, the distance between the first fluid feed and the first body or the second fluid feed and the first body corresponding to 80 times the particle size of the particulate material, the particle size being the Size is used where 50% of all particles are below the particle size (d _P 5o). If the first fluid feed and the second fluid feed consist of different elements, for example annular elements, these elements are preferably also at a distance from one another which is 80 times the particle size of the particulate material, the particle size used being the size at which 50% of all particles are below the particle size (d _P 5o).

In a further embodiment of the invention, the trickle device has a third fluid feed, wherein the third fluid feed is preferably arranged in the middle of the central region (center ± 10%). In a further embodiment of the invention, the first body has a conical shape in the feed area, with the tip pointing upwards. This achieves a good distribution of the particulate material and no accumulation of particulate material forms on the first body.

In a further embodiment of the invention, the tip of the first body has a distance from the material feed in the feed area, the distance between the tip and the material feed corresponding to 50 times to 300 times the particle size of the particulate material, the size being used as the particle size where 50% of all particles are below the particle size (dpso). The distance between the tip and the material feed preferably corresponds to 200 times the particle size of the particulate material.

In a further embodiment of the invention, the first fluid feed and the second fluid feed are designed to be rotationally symmetrical, in particular annular or polygonal, particularly preferably in the form of several concentric rings with different diameters.

In a further alternative embodiment, the fluid feed is designed in a spiral shape. The spiral-shaped fluid feed preferably has an inclination, with the outside preferably being higher than the inside. Furthermore, in the spiral-shaped fluid feed, the distance between the different areas of the spirals corresponds to 50 to 100 times, particularly preferably 80 times, the particle size of the particulate material corresponds, whereby the particle size used is the size at which 50% of all particles are below the particle size (dpso).

In a further embodiment of the invention, the trickle device has a fluid supply to the first fluid feed and to the second fluid feed, the fluid feed being arranged in the first body. Through the fluid supply, the fluid supplied from the outside reaches the fluid feeds and thus into the interior of the trickle device. In a further embodiment of the invention, the first body in the feed area is connected to the outer wall in a load-bearing manner. The first body is thus arranged practically hanging inside. The advantage is that the flow of the particulate material is irregular in the feed area, but is no longer disturbed by supporting structures in the lower area.

In a further embodiment of the invention, the first body is connected to the outer wall in the output area. In particular, the first body is supported thereby. Particularly preferably, the first body is connected to the outer wall in the feed area in a load-bearing manner and is connected to the outer wall in the output area. This achieves optimal attachment with minimal disruption to the flow in the central area.

In a further embodiment of the invention, the fluid supply is partially arranged in the connection between the first body and the outer wall in the feed area.

In a further embodiment of the invention, the trickle device is a drying device.

In a further embodiment of the invention, the first body can also have a more complex structure. For example, the first body can be constructed from three tubular partial bodies that are connected to one another and constructed symmetrically about the axis of symmetry.

During operation, the volume flow of the particulate material is preferably set so that the ratio of the internal volume to the volume flow is between 2 and 25, preferably between 3 and 20, particularly preferably around 18. This means that the particulate material has an average residence time of 2 to 25, preferably 3 to 20, particularly preferably 18 hours.

The trickle device according to the invention is explained in more detail below using exemplary embodiments shown in the drawings. Fig. 1 first exemplary longitudinal section

Fig. 2 first exemplary cross section

Fig. 3 second exemplary cross section

Fig. 4 second exemplary longitudinal section

The exemplary embodiments are schematic and not to scale and are intended only to illustrate the ideas of the invention.

A first exemplary longitudinal section of a trickle device 10 is shown in FIG. The trickle device 10 has a feed area 20 arranged at the top, a middle area 30 arranged underneath and an output area 40 arranged at the very bottom. A material feed 130 opens into the feed area 20, via which particulate material can be fed. The particulate material then trickles through the trickle device 10 and can then be removed again by a material removal 140 that opens into the output area 40. The trickle device 10 has an axis of symmetry 60. The first body 70 also lies on this axis of symmetry 60, which is connected to the outer wall 50 of the trickle device 10 via load-bearing connections 120 in the feed area 20 and is thus held mechanically. A first fluid feed 80 and a second fluid feed 90 are arranged on the first body 70. In the feed area 20, the first body 70 has a conical tip 100, so that the particulate material, which is introduced from the material feed 130 into the trickle device 10, is safely guided into the central area 30. The conical tip 100 has an angle of 20° to 120°, preferably 40°, at the tip. Likewise, the output area 40 can have an angle of 10° to 60°, preferably 45°.

In order to be able to introduce a fluid into the interior of the trickle device 10, the trickle device 10 has a fluid supply 110. Through the fluid supply 110, the fluid is guided via a supporting connection 120 and the first body 70 into the two fluid feeds 80, 90 and there through fluid outlets, which are advantageously arranged on the underside of the two fluid feeds 80, 90, into the interior of the trickle device 10 headed. In Fig. 2 and Fig. 3 two different possible exemplary cross sections along AA in Fig. 1 are shown.

Fig. 2 shows a round cross section of the outer wall 50 and a round cross section of the first body 70. In the example shown, the first fluid feed 80 consists of two annular components and four struts. These two annular components and preferably also the struts have fluid outlets on the underside.

A second alternative cross section is shown in Fig. 3. The outer wall 50 and the first body 70 have a round cross section, as in the first example shown. In contrast to the first example, the first fluid feed 80 is designed in a hexagonal shape, which simplifies production of the first fluid feed 80.

The second exemplary longitudinal section shown in FIG. 4 differs from the first exemplary longitudinal section shown in FIG. 1 in that the two fluid feeds 80, 90 have an inclination. As a result, forces can be better dissipated into the first body 70 by the particulate material striking from above.

Reference symbols

10 trickle device

20 task area

30 middle range

40 output area

50 external wall

60 axis of symmetry

70 first body

80 first fluid feed

90 second fluid feed

100 conical tip

1 10 fluid supply

120 load-bearing connection 130 material feed

140 Material removal

Claims

Patent claims 1. Trickle device (10) for a particulate material, the trickle device (10) having a feed area (20), a middle area (30) and an output area (40), the feed area (20) being above and immediately adjacent to the middle area ( 30), the central region (30) being arranged above and immediately adjacent to the output region (40), the trickle device (10) having an outer wall (50), the central region (30) having a first axis of symmetry (60). , wherein a first body (70) is arranged at least in the central region (30), the first body (70) extending over the entire length of the central region (30), the first body (70) having a second axis of symmetry (60). , wherein the first axis of symmetry (60) and the second axis of symmetry (60) are identical, the distance between the outer wall (50) and the first body (70) being constant in the central region, wherein in the central region (30) or in the output region (40 ) at least one first fluid feed (80) is arranged, the first fluid feed (80) being designed for the flat supply of fluid across the cross section of the trickle device (10). 2. Trickle device (10) according to claim 1, characterized in that in the feed area (20) the first body (70) has a conical shape, with the tip pointing upwards. 3. Trickle device (10) according to one of the preceding claims, characterized in that a second fluid feed (90) is arranged in the central region (30), the second fluid feed (90) for the flat supply of fluid over the cross section of the trickle device (10 ) is trained. 4. Trickle device (10) according to one of the preceding claims, characterized in that the first fluid feed (80) and the second Fluid feed (90) is annular, spiral or hexagonal. 5. Trickle device (10) according to one of the preceding claims, characterized in that the trickle device (10) has a fluid supply (1 10). first fluid feed (80) and the second fluid feed (90), the fluid feed (1 10) being arranged in the first body (70). 6. Trickle device (10) according to one of the preceding claims, characterized in that the first body (70) in the feed area (20) is connected to the outer wall (50) in a load-bearing manner. 7. Trickle device (10) according to claim 5 and claim 6, characterized in that the fluid supply (1 10) is partially arranged in the connection between the first body (70) and the outer wall (50) in the feed area (20). 8. Trickle device (10) according to one of the preceding claims, characterized in that the trickle device (10) is a drying device. 9. Trickle device (10) according to one of the preceding claims, characterized in that the first body and the outer wall consist of the same material. 10. Trickle device (10) according to one of claims 1 to 8, characterized in that the outer wall consists of a first material and the first body consists of a second material. 1 1 . Trickle device (10) according to claim 10, characterized in that the first material and the second material have a comparable roughness. 12. Trickle device (10) according to one of the preceding claims, characterized in that the ratio of the diameter of the outer wall to the diameter of the first body in the central region is in the range 5:1 to 10:1. 13. Trickle device (10) according to one of the preceding claims, characterized in that the first fluid feed and the second fluid feed are at a distance from the outer wall, the distance between the first fluid feed and the outer wall or the second fluid feed and the outer wall being at least 10 - times the particle size of the particulate material. Trickle device (10) according to one of the preceding claims, characterized in that the first fluid feed and the second fluid feed are at a distance from the first body, the distance between the first fluid feed and the first body or the second fluid feed and the first body being at least 10 - times the particle size of the particulate material. Trickle device (10) according to one of the preceding claims, characterized in that the first fluid feed and the second fluid feed are at a distance from the outer wall, the distance between the first fluid feed and the outer wall or the second fluid feed and the outer wall being at most 120 times that Particle size of the particulate material corresponds. Trickle device (10) according to one of the preceding claims, characterized in that the first fluid feed and the second fluid feed are at a distance from the first body, the distance between the first fluid feed and the first body or the second fluid feed and the first body being at most 120 - times the particle size of the particulate material. Trickle device (10) according to one of the preceding claims, characterized in that the first fluid feed and the second fluid feed are at a distance from the outer wall, the distance between the first fluid feed and the outer wall or the second fluid feed and the outer wall being 80 times the particle size of the particulate material corresponds. Trickle device (10) according to one of the preceding claims, characterized in that the first fluid feed and the second fluid feed are at a distance from the first body, the distance between the first fluid feed and the first body or the second fluid feed and the first body being 80 times the particle size of the particulate material. Trickle device (10) according to one of the preceding claims, characterized in that in the feed area the tip of the first body is at a distance from the material feed, the distance between the tip and the material feed corresponding to 50 times to 300 times the particle size of the particulate material .