EP1998897A1

EP1998897A1 - Apparatus for drying wet pourable material, preferably polymer particles

Info

Publication number: EP1998897A1
Application number: EP07710527A
Authority: EP
Inventors: Georg Wendelin; Helmut Bacher
Original assignee: EREMA Engineering Recycling Maschinen und Anlagen GesmbH
Current assignee: EREMA Engineering Recycling Maschinen und Anlagen GesmbH
Priority date: 2006-03-30
Filing date: 2007-03-21
Publication date: 2008-12-10
Also published as: AT503390B1; AT11394U2; AT503390A1; WO2007112466A1; DE202007019102U1; AT11394U3

Abstract

An apparatus for drying wet pourable material, preferably polymer particles in granule form, has a rotating body (4) driven about its axis (7) for rotation, at one end (49) of which the material to be dried is introduced through an entry orifice (2) of a casing (1) into a ring gap (6) which exists between the rotating body (4) and a perforated jacket (5) surrounding it. Centrifugal force spins the material introduced onto the jacket (5) and dries it at the same time. The liquid passes into a ring gap (23) between the jacket (5) and the casing (1). The rotating body (4) and the perforated jacket (5) each widen from the entry orifice (2) in the direction toward the collecting space (22). A spiral (20) secured on the outer surface of the rotating body (4) forms a conveying unit for the material, the outer edge of this spiral (20) being closely adjacent to the perforated jacket (5).

Description

Device for drying wet pourable goods, preferably from

Plastic particles

The invention relates to a device for drying wet 5 pourable goods, preferably of plastic particles, in particular in the form of granules, with a rotary body driven to rotate about its axis, at one end of which the goods to be dried pass through an inlet opening of a housing surrounding the rotary body into a between this rotary body and an annular gap surrounding it, the material introduced is thrown by centrifugal force onto the inner surface of the perforated jacket, so that the liquid penetrates the perforation of the jacket and enters an annular space surrounding the jacket and enclosed by the housing , which is provided with a drain opening for the liquid, and wherein on the outer surface of the rotating body arranged conveying elements to the gradually dried material to one

15 other end face of the rotating body arranged collecting space, from which it leaves the housing through an outlet opening.

Wet or moist plastic granules, in particular granules supplied by a granulating system, are usually dried in centrifuges. The centrifugal force is used for centrifuging and for drying the cooling liquid or other moisture adhering to the granules 0. The resulting air flow promotes drying. Such a device is e.g. known from DE 28 14 199. The plastic material is introduced into a fixed inner tube, on the outer surface of which inclined blades are attached along a helix. A second pipe surrounds at a short distance from the

25 shovels the inner tube and is driven to rotate about its axis. It is perforated and has a bottom. The material introduced into the inner tube, which is pressed against the inner surface of the outer tube by the centrifugal force arising when the base of the outer tube rotates, reaches this base. Here it is gripped by the blades and transported upwards,

30 until it is gripped and blown out by a radial fan at the upper end of the outer tube. A disadvantage of this construction is the apparent increase in weight of the material to be dried, which is caused by the centrifugal force. In order to transport the material, which is highly compressed by the centrifugal force, the blades have to penetrate the material, which requires a considerable amount of force. In addition, the

35. considerable friction of the good can be overcome when it is transported on the inner surface of the outer tube. The drive must therefore be designed accordingly strong. Hard or brittle granules, such as polystyrene, suffer from this considerable abrasion, which means loss of material on the one hand and dust on the other.

Another construction developed by the applicant is designed in the manner described above. Here, a fixed cylindrical perforated tube surrounds a coaxial cylinder, which is closed at the top by a cover and is driven by a motor to rotate about its axis. Sloping blade-like wings are attached to the jacket of the cylinder. The material to be dried is flung onto the perforated tube by sling bars on the cover of the cylinder, from where it springs back, is gripped by the rotating vanes and accelerated back to the perforated tube. Gravity also gradually moves the material downwards in the axial direction, which movement the rotating blades counteract. The material to be dried therefore describes a zigzag path until it is caught by a radial fan at the lower end of the cylinder and flung out of the device. The disadvantage here is the frequent back and forth throwing of the goods, which requires high drive energy and results in significant abrasion in the case of brittle granules. In addition, it is not guaranteed that each granulate has the same residence time in the centrifuge, so that the end product can have uncontrollable moisture differences. Finally, the zigzag movement of the granules creates a high-frequency noise, so that such a centrifuge can only be operated with an expensive sound-absorbing hood or in a sound-absorbing cabin.

The object of the invention is to improve a device of the type described at the outset in such a way that the material introduced is dried with a high degree of efficiency without the disadvantages described above, such as noise, abrasion, high drive power, uneven drying, etc. being accepted have to. The invention solves this problem in that the rotary body and the perforated casing each widen from the inlet opening in the direction of the collecting space and the conveying members are formed by at least one helix fastened to the outer surface of the rotating body, the outer edge of which is close to the perforated casing. In such a device, the material to be dried is thus always introduced at the smaller end of the rotating body or the perforated jacket, the material being thrown against the inner surface of the perforated jacket in the annular gap between the rotating body and the perforated jacket. The liquid that is thrown out penetrates the perforation of the jacket and is collected and drained off in the annular space. Due to the widening shape of the perforated jacket, the goods tend to slide along the jacket surface to the larger end of the jacket. Depending on the selected inclination of the perforated jacket and the speed and shape of the helix, the material is braked or accelerated in its sliding movement. The required energy requirement is low, as is the developed noise level and the abrasion that occurs on the goods.

Further advantages of the construction according to the invention are as follows: The volume flow of the material to be dried in the direction of the larger diameter of the gap between the rotating body and the jacket is thinned out by this increasing diameter, which leads to better ventilation and consequently also to a better drying effect. In comparison with known construction methods, the residence time of each particle to be dried is more uniform and longer in the construction according to the invention, so that the drying time is increased. The construction according to the invention forming a centrifuge can be used both for continuous feeding and with a different volume flow of feeding. It is also advantageous that, in the construction according to the invention, the granules to be dried glide smoothly along the surface of the casing without significant noise, so that a sound absorbing hood or sound absorbing cabin, as is required in the known devices, is unnecessary.

Finally, with a suitable inclination of the sliding surface of the casing, the granulate particles cannot become jammed between the helix and this surface, since the centrifugal effect causes the granulate to move independently in the direction of the larger diameter of this casing surface.

According to a preferred embodiment of the invention, the rotating body and the perforated jacket each have the shape of a truncated cone or a cambered shape with a continuous course. Both forms are easy to create. According to the invention, the perforated jacket is preferably driven to rotate about its axis, in the same direction of rotation as the rotating body, but at a lower speed. This enables a particularly effective and gentle transport of the particles to be dried from the inlet opening in the direction of the outlet opening of the housing and accordingly a particularly effective uniform drying. By choosing the taper or the formation of the crown of the rotating body or the perforated jacket and by choosing the speed of these two components, different operating conditions can be set in a simple manner and the device can accordingly be adapted to different existing conditions. Suitable rotational speeds of the rotary body are 700 to 1200 revolutions / minute, the rotational speed of the perforated jacket being about 100 revolutions / minute lower, thus about 600 to 1100 revolutions / minute. For design reasons, it is usually favorable to keep the radial width of the gap between the rotating body and the perforated jacket constant. However, this is not absolutely necessary. Rather, by reducing this radial width, the advantage can be achieved that the thinning that increases during the transport of the material to be dried is at least largely compensated for. The change in the radial width of the gap mentioned must then of course be adapted accordingly to the outside diameter of the helix. A similar effect can be achieved if the helix is designed with a gradient decreasing towards the larger front end of the rotating body. A multi-start helix can also be used.

Different effects on the transport of the goods through the device can also be achieved in that the rotating body and the perforated jacket are each composed of at least two truncated cones with different opening angles. A particularly favorable embodiment of the invention consists in that the rotary body is also perforated and at least one blower is arranged in its interior, in particular blades rotating about the axis of the rotary body. This favors the drying of the material introduced into the device.

Further characteristics and advantages of the present invention result from the description of exemplary embodiments which are shown schematically in the drawing. 1 shows an axial section through the device, the goods being transported in the device from top to bottom. 2 shows a similar section through an embodiment variant in which the material to be treated is fed in at the bottom, so that the material is transported in the device from bottom to top. Fig. 3 shows a detail of a variant of Fig. 2 in section.

In the embodiment according to FIG. 1, the device has a truncated cone-shaped housing 1, which has an annular inlet opening 2 at the top for the material to be dried. A funnel 3 is connected to this inlet opening 2 at the top. In the housing 1, a truncated cone-shaped rotating body 4 and a truncated cone-shaped casing 5 are arranged concentrically to one another. The rotating body 4 and the casing 5 are formed by perforated sheets. The perforation must be designed such that the material introduced into the gap 6 existing between the rotating body 4 and the casing 5 can only emerge from it at the lower end of this gap 6. These two components 4, 5 can be formed by perforated plates, but the perforation can also have a slot shape. Both the rotating body 4 and the casing 5 are driven to rotate about the common axis 7, for which purpose the rotating body 4 at its upper, smaller end 49 through a cover 8 and at its lower, larger end 50 is closed off by a base 9, these two components 8, 9 being connected to a central shaft 10 which is driven by a pulley 11 by a motor (not shown) for rotation about its axis (arrow 12). A further pulley 13 is rotatably seated on the shaft 10 and is likewise driven by a motor (not shown) for rotation about the axis 7. The pulley 13 is fixedly connected to a connecting piece 14, which drives a base 15 of a radial fan 16 for rotation about the axis 7. On this floor, wings 17 are fastened, and a ring 18, to which the lower, larger end 52 of the casing 5 is fastened. This rim is guided on its outer circumference on a wall 19 of the housing 1 and is thereby stored. The two pulleys 11, 13 are driven in the same direction, so that the rotating body 4 and the casing 5 rotate in the same direction, but the casing 5 with a lower peripheral speed compared to the rotating body 4. Suitable speeds are about 700 to 1200 revolutions / minute for the rotating body and 600 to 1100 revolutions / minute for the casing. A separate bearing can be provided for the upper, smaller end face 51 of the casing 5, it is not necessary since this end face can be supported on a helix 20 which is fastened to the outer surface of the rotary body 4. The outer circumference of this helix 20 is at a short distance, about 0.5 mm, from the inner surface of the jacket 5. The gap 6 opens at the bottom into a collecting space 22 for the dried material located below the bottom 9. The radial fan 16 lies in this collecting space 22 and conveys it to the outside through an outlet connection 21. The housing 1 surrounds the jacket 5 at a distance, so that an annular space 23 is formed for the collection of the thrown off water, which opens at its lower end into a collecting channel 53 which is provided with a drain pipe 24. Furthermore, the annular space 23 has an air outlet connection 25 in its upper region. In the cavity 40 of the hollow rotating body 4 there is a blower 26 which can be formed in a simple manner by at least one paddle wheel 27 which is fixedly connected to the shaft 10 and by the latter is driven to rotate.

The material to be dried is introduced into the device from above in the direction of arrow 28. It passes through the inlet opening 2 into the conical gap 6 between the rotary body 4 and the jacket 5. Here, the material is carried along by the helix 20 and from the outer surface of the rotary body 4 for rotation around the axis 7 and by centrifugal force on the inner surface of the conical Coat 5 hurled. The liquid adhering to the relevant good particle is thrown off and the good is thereby dried. The centrifuged liquid passes through the openings of the perforated jacket 5, is collected in the annular space 23, flows downward in this and finally leaves the annular space 23 through the drain pipe 24. The Drying effect on the mostly formed from plastic granules is increased by the air flow which is generated by the blower 26 and passes through the rotating body 4 and the jacket 5.

With a suitably chosen angle of inclination α of the conical surface of the casing 5 (in relation to the direction of the axis 7), the individual granules will automatically want to slide towards the larger conical diameter, but will be held back by the continuous helix 20 forming a conveying element. If the cone inclination angle α is too small to achieve this, the granulate will try to remain, but is pushed forward by the continuous conveyor helix 20 towards the larger end of the cone end, i.e. downwards, since the conveying direction of the helix 20 is directed downwards . Only little energy is required for this advance. The conditions depend not only on the angle of inclination α, but also on the coefficient of friction which exists for the granules sliding on the jacket 5 and on the speed of the jacket 5. At the lower, larger end of the conical gap 6, the material finally reaches the radial fan 16, which dries the dried Well captured and drives it out of the device through the blow-out nozzle 21. The blades 17 of this radial fan 16 are relatively thick-walled in order to keep the developed noise as low as possible. The radial fan 16 has a spiral housing, from which the material is ejected through the blow-out nozzle 21. The bottom 15 of the casing 5, which at the same time forms the bottom of the impeller of the radial fan 16, has air slots 29, analog air slots 30 are provided in the bottom 31 of the housing 1, further air slots 32 in the bottom 9 of the rotating body 4. Through these air slots 29, 30 , 32, on the one hand, the air supply to the radial blower 16 is ensured, on the other hand, the air supply to the blower 26. The air flow generated by it passes through the openings of the rotating body 4 and the jacket 5 and thereby dries the material in the gap 6.

The rotation body 4 and the casing 5 for the rotary movement are expediently driven by a common motor, not shown. The somewhat lower rotational speed of the casing 5 compared to the rotational speed of the rotating body 4 is achieved by a larger diameter of the pulley 13 compared to the diameter of the pulley 11. The transmission formed by the two pulleys 11, 13 is located within a hollow base 33 which supports the housing 1.

While the passage of the goods through the device takes place from top to bottom in the embodiment according to FIG. 1, this is reversed in the embodiment according to FIG. 2, that is to say from bottom to top. For this purpose, a pipe 34 forming the feed line 34 for the material to be dried is inserted into the housing 1, said pipe being directed upwards has a funnel-like widening mouth 35. The wall 36 of this mouth 35 forms, together with the lower edge of the casing 5, a gap seal 37. A reinforcement 38 prevents the lower end of the casing 5 from widening. The casing 5 is rotated around the axis 7 at its upper end by a not shown Drive driven, for example, the jacket 5 may be provided with a ring gear which is driven by the motor for rotation. The rotary movement of the rotary body 4 takes place via the central shaft 10 and the pulley 11 as in the embodiment according to FIG. 1, the rotary body 4 being carried along by the shaft 10 via a base 39 connecting the two components 4, 10 for the rotary movement. This bottom 39 is provided with air slots 11 in order to be able to ventilate the lowermost area of the cavity 40 enclosed by the rotating body 4. At its lower end, the rotary body 4 is closed off by a further base 41, which slides sealingly on a tubular connecting piece 42 of the housing 1 and prevents the material introduced into the device via the feed line 34 from penetrating into the cavity 40 from below. The annular space 23, in which the liquid spun off from the material is collected, has at the bottom an extension 43 opposite the feed line 34, from which the liquid is conducted via the drain pipe 24 into the interior of the base 33. From there this liquid can be drained in any way.

In this embodiment, both the rotating body 4 and the casing 5 are each composed of two frustoconical sections 44, 45 and 46, 47, respectively, which have different opening angles, the opening angle of the upper sections 44, 46 being less than the opening angle of the lower sections 45, 47. This ensures that the still very moist material that enters the gap 6 between the rotating body 4 and the jacket 5 via the mouth 35 can slide upwards when it hits the jacket 5 and is thus reliably captured by the coil 20 . As a result, the risk is also very low that undried material can get through the gap seal 37 into the annular space 23 or its extension 43.

In the embodiments described so far, the helix 20 had a constant slope, but this is not absolutely necessary. Rather, in many cases it is favorable to make the helix degressive in the conveying direction, ie with a reduced pitch. Such an embodiment is shown in FIG. 3 in a construction in which the goods are transported from bottom to top (FIG. 2). As can be seen, the pitch of the helix 20 decreases in the direction of conveyance, ie to the larger diameter of the frustoconical components 4, 5 (arrow 48). As a result, the thinning of the material to be dried can be at least largely compensated for, in particular if the coil volume, ie the volume of the coil 20 measured per pitch, is at least approximately constant with increasing diameter. Similar conditions can also be applied to a helix 20 which is of multi-start design.

The rotating body 4 and the casing 5 do not necessarily have to be frustoconical or composed of frustum sections. Rather, a curved shape is also possible. As can be seen, the embodiment according to FIG. 2 is approaching a convex shape. However, a continuous course of the conical surface or the cambered surface along which the granules slide is required to ensure a continuous transport of the granules towards the collecting space 22. The rotary body 4 and the casing 5 can be driven by different drives, at least one of these drives being designed as a vario drive. The rotational speed of the rotating body 4 and / or the casing 5 can thus be adapted to different existing conditions, so that the device can be used universally. The choice of the angle of inclination α of the truncated cone surfaces or the cambered

The area of the rotating body 4 or of the casing 5 largely depends on the friction conditions which the material to be dried finds on the perforated or slotted plate of the casing 5. In practice, angles of inclination α of approximately 15 to 20 ° have proven to be suitable, although measurements with perforated plates have shown a spread of the friction angles between 17 and 31 °. Vibrations, which the material to be dried finds on the jacket 5, can reduce the friction and thus the size of the angle of inclination α by up to half.

The radial width of the gap 6 existing between the rotating body 4 and the perforated jacket 5 can be dimensioned constantly, which results in a particularly simple construction. This radial width can, however, also be designed to decrease towards the collecting space 22, the outer diameter of the helix of course having to be adapted to this reduction, so that the helix 20 is everywhere at a short distance from the inner surface of the jacket 5 and therefore safely transport the granules of the goods can. Although in the illustrated embodiments, the axis 7 of the

If the device stands vertically, this is not absolutely necessary; the device can rather be used with any inclined axis of rotation 7.

Theoretically, the device according to the invention can also be operated with a still-looking lateral surface 5, albeit with reduced advantages mentioned at the beginning. Although the use of perforated or slotted metal sheets for the jacket 5 and the rotating body 4 is most expedient, these components can also be made from other air or liquid permeable materials.

Claims

Claims:

1.Device for drying wet bulk goods, preferably of plastic particles, in particular in granulate form, with a rotary body driven to rotate about its axis, at one end of which the material to be dried is passed through an inlet opening of a housing surrounding the rotary body into a between this rotary body and a the annular gap surrounding it is introduced, the introduced material being thrown by centrifugal force onto the inner surface of the perforated jacket, so that the liquid penetrates the perforation of the jacket and enters an annular space surrounding the jacket and enclosed by the housing, which has a drain opening for the liquid is provided, and wherein conveying elements arranged on the outer surface of the rotating body guide the gradually dried material to a collecting space arranged at the other end of the rotating body, from which it ver ver the housing through an outlet opening , characterized in that the rotary body (4) and the perforated jacket (5) each expand from the inlet opening (2) towards the collecting space (22) and the conveying members of at least one helix attached to the outer surface of the rotary body (4) (20) are formed, the outer edge of which is close to the perforated jacket (5).

2. Device according to claim 1, characterized in that the rotating body (4) and the perforated jacket (5) each have the shape of a truncated cone or cambered shape with a continuous course.

3. Device according to claim 1 or 2, characterized in that the perforated casing (5) is driven to rotate about its axis, in the same direction of rotation as the rotary body (4), but at a lower speed.

4. The device according to claim 3, characterized in that the speed of rotation of the rotary body (4) is 700 to 1200 revolutions / minute, that of the perforated

Jacket (5) 600 to 1100 revolutions / minute.

5. Device according to one of claims 1 to 4, characterized in that the radial width of the gap (6) existing between the rotary body (4) and the perforated jacket (5) is constant or decreases towards the collecting space (22), whereby the outer diameter of the helix (20) is adapted to this reduction.

6. Device according to one of claims 1 to 5, characterized in that the rotating body (4) and the perforated jacket (5) are each composed of at least two truncated cones with different opening angles.

7. Device according to one of claims 1 to 6, characterized in that the rotary body (4) is hollow and perforated and in its interior at least one blower (26), in particular around the axis (7) of the rotary body (4) rotating Paddle wheel (27) is arranged.

8. The device according to claim 7, characterized in that the housing (1) is provided with at least one air outlet opening (25).

9. Device according to one of claims 3 to 8, characterized in that the perforated jacket (5) is mounted only on its larger end (52), whereas its smaller end (51) is supported on the helix (20).

10. The device according to one of claims 1 to 9, characterized in that the helix (20) is designed with multiple threads and / or with a slope decreasing towards the larger end face (50) of the rotary body (4).

11. The device according to one of claims 1 to 10, characterized in that the rotary body (4) and the perforated casing (5) are driven by a common drive, but via different, optionally adjustable variable, gear.

12. Device according to one of claims 1 to 10, characterized in that the rotary body (4) and the perforated casing (5) are driven by different drives, at least one of the drives being designed as a vario drive.

13. Device according to one of claims 1 to 12, characterized in that the collecting space (22) is designed as a radial fan (16) with a spiral housing.

14. The apparatus according to claim 13, characterized in that the housing of the radial fan (16) has air inlet openings (30).

15. Device according to one of claims 1 to 14, characterized in that a filling funnel (3) is connected to the inlet opening (2).

16. Device according to one of claims 1 to 15, characterized in that a collecting channel (53) is provided for the centrifuged liquid at the larger end of the annular space (23).