EP0818249A1 - Classifying rotor for pneumatic separator - Google Patents

Abstract

The wheel channels in its circumference. The sifter air loaded with fine material passes through from out to inside and is expelled in the axial direction. The channels (12) are in axially different radial planes and at different angles ( alpha ) relative to the radial direction of the wheel. The channels are formed by bores in the jacket surface of the wheel and are defined by mainly axially directed blades (9,9'). The wheel consists of at least two sections and the channels in one section are directed at different angles from those in the other section.

Description

The invention relates to a classifying wheel for a wind classifier has channels on its circumference through which the classifying wheel from the visible air loaded with fine material from outside to inside is flowed through, and in which the fine air loaded with fine material is discharged from the classifying wheel in the axial direction.

Sifters have the task of being carried in the visible air Separate visible material into fine and coarse material, which, e.g. in EP-A1 552 837 described, can be done in that a Classification wheel of an air classifier approximately radially from the outside inwards is flowed through, after which the fine air laden with fine material in axial direction is discharged from the classifying wheel. Through the Rotation of the classifying wheel and the resulting centrifugal forces in the channels or in the area of the outer mouths of the Channels, the coarse material is thrown outwards and cannot with the visible air and the fine material are discharged to the inside.

The problem arises that due to the higher flow rates or the higher pressure difference in The area of the axial outflow end of the classifying wheel is more coarse Visible material is subtracted from the middle or from the outflow end distant area of the sight wheel, so that the separation or classification of the visible goods in coarse and fine goods often not as accurate as desired.

It should be noted that at the axial ends of the classifying wheel Due to the edge flow, much larger particles are entrained than is the case in the middle of the sight wheel. in the This is why it also works together with the classifier housing Reverse flows, which result in a blurred sighting cause. If you compare the practical results with the theoretical calculations according to Stokes, so it's easy to recognize that in practice the largest particles around in the fines are many times larger than under ideal conditions, whereby science has proven in itself that the Particle sedimentation according to Stokes.

In order to solve this problem, it was proposed in EP-A1 552 837 to arrange a distribution pipe within the classifying wheel, in which a plurality of openings is provided, wherein the size of the openings from the axial outflow end of the classifying wheel away increases more and more. Through the smaller openings near the The flow resistance at the outflow end is higher than in the outflow end distant area, so that a more constant Course of the flow velocity or the acting Negative pressure within the classifying wheel via the axial Length of the same is reached.

However, with the solution proposed in EP-A1 552 837 the disadvantage connected that the power requirement of the classifier through the openings in the distributor pipe that act as chokes is increased, which is particularly the case at high flow velocities adversely affects. On the other hand, they should larger particles as soon as they enter the channels on the circumference of the sight wheel are rejected, which is not the case with this solution.

The invention is therefore based on the object of a classifying wheel the genus mentioned at the beginning, with which one as possible over the axial length of the classifying wheel constant separation behavior can be achieved.

This task is solved with a generic classifying wheel in that the channels in axially different radial Levels different angles to the radial direction of the sight wheel exhibit.

Due to the different angular inclination of the channels in axial different radial planes on the outer circumference Rejection of the visible air particle flow over the axial length of the sight wheel influenced to different degrees.

The rejection on the rotor outer radius does not only affect the Visible air, but also very effectively on the particles. Around that corresponds to the spatially very different flow behavior To take into account or in those areas along the rotor, where especially large particles pass through, To prevent this from happening, it is beneficial to reject it in axially different radial planes through channels with different Angles to the radial direction of the sight wheel to influence differently.

The invention thus takes advantage of the fact that the Inflow of the fine air laden visual air to the outer mouth of the channels from the inclination of the channels to the radial direction the sight wheel is influenced. Therefore, the channels in axially different radial planes in different Angles aligned with the radial direction of the classifying wheel, then those mentioned above can be more even Separation properties can be achieved through the classifying wheel without that there are additional facilities, such as a manifold According to EP-A1 552 837, what throttle losses or cause high pressure drops.

In particular in a preferred embodiment of the invention, which is characterized in that the channels from the inside are inclined outward against the direction of rotation, is according to the invention suggested that the angle of inclination of the channels at Outflow end of the classifying wheel is greater than the angle of inclination the channels distant from the outflow end. With this embodiment can achieve very good visual behavior of the classifier because the mentioned repellency does not only apply to the sight air affects, but also on those to be sighted Particle.

Further preferred embodiments of the invention are the subject of the other subclaims.

Fig. 1 schematisch einen Windsichter mit drei Abschnitten im Längsschnitt,

Fig. 2 eine Ansicht auf den Windsichter von Fig. 1 von links,

Fig. 3 eine teilweise Ansicht eines erfindungsgemäßen Sichtrades mit fünf Abschnitten im Schnitt.

Fig. 4 eine Achsansicht einer ersten Ausführungsform eines Sichtradabschnittes,

Fig. 5 eine Achsansicht einer zweiten Ausführungsform eines Sichtradabschnittes und

Fig. 6 einen Schnitt durch einen Teil des Sichtradabschnittes von Fig. 5 entlang der Linie VI-VI.

Preferred embodiments of the invention are described below with reference to the drawings. It shows:

1 schematically shows an air classifier with three sections in longitudinal section,

2 is a view of the air classifier of FIG. 1 from the left,

Fig. 3 is a partial view of a classifying wheel according to the invention with five sections in section.

4 shows an axial view of a first embodiment of a classifying wheel section,

Fig. 5 is an axial view of a second embodiment of a classifying wheel section and

Fig. 6 shows a section through part of the classifying wheel section of Fig. 5 along the line VI-VI.

In Fig. 1 is a wind sifter schematically with an inventive Classification wheel 20 is shown schematically, the Classifying wheel 20 in a housing 21 with an inlet 23 for classifying air with exposed material and an outlet 22 for coarse material is. The classifying air is removed with a classifying material axial outlet 24.

It is understood that instead of that shown in FIGS. 1 and 2 and described housing 21 also other forms of Housings can be used and that the visual air and Visible material is also fed separately into the housing 21 can be.

In Fig. 3 an inventive sight wheel 20 is in section partially shown, which consists of five classifying wheel sections 1, 2 and 3 is built. The classifying wheel 20 becomes classifying air with classifying material fed in the direction of arrows 5 and loaded with fines Visual air is at the outflow end 13 in the direction of arrow 4 discharged through the outlet 24 from the classifying wheel.

In a first embodiment, shown in FIG. 4 in an axial view the classifying wheel sections 1 and 2 consist of one Carrier 6, which is connected to a hub 8 via five spokes 7 is. A plurality of wheel blades 9, 9 'is on the carrier 6 arranged, which is in the axial direction of the classifying wheel section 1, 1 'extend. The wheel blades 9, 9 'can be radial Direction of the classifying wheel section 1, 1 'angled, like is shown using the wheel blades 9, or be curved.

In their simplest form, the wheel blades can also be designed as flat rotor bars, as is shown in the Wheel blades 9 'is shown in Fig. 4. In its outer In the area, the wheel blades 9, 9 'have an angle of inclination α to the radial. The angle of inclination α in the outer area determines the visual behavior more than the angle of inclination in the inner region of the channels 12 in the wheel blades 9.

The wheel blades 9, 9 'are at an angle α to the radial inclined that they run from the inside to the outside Direction of rotation 10 of the sight wheel 20 are inclined. Through this Inclination, coarser particles of the material to be viewed are made more difficult, the classifying wheel 20 in the direction of arrow 5 from the outside to flow inwards so that a good classification of the Visible goods are possible.

After passage of the fine air through the between the blades 12, 9 'formed channels 12 from the outside the fine air loaded with fine material becomes 90 ° inwards deflected and flows in the axial direction of the classifier, such as is indicated by the arrows 11 in Fig. 3.

The classifying wheel section 3 in FIG. 3 differs in that 4 of the sight wheel sections 1, 2 i.a. in that the carrier 6 does not have spokes with the Hub 8 is connected, but via a continuous disc 14, as can be seen in FIG. 3. This is necessary because the Classifying wheel section 3 at the outflow end 13 of the classifying wheel End is arranged and thus the conclusion of the classifying wheel.

The angle of inclination α of the sight wheel sections 1, 2 and 3 is at the sight wheel sections 2 and 3 larger than the sight wheel sections 1. Due to the larger angle of inclination of the wheel blades 9, 9 'or the channels 12 formed between them the rejection for the visible air particle flow increased so that here the passage of larger particles is prevented and thus an improved separation behavior of the entire rotor precise separation is achieved.

It is noted that the classifying wheel section shown in FIG. 4 not exactly with the classifying wheel sections shown in FIG. 3 coincides, since it is in the in Fig. 4th illustrated wheel section around an integral part is, in which the blades 9, 9 'formed on the carrier 6 are, whereas it is with the classifying wheel sections shown in FIG. 3 are those in which between support disks 16, 16 ', 16 ", blades 9, 9' held positively are, as can be seen in FIGS. 5 and 6 in detail.

The middle support disks 16 point to both of them End faces 25 circumferential grooves 26 in which the Blades 9, 9 'are added with their ends 27. To the To fix blades 9, 9 'in position on the support disks 16, spacers 28 are provided, which are a total have an annular shape and in the groove 26 on both sides the support disk 16 are inserted. To accommodate the ends 27 of the blades 9, 9 'have the spacers 28 radially (around the Inclination angle α inclined to the radial) open to the outside Slits in which the blades 9, 9 'lie.

Have a training similar to the middle support disks 16 the edge-side support disks 16 ', 16 ", but here only on the one facing the inside of the sight wheel 20 End face a groove 26 is provided for receiving the blades 9, 9 ' is.

The construction of the classifying wheel 20 from support disks just described 16, 16 ', 16 ", between which the blades 9, 9' are held positively without penetrating them the advantage that the sight wheel 20 is very stable overall is constructed because the support disks 16 through their continuous annular cross section have a high load-bearing capacity. It is understood that this structure of a classifying wheel Carrying disks and blades held in a positive manner between them can also be used with classifying wheels, where the channels between the blades over the entire length of the classifying wheel have substantially the same orientation.

As can also be seen in FIGS. 1 and 3, the classifying wheel sections are 1, 2 and 3 placed on a shaft 15 in a rotationally fixed manner, over which the sight wheel sections 1, 2 and 3 with a Drive, not shown, are driven.

The angle of inclination of those formed between the wheel blades 9, 9 ' Channels 12 is preferably between 30 ° and 45 °, can, however, depending on the respective conditions, such as the particle size or the specific weight of the particles the material to be viewed or the desired fraction ratio between Coarse and fine goods, also above or below, for example between 15 ° and 60 °.

In alternative embodiments not shown in the drawings it is also possible that instead of between paddles 9, 9 'formed channels 12 openings, e.g. Bores are provided or that the classifying wheel is not out individual sections in which the channels are included, but that channels with different angles of inclination in different radial planes in one one-piece sight wheel or in a single sight wheel section are arranged.

In another, also not shown in the drawings Embodiment can the fine air loaded with fine material also at both axial ends of the classifying wheel via outflow channels dissipated to the performance of the invention Classifier.

In summary, an embodiment can be described as follows will:

A classifying wheel 20 for a wind classifier has on its circumference Channels 12 through which the classifying wheel 20 of the fine material laden visual air is flowed through from the outside to the inside. Then the fine air loaded with fine material becomes axial Direction removed from the sight wheel 20. The channels 12 point different in axially different radial planes Angle α to the radial direction of the sight wheel 20, the angle of inclination α of the channels 12 near the outflow end 13 of the classifying wheel is greater than the angle of inclination .alpha Outflow 13 distant channels 12.

The fact that the inflow of the fine air laden visual air on the outer mouth of the channels 12 from the inclination of the channels 12 to the radial direction of the sight wheel 20 is influenced through the channels 12 which are in axially different radial Planes at different angles α to the radial Direction of the sight wheel 20 are aligned, more uniform Separation properties achieved.

Claims (15)

Classifying wheel for a wind sifter that channels on its circumference has, through which the classifying wheel of the fine laden visual air is flowed through from the outside to the inside and in which the fine air loaded with fine material is in axial Direction is removed from the classifying wheel, characterized in that that the channels (12) in axially different radial planes different angles (α) to the radial Have direction of the sight wheel. Classifying wheel according to claim 1, characterized in that the Channels (12) through openings, in particular bores, are formed in the outer surface of the classifying wheel. Classifying wheel according to claim 1 or 2, characterized in that that the channels (12) by substantially axially aligned Wheel blades (9, 9 ') are limited. Classifying wheel according to one of Claims 1 to 3, characterized in that that the classifier wheel consists of at least two classifier wheel sections (1, 2, 3) and that the channels (12) one Classification wheel section (1, 2, 3) at a different angle (α) are aligned to the radial direction than the channels (12) of the other classifying wheel sections (1, 2, 3). Classifying wheel according to one of claims 1 to 4, characterized in that that the angle of inclination (α) of the channels (12) changes to the radial direction from outside to inside. Classifying wheel according to claim 3 and 5, characterized in that the wheel blades (9, 9 ') have a curved course to have. Classifying wheel according to one of claims 1 to 6, characterized in that that the channels (12) from the inside to the outside the direction of rotation (10) are inclined. Classifying wheel according to one of claims 1 to 7, characterized in that the angle of inclination of the channels (12) approximately between 15 ° and 60 °, in particular between 30 ° and 45 ° to the radial direction. Classifying wheel according to one of Claims 1 to 8, characterized in that that the angle of inclination (α) of the channels (12) is close the outflow end (13) of the classifying wheel is larger than that Angle of inclination (α) from the outflow end (13) Channels (12). Classifying wheel according to one of claims 1 to 9, characterized in that that two outflow channels are provided which Connect opposite sides axially to the classifying wheel and through which the fine air loaded with fine material is dissipated. Classifying wheel according to one of Claims 3 to 10, characterized in that that the classifying wheel sections (1, 2) from one ring-shaped carrier (6, 6 ') exist on which the classifying wheel blades (9, 9 ') projecting in the axial direction are molded. Classifying wheel according to one of Claims 3 to 10, characterized in that that radially extending support washers (16, 16 ', 16 ") are provided, between which the wheel blades (9, 9 ') are held in a form-fitting manner. Classifying wheel according to claim 12, characterized in that the The blades (16, 16 ', 16 ") do not have wheel blades (9, 9') penetrate. Classifying wheel according to claim 12 or 13, characterized in that that in the area of the outer edges of the support disks (16, 16 ', 16 ") on the end faces (25) recesses (26) are in which the wheel blades (9, 9 ') with their ends (27) are added. Classifying wheel according to claim 14, characterized in that the Recesses (26) are annular grooves and that the wheel blades (9,9 ') by spacers (28) in their position in the annular grooves (26) are fixed.

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