WO2006015696A1 - Dust-free transfer chute - Google Patents

Abstract

The invention relates to a transfer chute for bulk goods, characterised in that the inlet chute (12) is divided into at least two chambers (20, 21) by means of at least one separating wall (18, 19) arranged in the flow direction of the bulk goods (11) in the inlet chute (12) and the discharge conveyor (15) is connected to the chambers (20, 21), the charge conveyor (10) charges into the charging chamber (20) of the inlet chute (12) nearest thereto in the transport direction and the separating wall (18) has the base point (24) thereof as determined by the layer height (25) of the bulk goods supplied by the charge conveyor (15) from the charging chamber (20), such that the discharge amount of the bulk goods from the charging chamber (20) is less than the amount of bulk goods introduced into the charging chamber (20) from the charge conveyor (10).

Description

 Low-dust transfer chute

Description

The invention relates to a transfer chute as a material transfer point for bulk materials. Such devices are used to transfer the material to be conveyed from one conveyor to another and are characterized by a closed as possible construction, which is intended to prevent deterioration of the environment by the subsidized Good or associated with the promotion of dust.

Devices and systems for conveying bulk materials must be designed in terms of mechanical engineering as well as bulk material technology. In particular, at material transfer points the promotion of bulk materials has an at least partially uncontrollable movement of the conveyed result. A decisive factor in this context is the relative movement of the particles. An increase of the relative movements and thus of the granular state of aggregation manifests itself in an increase in the granular temperature and a change in the bulk material properties. A solid-like, very slowly flowing bulk material changes to a liquid-like state as the shear gradient increases. With further increasing fluctuations of the individual Particle movements are more closely resembling the phenomenological properties of the bulk material than those of a gas.

Because of the low binding forces between the particles of a bulk material, however, the granular phase transitions in practice can be spontaneous and much easier than with atomic substances. Therefore, in particular in bulk material conveyors often several states of matter spatially close together. Primarily as a result of gas-like bulk material properties, dust may develop which, as part of the conveying process, leads to additional measures due to the disturbing effects on the environment associated with the formation of dust. Due to the speed, which is sometimes high as measured by the normal conveying speed, as a result of the uncontrolled movement of the bulk material, which is accelerated by the gravitational pull, the particle flow dilutes in regions, so that the geometry of the transfer chute permits. As a result, the proportion of fines embedded in the real case and thus bound is exposed and exposed to air resistance, so that a more or less pronounced wind vision effect is produced according to air and fall velocity. The particles hit due to the uncontrolled movement of large drop height at high speed on a resting in this direction bulk material bed, for example, in a task chute. The impact of the particles causes both abrasion and particle breakage.

In the foreground of the currently pursued approaches to minimize these effects is not the prevention of dust itself, but rather the elimination or withdrawal of the already formed dust. Consequently, extraction systems with some enormous benefits _zu_ _. _ install, jm .. di_e _^ entire. Material transfer. one. Exposing negative pressure and so effectively and controlled to withdraw the resulting dusts. Furthermore, collecting containers and optionally additional conveyor units are to be planned in order to feed the withdrawn amounts of dust back to the conveying process.

The invention is therefore based on the object to avoid the formation of dust in the area of a transfer chute to the largest possible extent to perform the downstream aggregates and systems for dedusting as low-power as possible.

The solution to this problem arises, including advantageous refinements and developments of the invention from the content of the claims, which are adjusted to this description.

The invention provides in its basic idea that the inlet chute is divided into at least two chambers by at least one in the flow direction of the bulk material in the inlet chute partition wall and the discharge conveyor is connected to the chambers, wherein the feed conveyor in him in the conveying direction nearest task chamber of the inlet chute gives up and the partition with its base adjusts the layer height of the discharged from the discharge conveyor from the feed bulk material determining distance such that the withdrawal amount of the bulk material from the feed chamber is lower than the discontinued by the feed conveyor in the feed chamber bulk.

The invention is thus based on the principle that run-in chute through which the conveyed material passes into the transfer chute to execute such that the Filling no longer - as prevailing in the art - vertically, but gradually horizontally. For this purpose, the uncontrolled movement of the particles is reduced to a minimum and at the same time the flow of material in the intake chute is calmed down, without influencing the overall material handling process. Linked to this filling strategy is a reduction of the drop height to a minimum. With this reduction, a minimization of the wind vision effect, the abrasion and the particle breaks can be achieved. To realize this, the transfer chute according to the invention has one or more partitions which divide the inlet chute in at least two or in any number of chambers. Background of the classification of the inlet chute and the positioning of the partition walls is the underlying material handling process. Thus, the individual partitions are to be designed with respect to their separating behavior so that always lying in the flow first chamber is filled. All other chambers fill up as a result of the overflow of the previous chamber depending on the upcoming flow rate. Consequently, the withdrawal of bulk material from the first chamber is to be selected smaller than the minimum occurring flow rate to keep them filled. The deduction is not determined by the horizontal position of the partition, but by the allowed by the arrangement of the partition layer height on the discharge conveyor. Of crucial importance is thus the formation of the partition in the area of the trigger; the chamber volume, however, has an impact on the relative velocities between bulk material and chamber wall. All other chambers provided can divide the remaining intake chute volume in any manner, for example, by constant chamber volume or by a steadily decreasing chamber volume. The exhaust side (lower) base of the partition protrudes less far into the maximum possible - flow in as the base of the opposite 'the Conveying direction previous partition. Thus, a new layer of the conveyed material stream formed in addition to the bulk material layers already formed by the base points of the bulk material layers opposite to the conveying direction is permitted by each lower base of a partition wall.

According to one embodiment of the invention, it is provided that in the conveying direction of the bulk material in the feed chamber of the respective bulk material own slope angle between the outer wall of the inlet chute and the upper edge of the partition can be adjusted.

It can be provided that in the feed chute a layer height of the from the task chamber downstream overflow chamber of the discharge conveyor absorbed bulk material limiting guide wall is arranged.

In an alternative embodiment of the invention it is provided that a plurality of partitions for dividing the inlet chute are arranged in a feed chamber and in several downstream overflow chambers in the inlet chute, the bases of the downstream partitions are arranged such that in each case a predetermined layer height of bulk material from the associated Overflow chamber is the Abzugsförderer superimposed. It can be provided that all other partitions allow a greater overall layer height on the discharge conveyor than all partition walls upstream in the conveying direction.

As far as feed conveyor and take-off conveyor are not arranged in a continuous conveying direction, according to an embodiment of the invention, it is provided that between that at an angle to Abzugsförderer arranged feed conveyor and the inlet chute a bulk material in the feed chamber of the inlet chute conductive saddle is arranged.

To ensure a trouble-free flow of material through the inlet chute, a geometry opening in the falling direction of the bulk material can be advantageous, in particular when using a plurality of partitions and thus resulting small chamber volume. This means that the housing walls and the partition walls form chambers whose outlet openings are larger than the inlet openings. With this geometry, the formation of bridge formations in the bulk material can be counteracted.

In alternative embodiments of the invention, the basic shape of the intake chute can be circular and / or curved edge or box-shaped.

To protect the walls or partitions against wear can be provided according to an embodiment of the invention that the acted upon in the conveying direction of the bulk material walls of the chambers and / or the partitions with the structure of acting as a regenerative wear protection bulk material profile profiles is occupied.

In the drawings, embodiments of the invention are shown, which are described below. Show it: Fig. 1 is a transfer chute with a single vertical division of the inlet chute with filled first chamber and the withdrawal of the bulk material in a schematic side view

2 shows a transfer chute with double vertical division of the inlet chute with filled first and second chambers and the withdrawal of the bulk material in a representation corresponding to Figure 1,

3 a transfer chute according to FIG. 1 with a feed conveyor arranged at an angle to the discharge conveyor, FIG.

4 shows a transfer chute according to FIG. 1 including a wear protection formed by bulk material regions.

As is first apparent from the schematic drawing representation of FIG. 1, promotes an only indicated, the bulk material feeding task conveyor 10 a bulk material 1 1 in an inlet chute 12, which forms the transfer chute together with the downstream task chute 13. The bulk material 11 falls through the inlet chute 12 onto a saddle 14, from which it is drawn off to the feed chute 13 by the relative speed of the discharge conveyor 15. The maximum bulk material flow 16 to be drawn off is limited by a guide wall 17. Within the chute 12, a partition 18 is installed, which divides the chute into two chambers, namely a first feed chamber 20 and a downstream overflow chamber 21. The positioning of the partition wall 18 is based on the bulk material properties and is chosen so that in the first task chamber 20 at least the angle of repose of the bulk material 1 1 can adjust. From this condition, the location of the upper edge 23 of the partition 18 is derived. The lower base 24 of the partition 18 determines the layer height 25 of the deducted bulk material 1 1, which is smaller than that through the guide wall 17 maximum permitted layer height 16. As a result of

Relative speeds between the bulk material 1 1 and the

Housing walls of the inlet chutes 12, it is particularly at the

Flow rate conductive boundary edge 23 and the base 24 of the

Partition 18 for wear. In order to reduce this, wear strips are used as wear protection on the upper boundary edge 23 and on the lower base point 24 of the partition wall 18.

FIG. 2 illustrates another embodiment of the invention which does not differ in material flow from the embodiment shown in FIG. 1 but has two partitions 18 and 19. Consequently, the inlet chute 12 is divided into the feed chamber 20 and two downstream overflow chambers 21 and 22. The feed chamber 20 is filled directly from the fed via the feed conveyor 10 bulk flow. As a result of the limited by the lower base 24 of the partition 18 layer height 25, which is selected in terms of throughput so that the peelable Fördergutstrom is smaller than the minimum on the conveyor 10 supplied bulk amount, the level in the feed chamber 20 increases until it filled is. The now supplied bulk material 1 1 runs in the overflow chamber 21 and fills it, as long as the supplied mass flow is greater than the limited by the base 24 deducted summed flow from the chambers 20 and 21. After filling the first overflow chamber 21, the bulk material is now running in the second overflow chamber 22 and falls directly on the bulk material. This overflow chamber 22 is not filled because the maximum removable bulk material volume is always greater than the supplied. In Fig. 3, a variant is shown, which also allows lateral filling of the inlet chute 12, if the feed conveyor 10 is arranged deviating from the conveying direction at an angle to the discharge conveyor 15. Deviating from the illustrations in FIGS. 1 and 2, for this purpose, an additional saddle 26 is used to divert the bulk material flow directly into the feed chamber 20, which is created by the dividing wall 18 dividing the intake chute 12. The further material flow takes place as described for Fig. 1 such that after filling the feed chamber 20, the excess bulk material falls over the overflow of the upper boundary edge 23 into the chamber 21 and deducted from this directly through the already existing bulk bed 25 from chamber 20 and is abandoned on the conveyor 15. To protect against wear, the upper boundary edge 23 and the saddle 26 may be provided with a wear protection, which also allows a bedding on the saddle 26.

Fig. 4 illustrates a further embodiment of the transfer chute with angle profiles 27 on all walls of the chambers. On the angle profiles 27, which are fixed in a defined and mathematically determinable distance from each other, collects with increasing degree of filling of the chambers 20, 21, the bulk material and thus forms a natural, regenerating wear protection 28th

Claims

P a n t a n s p r e c h e Transfer chute for bulk materials for transferring a bulk material from a conveyor to a downstream conveyor, wherein the transfer chute consists of a connected to a feed conveyor and the flow connection to a discharge conveyor producing inlet chute and from an adjoining and the adjoining the inlet chute area of the discharge conveyor Aufhauseschurre characterized in that the inlet chute (12) by at least one in the flow direction of the bulk material (1 1) in the Einlauf¬ chute (12) aligned partition (18, 19) divided into at least two chambers (20, 21) and the discharge conveyor ( 15) to the chambers (20, 21) is connected, wherein the feed conveyor (10) in the conveying direction closest to the task chamber (20) of the inlet chute (12) gives up and the partition (18) with its base (24) a layer height (25) of the discharge conveyor (15) from the Aufgabek Ammer (20) abgegeförderten bulk material defining distance sets such that the withdrawal amount of the bulk material from the feed chamber (20) is less than the feed conveyor (10) in the Aufzubbekammer (20) abandoned ^" Scliüttgütmehge. 2. transfer chute according to claim 1, characterized in that the partition wall (18) in the conveying direction of the bulk material (1 1) in the inlet chute (12) is arranged such that in the conveying direction of the bulk material in the feed chamber (20) of the respective Bulk material (1 1) can set its own angle of repose between the outer wall of the inlet chute (12) and the upper edge of the partition wall (18). 3. transfer chute according to claim 1 or 2, characterized in that in the Aufgabeschurre (13) a layer height of the from the task chamber (20) downstream overflow chamber (21) of the discharge conveyor (15) recorded bulk material limiting guide wall (17) is arranged , 4. transfer chute according to one of claims 1 to 3, characterized in that in the inlet chute (12) a plurality of partitions (18, 19) for dividing the inlet chute (12) in a feed chamber (20) and in a plurality of downstream overflow chambers (21, 22 ), wherein the foot points (17) of the downstream partitions (19) are arranged such that in each case a predetermined layer height of bulk material from the associated overflow chamber (21, 22) is deposited on the discharge conveyor (15). 5. transfer chute according to claim 4, characterized in that all other partitions (19) allow a greater total layer height on the discharge conveyor (15) than all upstream in the conveying direction partitions. 6. transfer chute according to one of claims 1 to 5, characterized in that between the at an angle to the discharge conveyor (15) arranged feed conveyor (10) and the inlet chute (12) a the bulk material (11) in the feed chamber (20) of the inlet chute ( 12) conductive saddle (26) is arranged. 7. transfer chute according to one of claims 1 to 6, characterized in that the shape of each individual chamber (20, 21, 22) has an opening in the direction of the bulk material training. 8. transfer chute according to one of claims 1 to 7, characterized in that the basic shape of the inlet chute (12) is circular and / or formed with curved boundary edges. 9. transfer chute according to one of claims 1 to 7, characterized in that the basic shape of the inlet chute (12) is box-shaped. 10. transfer chute according to one of claims 1 to 9, characterized in that in the conveying direction of the bulk material acted upon walls of the chambers (20, 21, 22) and / or the partitions (18, 19) with the structure of as a regenerating wear protection acting bulk material causing profile parts (27) is occupied.