WO2008128530A1 - System and method for binding dust - Google Patents

Abstract

The invention relates to a system for binding dust, especially during the conveyance of bulk goods. Said system comprises at least one housing (5) in which an electrode (6) is arranged to generate an electrical field between the electrode (6) and the housing (5). The aim of the invention is to improve or increase the quality and variety of possible uses of bulk goods. To achieve this aim, at least one diverter element is used to divert particles from a dust/air mixture from the housing (5) and to separate them from the bulk goods.

Description

 System and method for dust binding

The present invention relates to a system for binding dust, in particular when conveying bulk material, with at least one housing in which an electrode is arranged in order to generate an electric field between the electrode and the housing. The invention further relates to a method for

Dust binding, in particular in the case of bulk material conveying, in which an electrode arranged in a housing forms an electric field between the electric field

Electrode and the housing generates and charge-carrying particles of a located in the housing dust-air mixture on an inner wall of the

Housing be deposited.

When conveying or transporting bulk material, dust often forms, in particular if the bulk material is transferred from a transport device, for example to another transport and / or storage device. The dust development is enhanced if the bulk material overcomes a certain drop height during transfer. The individual particles of the dust produced during the transfer have only a very small particle size, so that the particles can float over a longer period of time in the environment. This forms a dust-air mixture that exerts a harmful effect not only on the production process, but also on the environment, personnel and / or the environment. Finally, the material loss of the bulk material occurring due to the dust development is not insignificant.

In order to bind the dust, several possibilities are known, for example, the dust-air mixture can be passed through suitable filter means with a plurality of small openings, in which the dust particles in attach the filter devices to the boundaries of the openings. The degree of purity of the dedusted or filtered exhaust air in this case depends on a fineness of the filter devices, the size and number of openings, the thickness of the filter cake and the dust particle size.

Since the particles of dust are deposited in the filter devices during this filtering, the individual openings continue to increase over time until the filter device finally becomes clogged. Due to the changing opening size, the filter properties are also not constant. Furthermore, the stuffed with the dust particles or clogged filter devices must be cleaned regularly or replaced by fresh, unused filter devices. The exchanged and replaced filter devices are then either to dispose of, the amount of dust particles are lost to the material flow of the bulk material, or they need to be elaborately reconditioned to re-supply the dust particles the material flow or as a separated material with a certain particle size other uses available to deliver.

After flowing through the filter housing, the dedusted dust-air mixture exits the dust binding system as exhaust air, which still contains a residual amount of dust. Although much of the particulate matter has been filtered out, the incompletely cleaned exhaust air continues to exert a deleterious effect on the environment, personnel and / or the environment.

In order to bind the dust at its place of origin and then directly return it to the material flow, dust binding systems based on the application of the electrostatic principle have been developed. Here is the resulting dust-air mixture within a housing which is located above the transferred bulk material and in which the dust-air mixture rises. In the grounded housing, an electrode is arranged, which can be connected to a corresponding high voltage. Due to the generated electric field between the Electrode and the housing particles of the mixture are ionized and charge carrying.

These particles will now move toward the grounded housing due to the charge in the electric field. For example, they deposit on the grounded inner wall of the housing and form agglomerates there. Due to the increasing agglomerate size and / or by a suitable mechanical shaking movement of the housing, the particles are detached again from the inner wall of the housing, where they have agglomerated, and they fall back into the bulk material as agglomerates. In the bulk material bodies or particles of different sizes are generally mixed together. Here, the proportion of particles of a certain size has a clear effect on the quality and versatility of the transported bulk material.

A division of the particles depending on their size is possible for example by means of known air classifier. In this case, falling bulk material is blown from the side with air of a defined flow rate. Depending on the particle size or the particle mass, the individual particles are deflected to different degrees from the flowing air, so that in each case collecting particles of certain orders of magnitude accumulate in several collecting containers, which are arranged one behind the other in the flow direction. In the exhaust air are the smallest particles, for example, in the order of a few microns, but still present.

Against this background, it is the object of the present invention to improve or increase the quality and versatility of a bulk material.

This object is achieved by a system having the features according to claim 1 and by a method having the features according to claim 9. In a system for dust binding of the type described above, the invention provides that at least one discharge element is provided to direct particles from a dust-air mixture out of the housing and to separate from the bulk material.

The essence of the invention is that a part of the particles of the rising dust-air mixture is filtered out and taken from the material flow. The proportion of particles of this particular particle size is then reduced in the remaining bulk material and the filtered-out dust particles are available for other use. Furthermore, since dust separation and dust binding are carried out, no harmful exhaust air is produced.

At least one vibrator device is preferably provided on an outer side of the housing in order mechanically to release the dust which has been deposited on an inner wall of the housing and which adheres electrostatically by means of a vibrating movement. Particularly preferably, the vibrator is an unbalance motor, which requires only a relatively low power consumption.

An advantageous embodiment of the system according to the invention provides that the housing can be arranged above a section of a conveyor belt and the housing has an opening towards the conveyor belt. With a suitable opening size is ensured by this arrangement that the resulting dust almost completely rises in the housing and only a small part escapes into the environment as harmful and the environment polluting exhaust air.

In an advantageous manner, in each case one discharge element is provided on two opposite side edges of the opening in the longitudinal direction of the housing. Preferably, the discharge element is a discharge plate extending in the longitudinal direction of the housing, which has a first longitudinal edge pointing into the interior of the housing and a second longitudinal edge protruding from the housing. Due to the planar design as a sheet a structurally simple construction of the dust binding system is possible.

In order to utilize the gravitational force, it is provided according to the invention that the deflecting plate is arranged below the side edge of the opening and with an inclination oriented downwardly outward from the interior of the housing.

In order to be able to supply the dust material which has been led out and separated via the deflecting plate to a suitable collecting device, an additional side conveyor belt is preferably provided below the second longitudinal edge of the deflecting plate, which conveys the dust particles falling off the deflecting plate.

In the following, the present invention is explained in more detail by way of example with reference to the detailed description of an embodiment with reference to the attached figures, in which:

1 shows a longitudinal section through an inventive system for

Dust binding shows, and

FIG. 2 shows a corresponding cross section through the dust binding system according to the invention from FIG.

Figure 1 shows an embodiment of a system according to the invention for dust binding, which is used in conjunction with a transfer of bulk material from a first conveyor belt 1 to a second conveyor belt 2. The conveyor belts 1 and 2 used are formed in a known manner. Here, the bulk material (not shown) from the first conveyor belt 1 falls through a transfer chute 3 on the second conveyor belt 2. The conveying direction of the second conveyor belt 2 is indicated in the figure by the arrow 4. About the following in the conveying direction after the transfer chute 3 section of the second conveyor belt 2, the dust binding system according to the invention is arranged.

The dust-binding system has a housing 5, in which a dust-air mixture rises, which arises during the transfer and the falling of the bulk material. In the grounded housing 5, an electrode 6 is arranged, which has a plurality of spaced electrode plates 7. The electrode is fastened to the housing 5 by means of a holder 8. The holder 8 may optionally be provided with an insulating layer. The electrode 6 is connected to a suitable high voltage supply 9, which is controlled via a central control device 10.

The housing 5 extends in the longitudinal direction along the conveying direction. On the outside of the housing 5, an unbalance motor 11 is mounted, which has a mechanical shaking movement of the housing 5 causes. It is sufficient if the unbalance motor 11 is only turned on periodically for a defined time. The switching on and off of the unbalanced motor 11 can also be controlled by means of the central control device 10.

Slightly deeper than the second conveyor belt 2 is another, slightly smaller dimensioned side conveyor 12 to recognize, on the separated dust particles 13 a collecting device 14, for example, a suitable container, are supplied. The side conveyor 12 can move permanently for particle transport. Alternatively it can be provided that at standstill of the side conveyor belt 12 first separated dust particles

13 are collected and at defined intervals the side conveyor belt 12 starts to supply the accumulated material of the collecting device 14. Alternatively, the dust particles 13 may also be pneumatic, with a screw conveyor or the like of the collecting device

14 are supplied.

Figure 2 shows a cross-sectional view along the line A-A of Figure 1, which in turn shows a longitudinal sectional view along the line B-B of Figure 2. In FIG. 2, a conveyor belt surface of the second conveyor belt 2 formed by three in each case known manner in a side-by-side manner and with a certain angle to one another is shown with the bulk material 16 thereon.

Above the second conveyor belt 2, the housing 5 and the electrode 6 with the star-shaped electrode plates 7 can be seen. The housing 5 has at the bottom of an opening, below which the second conveyor belt 2 runs along with the bulk material 16 thereon.

The rising dust-air mixture with dust particles 17, which are indicated in this illustration by means of the dots, is ionized by a high voltage applied to the electrode 6 and the charge-carrying Dust particles 17 are attracted to the inner wall 18 of the grounded housing 5. As soon as the dust particles 17 deposited there form an agglomerate of a certain size, the agglomerates fall down due to gravity. The agglomerates can already be previously supported by a mechanical shaking movement of the housing 5 due to the unbalance motor 11 (see Figure 1) detach from the inner wall 18 and fall down.

The circumference of the inner wall 18 of the housing 5 can be divided into two side sections 20 and a middle section 21 by means of the illustrated auxiliary line 19. In these three sections 20, 21, each section occupies approximately one third of the area of the inner wall 18. The falling dust agglomerates of the central region 21 fall back onto the second conveyor belt 2 and the bulk material 16 located thereon.

However, the dust agglomerates falling down the two side sections 20 of the inner wall 18 each fall on a deflector plate 22. This has a first longitudinal edge 23 facing the interior of the housing 5 and a second longitudinal edge 24 projecting outwardly from the housing 5. The deflecting plate 22 is arranged in principle between the side edge of the opening of the housing 5 and the second conveyor belt 2 and aligned substantially parallel to the side edge in the longitudinal direction of the housing 5.

The deflector 22 is further inclined in the transverse direction of the housing 5 downwards such that the first longitudinal edge 23 is arranged higher than the second longitudinal edge 24. Thereby, the dust particles 13 of the slope along the deflector 22 can be conveyed out of the housing interior to the outside. In order to support the discharge of the dust particles 13, a further unbalance motor 25 is arranged on the deflector 22, in order to ensure that the dust particles 13 do not adhere electrostatically to the deflector 22.

Subsequently, the dust particles 13 fall on the two side conveyor belts 12, the side next to the second conveyor belt 2, parallel to this and something are arranged lower. The conveying direction of the side conveyor belts 12 may be equal to the conveying direction of the bulk material 16 (arrow 4 in Figure 1) or provided opposite thereto. Also, the two side conveyor belts 12 can run either in the same direction or opposite to each other. The separated dust particles 13 are conveyed by the conveyor belts 12 to corresponding collection devices 14, for example a suitable container.

Finally, FIG. 2 shows support systems 26 and 27 for both the second conveyor belt 2 and the dust binding system according to the invention. The support system 26 has a frame 28 which carries the arrangement of the support rollers 15. The frame 28 is held by a plurality of supports 29 from a bottom surface (not shown) spaced. The second conveyor belt 2 can be oriented both substantially horizontally and with a corresponding angle of inclination to the horizontal plane. The housing 5 is held by support arms 30, which are spaced from the bottom surface via corresponding support posts 31, so that the housing 5 is arranged above the second conveyor belt 2.

According to the invention, in the dust binding system and the corresponding method presented here, the dust binding to avoid environmentally harmful, hazardous and / or polluting exhaust air and the separation of material bodies of a certain particle size, in particular of the order of the diameter of about 10 to 100 microns from the material flow at the same time instead of.

Claims

claims A system for binding dust, in particular when conveying bulk material, comprising a housing (5) in which an electrode (6) is arranged to provide an electric field between the electrode (6) and the Produce housing (5), characterized in that at least one discharge element is provided to lead particles from a dust-air mixture from the housing (5) and to separate from the bulk material. 2. System according to claim 1, characterized in that at least one vibrating device is provided on an outer side of the housing (5). 3. System according to claim 2, characterized in that the vibrating device is an unbalance motor (11). 4. System according to any one of the preceding claims, characterized in that the housing (5) above a portion of a conveyor belt (2) can be arranged and the housing (5) to the conveyor belt (2) towards a Opening has. 5. System according to any one of the preceding claims, characterized in that on two opposite side edges of the opening in the longitudinal direction of the housing (5) each have a discharge element is provided. 6. System according to any one of the preceding claims, characterized in that the discharge element is a in the longitudinal direction of the housing (5) extending deflector (22) having a first in the interior of the housing facing the longitudinal edge (23) and a second of the housing outstanding longitudinal edge (24). 7. System according to claim 6, characterized in that the deflector (22) is arranged below the side edge of the opening and with a downwardly directed from the interior of the housing downwards inclination. 8. System according to claim 7, characterized in that below the second longitudinal edge of the Ableitblechs (22) an additional side conveyor belt (12) is provided. 9. A method for dust binding, in particular in a promotion of bulk material, in which in a housing (5) arranged electrode (6) generates an electric field between the electrode (6) and the housing (5) and charge-carrying particles in the Housing (5) located dust-air mixture on an inner wall (18) of the Housing (5) are deposited, characterized in that the deposited particles are partially led out by at least one discharge element from the housing (5) and separated from the bulk material.