CH716030A1 - Pipeline system for the pneumatic conveying of bulk goods. - Google Patents

Abstract

A pipeline system (1) for the pneumatic conveying of bulk material is described. The pipeline system (1) comprises a delivery line (4) and a secondary line (5), the secondary line (5) being connected to the delivery line (4) via openings (6) which are distributed over the length of the delivery line (4) stands. The delivery line (4) has a wear-resistant material over its entire inner surface. The secondary line (5) is arranged on the outside of the delivery line (4). The delivery line (4) and the secondary line (5) are enclosed by a casing pipe (7), and the space between the delivery line (4) and the casing pipe (7) and between the secondary line (5) and the casing pipe (7) is with filled with a filler material (2).

Description

Technical area

The invention relates to a pipeline system for the pneumatic conveying of bulk material.

State of the art

Pipelines for the pneumatic conveying of bulk material over long distances are known. In order to ensure continuous conveyance of the bulk material even over long distances and to prevent the formation of clogs, a sufficient minimum speed of the compressed air must be guaranteed, which can be improved via additional compressed air lines.

For example, CH 685697 describes a pipeline system which comprises at least one delivery line and one compressed air line, the compressed air line having a plurality of axially oriented and spaced apart openings via which the compressed air line is connected to the delivery line. The compressed air line is attached to the inner wall of the delivery line and includes a deflector plate to divert the compressed air and to clear the blockage.

DE 20211770 U1 describes a device for the pneumatic or hydraulic conveying of bulk material with a conveying line, an inner tube with openings, and with flow resistances in the inner tube in the area of the openings, the flow resistances serving to dissolve blockages.

These systems are made of steel, which do not have a satisfactory long service life of the line when transporting abrasive goods such as lignite, activated carbon, ash, ores, slag, cement, or sand. In order to make steel pipes more wear-resistant, they are clad with wear-resistant materials, as described in DE9320465U1, for example. However, the conveying means described here tend to clog because the compressed air lines necessary to avoid the formation of clogs are missing.

A disadvantage of the known systems is that they are either made of wear-prone steel, or that they tend to clog under certain conditions.

Object of the invention

The present invention is now the task of creating a pipeline system which increases the service life of the lines for abrasive bulk materials, which enables continuous conveyance of bulk material, prevents the accumulation of bulk material and clogging, and stable promotion with high loads guaranteed over long distances.

Description of the invention

This object is achieved by a pipeline system for the pneumatic conveying of bulk material with a conveying line and a secondary line, the secondary line being connected to the conveying line via openings which are distributed over the length of the conveying line. The delivery line has a wear-resistant material over the entire inner surface, and the secondary line is arranged on the outside of the delivery line. The delivery line and the secondary line are enclosed by a casing pipe, and the space between the delivery line and the casing pipe and between the secondary line and the casing pipe is filled with a filler material.

The invention has the advantage that the pipeline system through the delivery line, which has a wear-resistant material at least on the entire inner surface, has a high level of abrasion resistance and thus a high level of wear protection. This has the advantage that the service life of the pipeline system is increased and the pipelines according to the invention have to be replaced less quickly than conventional systems made of steel. Another advantage is that the secondary line on the outside of the delivery line prevents clogging within the delivery line and bulk material accumulations can be broken up by the conveying air passing through the openings into the secondary line and flowing through the secondary line if the delivery line is blocked. In addition, by arranging the secondary line on the outside of the conveying line, the conveying cross-section available for the bulk material is retained in the conveying line, in contrast to conventional systems in which the secondary line is attached to the inside of the conveying line, which reduces the conveying cross-section. The arrangement of the secondary line on the outside of the conveying line thus additionally leads to an improved continuous conveyance of bulk material. The pipeline system according to the invention is therefore particularly suitable for conveying abrasive bulk materials.

A pipeline system according to the invention is understood to mean a system of pipelines which is suitable for the pneumatic conveyance of bulk material, in particular of abrasive bulk material. The pipeline system is sometimes referred to as a dense phase pipe. The bulk material to be conveyed can, for example, be dusty, powdery or granular. Abrasive bulk materials are, for example, lignite, activated carbon, fly ash, sintered dust, bottom ash, boiler ash, filter ash, oxides of ferrous and non-ferrous metals, ores, abrasive materials used in the chemical industry, slag or sand.

[0011] Pneumatic conveying means the transport of bulk materials with gas such as air or an inert gas, preferably air, by means of positive or negative pressure. In the case of flammable or oxygen-sensitive bulk materials, an inert gas, preferably nitrogen, is used. The promotion takes place through pipes.

[0012] The entire inner surface of the delivery line preferably has a wear-resistant material. The entire inner surface is understood to mean that at least the inside of the delivery line is coated with a wear-resistant material. In a preferred embodiment, not only does the entire inner surface of the conveying line have a wear-resistant material, but the entire conveying line consists of a wear-resistant material.

Under wear-resistant material is understood a material which is resistant to mechanical abrasion by bulk material. Examples of wear-resistant materials are ceramics, hard metal, hard alloys, hard stoneware, corundum or fused basalt. The wear-resistant material is preferably ceramic. Ceramic has therefore proven to be particularly preferred because it has a higher wear resistance to abrasive bulk materials than other wear-resistant materials. This means that less material is required and thus the costs and weight are lower than with other wear-resistant materials.

Since the secondary line is also subject to a bulk material flow and thus abrasive material flows through the secondary line, the entire inner surface of the secondary line preferably also has a wear-resistant material. The entire secondary line preferably consists of a wear-resistant material, preferably ceramic.

Under ceramic a non-metallic material is understood, which is preferably made from the raw materials aluminum oxide, zirconium oxide or silicon carbide. In a preferred embodiment of the present invention, ceramic comprises alumina. Even more preferably, the delivery line or the delivery line and the secondary line consists essentially of aluminum oxide. Essentially means that the aluminum oxide ceramic can contain small amounts of additional materials in addition to aluminum oxide, but at least 90%, preferably at least 99%, consists of aluminum oxide. Aluminum oxide is particularly preferred because it has a particularly high wear resistance and therefore minimal wall or layer thicknesses are required for the desired wear resistance. This means that the costs and weight of the pipe systems can be kept as low as possible.

The jacket tube which encloses the delivery line and the secondary line is made, for example, of steel, aluminum, plastic or cardboard. The jacket tube is preferably made of steel.

To connect the delivery line and the secondary line to the casing pipe, the space between the delivery line and the casing pipe and between the secondary line and the casing pipe is filled with a filler material. The filling material absorbs impacts, bends and vibrations caused by the bulk material and thereby strengthens the conveying line. In addition, ceramic and steel are subject to different thermal expansions, which can be compensated for by a suitable filler material. In addition, the filling material holds the secondary line in position if the attachment between the secondary line and the delivery line should loosen during prolonged use of the delivery line.

Suitable filler materials include, for example, mortar, lightweight concrete, cement, rigid foam or plaster of paris. Mortar or cement is particularly preferred as the filler material, and Portland cement is particularly preferred.

The secondary line is arranged on the outside of the conveying line and preferably fastened to it, preferably by means of an adhesive. Epoxy resins or silicone-based resins, for example, can be used as adhesives. In a preferred embodiment, the secondary line is attached to the outside of the delivery line by means of an epoxy resin. Epoxy resin has proven to be particularly suitable when the delivery line and preferably also the secondary line consists of ceramic and ceramic is glued.

The delivery line is preferably a tube with a circular cross section and has several openings which are distributed over the length of the delivery line along a single longitudinal axis. The conveying line preferably has an internal diameter of 50 mm to 500 mm, preferably 50 mm to 200 mm, and an external diameter of 70 mm to 500 mm, preferably 70 mm to 250 mm. In a particularly preferred embodiment, the delivery line has an internal diameter of 80 mm and an external diameter of 110 mm.

The delivery line is preferably produced in molded parts, each molded part of the delivery line preferably having only one opening. The opening preferably has an elongated shape, for example an oval shape, preferably the shape of an elongated hole. The opening preferably has a length of 10 mm to 50 mm, preferably 20 mm to 40 mm, particularly preferably 30 mm, and a width of 2 mm to 30 mm, preferably 10 mm to 20 mm, particularly preferably 15 mm. The molded part, each with an opening, preferably has a length of 10 cm to 50 cm, preferably 20 cm to 40 cm, particularly preferably 25 cm to 30 cm. In order to produce a conveyor line of the desired length, several molded parts of the conveyor line are lined up until the desired length of the conveyor line is reached.

The secondary line is preferably designed as a tubular profile that is open in the longitudinal direction, for example as a half-tube. The open tubular profile preferably has a U-shaped, for example a semicircular, cross section. However, the secondary line can also have an angular cross section that is open on one side.

The pipe profile preferably has an open pipe segment with a cut-out angle of 100 ° to 180 °. The cut-out angle is particularly preferably 140 °. The cut-out angle of 140 ° has proven to be particularly preferred when the secondary line is glued to the delivery line. With a cut-out angle of 140 °, less adhesive is required than with other cut-out angles to glue the secondary line to the conveyor line. The less adhesive is required, the smaller the area of attack which can come into contact with the abrasive bulk material and thereby be removed.

In a preferred embodiment, the delivery line has a wall thickness of at least 10 mm, preferably at least 12 mm, and the secondary line has a wall thickness of at least 4 mm, preferably at least 6 mm. These wall thicknesses are particularly preferred for delivery lines made of ceramic and for secondary lines made of ceramic.

The secondary line is also preferably produced as a molded part. The secondary line is preferably arranged parallel to the delivery line on its outside along the openings, in such a way that the openings are enclosed by the secondary line and the secondary line forms a channel together with the outside of the delivery line. The pipeline system according to the invention preferably has a secondary line. However, designs with several secondary lines are also possible, which are arranged parallel to the delivery line on the outside of the delivery line. A molded part of the secondary line is preferably fastened to the outside of a molded part of the conveying line and the two molded parts have the same length. The secondary line preferably extends over the entire length of the conveying line.

In a preferred embodiment, the secondary line is attached over the entire length of the delivery line to the outside of the delivery line. This means that the secondary line and the conveying line are open to the sending container and the target container and the bulk material and the conveying air from the sending container are introduced into the conveying line and into the secondary line via pressure and conveyed into it until the bulk material and the conveying air are conveyed leaves the conveying line and the secondary line again in a target container.

When using the pipeline system according to the invention, the bulk material to be conveyed is introduced into the pipeline system from a container via compressed air. The main part of the bulk material flows into the conveying line. If the conveying of the bulk material to be conveyed is normal, the compressed air also mainly flows through the conveying line. If, however, the delivery in the delivery line stops due to an accumulation of bulk material or blockage, the compressed air escapes from the delivery line and reaches the secondary line via the openings. The compressed air leaves the secondary line via the openings in the direction of the delivery line, where bulk material can be removed for further delivery.

The pipeline system according to the invention is preferably produced in pipeline sections which are assembled into pipelines of desired lengths and shapes as required. The pipe sections preferably have a length of 1 to 6 meters, particularly preferably 2 to 3 meters. To produce the pipeline sections, individual molded parts of the secondary line are first attached to the desired location on the outside of individual molded parts of the delivery line. Several molded parts from the conveyor line and secondary line are lined up, fastened to one another, preferably with an epoxy resin, and inserted into a steel pipe. The space between the delivery line and the casing pipe and between the secondary line and the casing pipe is then filled with a filler material. The individual pipe sections have a connection piece, for example a flange, at the respective ends and are fastened to one another with fastening means, preferably with screws, and sealed with a seal between the flanges. The pipeline system according to the invention is preferably used at the points of a pipeline which are exposed to particular wear by the bulk material. This can be in the area of curves, for example.

Further advantages of the invention follow from the following description, in which the invention is explained in more detail with reference to an exemplary embodiment shown in the schematic drawings.

Brief description of the figures

[0030] They show: <tb> Fig. 1 <SEP> a molded part of a conveyor line in a perspective view. <tb> Fig. 2A <SEP> a molded part of a secondary line in a perspective illustration, <tb> Fig. 2B <SEP> shows a cross section through the secondary line from FIG. 2A, <tb> Fig. 3 <SEP> a cross section through a pipeline system according to the invention, <tb> Fig. 4 <SEP> a further cross section through a pipeline system according to the invention with a connecting piece, <tb> Fig. 5 <SEP> shows a longitudinal section through a pipeline system according to the invention from FIG. 4.

In the figures, the same reference numerals have been used for the same elements and initial explanations relate to all figures, unless expressly stated otherwise.

Embodiments of the invention

In Figure 1, a molded part 10 of a delivery line 4 is shown in a perspective view obliquely from above. The delivery line 4 has an opening 6 for each molded part 10. The opening 6 has the shape of an elongated hole. The molded part 10 preferably has a length of 250 mm. The entire inner surface 13 of the delivery line 4 is coated with a wear-resistant material, preferably ceramic. The entire conveying line is preferably made of a wear-resistant material, preferably ceramic, and preferably has a wall thickness of 12 mm.

FIG. 2A shows a perspective illustration of a molded part 11 of a secondary line 5 of the pipeline system 1 according to the invention (not shown here). The secondary line 5 has a tubular profile which is open in the longitudinal direction and has a U-shaped cross section. The inner surface 14 of the secondary line 5 is preferably coated with a wear-resistant material, preferably with ceramic. In a preferred embodiment, the entire secondary line 5 consists of a wear-resistant material, preferably ceramic.

FIG. 2B shows a cross section through the secondary line 5 shown in FIG. 2A. The U-shaped cross section has a cutout angle α of 140 °. To attach the secondary line 5 to the delivery line 4, the secondary line 5 is glued to the delivery line 4 by means of an epoxy resin (shown in FIG. 3).

FIG. 3 shows a cross section through a pipeline system 1 with a delivery line 4 with an opening 6, a secondary line 5 and a jacket pipe 7. The secondary line 5 encloses the opening 6 of the delivery line 4 and is attached to the delivery line 4 via an adhesive 3 so that the secondary line 5 forms a channel together with the delivery line 4. At least the inner surface 13 of the delivery line 4 and the inner surface 14 of the secondary line 5 comprise a wear-resistant material. The entire conveying line 4 and the entire secondary line 5 are preferably made of a wear-resistant material, preferably ceramic. The space between the delivery line 4 and the jacket pipe 7 and between the secondary line 5 and the jacket pipe 7 is completely filled with a filler material 2, preferably with mortar or cement, particularly preferably with Portland cement. The filling material 2 serves as a link between the delivery line 4 and the jacket pipe 7 and absorbs impacts, bends and vibrations which are exerted on the delivery line 4. In addition, the filling material 2 holds the secondary line 5 in position if the adhesive 3 should be worn out by the bulk material when the conveying line 4 and the secondary line 5 are subjected to heavy loads.

In Figure 4, a further cross section through a pipeline system 1 with a delivery line 4 with an opening 6, a secondary line 5, a casing pipe 7 and a filler 2 between the delivery line 4 and casing pipe 7 and between the branch line 5 and casing pipe 7 is shown, such as described in Figure 3. In addition, FIG. 4 shows a connecting piece 8 which can be attached to both ends of pipe sections (shown in FIG. 5) in order to connect individual pipe sections to one another, preferably with screws. In this way, pipes of any length can be made. The pipeline sections can have straight pieces but also bends, depending on the distance between a sending container and a target container. The connecting piece 8 is preferably a circular disc, preferably a flange, with a hole in the middle. The connecting piece 8 is preferably made of steel and is welded to the jacket pipe 7. In addition, the connecting piece 8 has a plurality of bores 9 in the outer region of the disk for receiving fastening means, preferably screws.

In Figure 5, a pipe section 12 is shown and shows a longitudinal section through the plane AA of the pipeline system 1 shown in Figure 4 with a delivery line 4 of several molded parts 10, each with an opening 6, with a secondary line 5, a jacket pipe 7 and a Filling material 2 between the delivery line 4 and the casing pipe 7 and between the secondary line 5 and the casing pipe 7. In addition, FIG. 5 shows the connecting pieces 8 for fastening several pipe sections 12 to one another. If two connecting pieces 8 are fastened to one another, a seal (not shown) is preferably placed between the two connecting pieces. The section B shows the length of a molded part of the delivery line 4 or the length of a molded part of the secondary line 5. Several molded parts of the delivery line 4 and the secondary line 5 of length B are lined up in a row in order to obtain the length of a pipe section 12.

List of reference symbols

1 pipeline system 2 filling material 3 adhesive 4 delivery line 5 secondary line 6 opening 7 jacket pipe 8 connecting piece 9 bore, screw hole 10 delivery line 11 secondary line 12 pipe section 13 inner surface of the delivery line 14 inner surface of the secondary line α cutout angle

Claims (12)

1. Pipeline system (1) for the pneumatic conveying of bulk material, with a conveying line (4) and a secondary line (5), the secondary line (5) via openings (6) which are distributed over the length of the conveying line (4) with the conveying line (4) is connected, characterized in that the conveying line (4) has a wear-resistant material on the entire inner surface (13), and that the secondary line (5) is arranged on the outside of the conveying line (4), wherein the conveying line (4) and the secondary line (5) are enclosed by a casing pipe (7), and the space between the conveying line (4) and the casing pipe (7) and between the secondary line (5) and the casing pipe (7) with a filling material (2) is filled. 2. Pipeline system (1) according to claim 1, characterized in that the filling material (2) is mortar or cement, preferably Portland cement. 3. Pipeline system (1) according to one of the preceding claims, characterized in that the conveying line (4) consists of wear-resistant material. 4. Pipeline system (1) according to one of the preceding claims, characterized in that the wear-resistant material is ceramic, preferably aluminum oxide. 5. Pipeline system (1) according to one of the preceding claims, characterized in that the secondary line (5) has a wear-resistant material on the entire inner surface. 6. Pipeline system (1) according to one of claims 1 to 4, characterized in that the secondary line (5) consists of wear-resistant material. 7. Pipeline system (1) according to one of claims 5 or 6, characterized in that the wear-resistant material is ceramic, preferably aluminum oxide. 8. Pipeline system (1) according to one of the preceding claims, characterized in that the jacket tube (7) is made of steel. 9. Pipeline system (1) according to one of the preceding claims, characterized in that the secondary line (5) is attached to the outside of the delivery line (4) by means of an adhesive (3), preferably an epoxy resin. 10. Pipeline system (1) according to one of the preceding claims, characterized in that the secondary line (5) extends over the entire length of the conveying line (4). 11. Pipeline system (1) according to one of the preceding claims, characterized in that the secondary line (5) is designed as a tubular profile that is open in the longitudinal direction. 12. Pipe system (1) according to claim 11, characterized in that the pipe profile has an open pipe segment with a cut-out angle (a) of 100 to 180 °, preferably 140 °.