DE3628380C1 - Apparatus for uniformly dividing a vertically flowing dust-gas mixture - Google Patents

Abstract

In an apparatus for uniformly dividing a vertically flowing dust-gas mixture, in particular a coal dust-air mixture, from an inflow channel into at least two branch channels by means of fittings, which are provided in the junction region, for an at least two-stage dividing device, the fittings comprising partitions which subdivide the inflow channel into a plurality of sub-channels of equal flow cross-section and guide devices, which are arranged between the partitions and, as a result of their regularly alternating arrangement, cause the sub-channels corresponding to one another to open into the branch channels provided, it is provided according to the invention that a device (16) for making the dust concentration in the dust-gas mixture uniform is arranged in every branch channel (2; 3) directly after the fittings (11) in at least one flow cross-section plane (18). Furthermore, a method for using the apparatus in accordance with the invention is provided. <IMAGE>

Description

The invention relates to a device for uniform Distribution of a vertically flowing dust-gas mixture, especially a coal dust-air mixture, from one Inflow channel in at least two branch channels by means of Branch area of intended internals for at least one two-stage distribution device, the internals from Partitions that divide the inflow channel into several subchannels divide and flow out the same flow cross-section guidance devices arranged between the partitions consist of the regularly changing arrangement corresponding sub-channels in the intended Allow branch ducts to open.

When transporting dust-gas mixtures, in particular of coal dust-air mixtures in a pipe or duct it comes about due to various influencing factors The flow cross-section is known to be uneven local dust distribution, for example up to 30% and more deviate from an even distribution can.

To compensate for the influence of gravity, is from the DE-PS 8 79 973 a method for attaching at any time of pegs in already installed, mostly horizontal known to weakly inclined delivery pipes, in which the pipes be provided with slits, from the outside to the inside vortex inserts protruding into the pipes to prevent segregation of bulk goods and pumped media.  The influences of centrifugal forces, such as, for example occurring in pipe elbows are also caused by Built-in prevented. So according to DE-PS 3 87 935 in a pipeline for pneumatic bulk material conveying in, possibly in front of or behind pipe elbows, fixed guide body or ribs arranged to counteract opposing forces all non-axial speed components of the conveying air exercise and so dampen this.

In order to achieve a flow with the lowest possible friction and Flow resistance due to vortex formation in a curved Leading pipeline is known from DE-GM 18 26 017 in a pipe bend by installing curved baffles Provide channels through which the flow of material to be conveyed into individual Partial streams is divided so that the material flow only within the pipe bend has the opportunity to join the Slightly thin the inner wall of each channel.

Even when dividing a mixture flow into several partial flows occur due to various influences in the partial flows different dust distributions.

From US-PS 15 51 643 a device is known with which approximately the dust distribution in separate mixture streams is equal to. This is achieved in that one in one Inflow channel flowing dust gas mixture flow through partitions into a large number of subchannels arranged side by side same flow cross-section that flows due to guidance devices located between the partitions alternately and regularly repeating in each branch duct flow out. As a guide device according to US-PS 15 51 643 an inclined flat sheet is provided.

In a device known from DE-PS 16 32 421 the partitions also from a flow direction acute-angled, isosceles triangular surface, on the Thighs alternately on one side and the other a control device is connected. Each of these guidance systems again consists of an upstream direction pointing acute-angled triangular surface, on the legs alternately inclined in one direction and the other obtuse-angled  Triangular surfaces are connected, the longest side of each connected to the leg of the triangular surface for the partition is.

In the device known from DE-GM 19 46 290 there is Guide device made of two inclined, roof-shaped Parallelogram surfaces whose common edge is in Flow direction is inclined.

Due to the mostly construction-related, not optimal training of the subchannels in the area of the control equipment form in the mixture flow during the Distribute along differently curved Current paths caused by the forces that occur Current filaments with greatly increased dust concentration, i.e. H. Streaks of dust. With purely theoretical Consideration three arise in each sub-channel Streaks of dust, two in the area of the two partitions and one in the closer area of the guidance device, of which the Partition strands at the outlet of the internals with the corresponding partition strands of adjacent sub-channels flow together while passing through the guide created dust streak essentially in Dependence on the inflow conditions then with the stabilizing partition strands too a bundle of dust, as it were, united.

The disadvantage here is that in multi-stage dust-gas mixture distributors there is a risk that in the Distribution device of a subsequent stage as a result of constructively justifiable number and width of subchannels streaks of dust formed in this way only in one subchannel can flow in, and so the dust content in the Mixing part flows changed to different values becomes. So studies on distributors have a Coal dust-air mixture in at least two stages evenly on several leading to coal dust burners Should divide supply lines, confirms that individual coal dust burner in this way  various coal dust-air mixtures were fed, which means that each burner has a different one Combustion process with different results took place.

The invention is therefore based on the object Device for evenly distributing a dust-gas mixture to improve so that in the sub-channels Streaks of dust formed in the outflowing mixture partial flow largely no longer available.

This problem is solved in that in each Branch duct following the internals in at least a flow cross-sectional plane a device for Comparing the dust concentration in the dust-gas mixture is arranged.

Due to the immediacy of the arrangement of internals and an equalization device in a device a distribution stage with rectangular, polygonal or round flow cross-section becomes a consistent separation between distributing and equalizing aimed at, each led through a sub-channel Mixture partial flow only then the equalization is subjected when the dust transport is no longer takes place along curved current paths, and which by the Distribution process caused dust streak formation is completed. The one brought about with this arrangement Merging of those in the subchannels Provides partial flows to a single mixture partial flow sure that one in the inflow channels of the devices following distribution stage the dust concentration in the Partial mixture flow over the flow cross section again is largely without streaks of dust before it again is shared.

As a leveling device, for example  any flow control elements in the manner of Displacers or in a shape with rotationally symmetrical, symmetrical or otherwise Profile are used, the one in arrangement and shape rectangular, polygonal or round in the branch area Flow cross section are adapted and a (net) lattice-like or lamellar, in one or in several cross-sectional planes rectified or take intersecting arrangement to get through in an optimal way a deliberate, continuous delay in the Branch channels guided mixture flow a resolution of the in the area of partitions and guidance systems to create streaks of dust.

In order to resolve the dust streak by relative alone to bring about simple means, it is useful if the equalization device out in one Flow cross-sectional plane arranged like a grid Flow control elements exist.

The arrangement of the flow guide elements can be preferably improve if these are among the Guides of the internals in the same direction are aligned.

It is also expedient if the flow guide elements in Arrangement and number of each of the subchannels adapted to the Built-in components are integrated, the flow guide elements in continuation of the partitions into the branch channels Partitions extending into the flow direction tapering cross-sectional profile in which two are facing each other symmetrical, curved profile boundary lines end in a point, are shaped, and each one Flow guiding element on the side facing away from the flow a guide device is positioned.  

Through the structural integration of distribution installations with the equalization device can be Simplify manufacturing in an advantageous manner and unify. In addition, by mutual Adaptation to a definable homogeneous flow state achieved for the dust gas mixture stream, where by choice a certain curvature on the cross-sectional profile of the A specific flow control element Flow state of the mixture partial flow in the wall area of the Flow guide element is brought about between Wall application and wall detachment of a current filament lies.

The invention is also directed to a method for even distribution of a dust-gas mixture flow, especially a coal dust-air mixture flow several mixture flows in at least two stages in one Contraption. This is the inventive method characterized in that at least those from the first stage escaping mixture streams immediately after the Distribute and after reaching a constant Flow state by delaying the mixture partial flow regarding their across the flow cross section distributed dust concentration.

The invention is explained in more detail below with reference to the attached figures using a preferred exemplary embodiment. It shows:

Fig. 1 shows an arrangement of a two-stage distribution device

Fig. 2 shows a cross section through a distributing a stage having a rectangular flow cross-section along section line II-II in Fig. 3 or 4,

Fig. 3 shows a cross section of the device shown in Fig. 2 along the section line III-III in Fig. 2 and 4 and

Fig. 4 shows a cross section of the device shown in Figs. 2 and 3 along the section line IV-IV in Fig. 2 and 3 respectively.

According to Fig. 1, a coal dust-air mixture flow is divided into four mixture partial flows for the supply of, for example, four coal dust burners, not shown, in such a way that the mixture flow conducted in a rectangular inflow duct ( 1 ) is firstly divided into two rectangular branch ducts ( 2, 3 ) by means of a device ( 4 ) and then in a second stage by means of two further devices ( 5, 6 ) to a total of four branch channels ( 2 ', 2 ", 3 ', 3 ").

The device ( 4 ) ( FIGS. 2 to 4) of the first stage consists of an outlet part ( 7 ) of the inflow channel ( 1 ) which, without a substantial change in cross-sectional area, continuously enters two adjacent inlet parts ( 8, 9 ) of the two branch channels ( 2, 3 ) transforms.

Immediately in front of a channel division ( 10 ) separating the inlet parts ( 8, 9 ) there are internals ( 11 ) in the outlet part ( 7 ). These internals ( 11 ) consist of partitions ( 12 ), which are arranged perpendicularly to the channel division ( 10 ) or parallel to the broad side of the wall of the outlet part ( 7 ) and which separate the outlet part ( 7 ) into a plurality of adjacent part channels ( 13, 14 ) divided the same flow cross-section. In each of the subchannels ( 13, 14 ) there is a guide device ( 15 ) connecting the partitions ( 12 ) and arranged at an acute angle with respect to the direction of flow, which divides the channel division ( 10 ) with one of the two channel walls of the outlet part ( 7 ) connects. In the simplest case, the guide device ( 15 ) is a straight wall web arranged perpendicular to the partition walls ( 12 ) delimiting the sub-channel in question. In somewhat complex implementation cases, the guide device ( 15 ) is a wall element with wall parts that are bent from rectangular or triangular surfaces.

The position of the guide devices ( 15 ) changes in a regular sequence from subchannel ( 13 ) to subchannel ( 14 ) and causes the subchannels ( 13 ) into the inlet part ( 8 ) of the branch duct ( 2 ) and the subchannels ( 14 ) into the inlet part ( 9 ) of the branch duct ( 3 ) open. Means ( 16 ) for equalizing the coal dust concentration in the dust-air mixture flow are immediately downstream of the internals ( 11 ). They are located in the two inlet parts ( 8, 9 ) of the associated branch ducts ( 2, 3 ) and consist of flow guide elements ( 17 ) arranged at certain distances from one another, parallel to the broad side of the two branch ducts ( 2, 3 ).

In each case a flow guide element ( 17 ) is designed so that the parallel partition walls ( 12 ) continue as partition walls ( 12 ', 12 ") up to an imaginary cross-sectional plane ( 18 ) of the flow channel at the rear inflow end of the guide device ( 15 ) or at the beginning of Channel division ( 10 ) initially in parallel and from the level ( 18 ) with a continuous transition in adaptation to the required flow conditions in the inlet parts ( 8, 9 ) of the branch channels ( 2, 3 ) are continued. In this area, two partitions ( 12 '; 12 ") are brought together on the side of a guide device ( 15 ) facing away from the flow, preferably in a convex or increasing curvature, to form a straight cutting edge ( 19 ) directed perpendicularly to the channel division ( 10 ) . The curvature and thus the expansion of the flow cross section present between the flow guide elements ( 19 ) begins when, after the distribution, ie after the passage through the subchannels ( 13; 14 ), there is a constant flow state and no more dust streaks are formed. The curvature of the flow guide element ( 17 ) of the equalization device ( 16 ) can have an elliptical course or can be composed of circular arc sections with a variable radius or of other geometric lines of curvature. Decisive for the curvature is the formation of the mixture flow in a sub-channel ( 13; 14 ) widening in cross-section between two flow guide elements ( 17 ) and in the subsequent, installation-free area of the branch channels ( 2, 3 ), the flow in the wall area of the flow guide element ( 17 ). ideally should be in a state between wall application and wall detachment. As a result, existing dust concentration differences in the outflow are compensated for or streaks of dust formed, without a renewed formation of streaks of dust due to concentration or due to detachment flow vortices on the flow guide elements. The degree of homogenization depends on the type of facility chosen ( 16 ). The shape of the flow guiding element ( 17 ) described here preferably influences dust streaks formed along the longitudinal side of the inflow or branch duct.

The mixture partial flows flowing out in the branch ducts ( 2, 3 ) now reach the devices ( 5, 6 ) of the second stage in an approximately uniform manner. The structure of these devices ( 5, 6 ) corresponds to that of the device ( 4 ), the surface area of the inlet cross section essentially corresponding to the outlet cross section of the branch duct ( 2, 3 ). In order to avoid a further increase in the local dust concentration in the mixture partial flow due to an incomplete homogenization in the device ( 4 ) of the first stage, the number and flow cross section of the partial channels located in the devices ( 5, 6 ) have been changed so that the principle of a uniform dust Gas mixture distribution is maintained.

Claims (5)

1.Device for uniformly distributing a vertically flowing dust-gas mixture, in particular a coal dust-air mixture, from an inflow duct into at least two branch ducts by means of internals provided in the branch region for an at least two-stage distribution device, the internals consisting of partitions which form the inflow duct Subdivide into several subchannels of the same flow cross-section and consist of guide devices arranged between the partition walls, which by means of regularly changing arrangement allow the corresponding subchannels to open into the intended branch ducts, characterized in that in each branch duct ( 2; 3 ) following the internals ( 11 ) in at least one flow cross-sectional plane ( 18 ) a device ( 16 ) for comparing the dust concentration in the dust-gas mixture is arranged. 2. Apparatus according to claim 1, characterized in that the equalization device ( 16 ) consists of flow-guiding elements ( 17 ) arranged in a grid-like manner in the flow cross-sectional plane ( 18 ). 3. Apparatus according to claim 2, characterized in that the flow guide elements ( 17 ) to the guide devices ( 15 ) of the internals ( 11 ) are aligned in the same direction. 4. Apparatus according to claim 2 or 3, characterized in that the flow guide elements ( 17 ) in arrangement and number of those of the sub-channels ( 13; 14 ) are adapted and integrated into the internals ( 11 ), the flow guide elements ( 17 ) in continuation of Partition walls ( 12 ) made of partition walls ( 12 '; 12 ″) extending into the branch ducts ( 2, 3 ) with a cross-sectional profile tapering in the direction of flow, in which two symmetrical, curved profile boundary lines ( 12 '; 12 ″) in a tip ( 19th ) end, are shaped, and one flow guide element ( 17 ) is positioned on the side of a guide device ( 15 ) facing away from the flow. 5. Process for the uniform distribution of a dust-gas mixture flow, especially a coal dust-air mixture flow, to several mixture flows in at least two stages, in particular in a device according to one of the claims 1 to 4, characterized in that at least the partial mixture streams emerging from the first stage immediately after distributing and after reaching one constant flow state by delaying the Mixture flow in terms of their over the flow cross section distributed dust concentration.