EP3892834A1 - Exhaust line for a large industrial installation and system with such an exhaust line - Google Patents

Abstract

The invention relates to an exhaust line (20) and a system (10) with such an exhaust line (20), the exhaust line (20) having a filter device (120), a first line section (35), a second line section (40) and a damper section ( 45), the filter device (120) being designed to at least partially filter the exhaust gas (25), the first strand section (35) being fluidically coupled to the filter device (120) at a first end (75) and extending along a first main direction of extent, wherein at a second end (80) of the first strand section (35) facing away from the first end (75) the first strand section (35) is mechanically and fluidically connected to the second strand section (40) and the damper section (45), wherein the damper section (45) extends along the first main direction of extent away from the first strand section (35) and inside a predefined damper volume (110) which can be filled with exhaust gas (25) tig, wherein the damper section (45) is designed to at least partially reflect a pressure fluctuation spreading from the filter device (120) in the direction of the second end (80) in the exhaust gas (25) back into the first strand section (35), the second strand section (40) extends laterally away from the first strand section (35) and is designed to remove or supply the exhaust gas (25) from the first strand section (35).

Description

An exhaust gas line for a large-scale industrial plant is known, the exhaust gas line being designed to discharge an exhaust gas from the large-scale industrial plant. The exhaust line can have a filter device and a fan, wherein the exhaust gas can ignite and deflagrate in the filter device. Pressure waves generated by the deflagration can damage the fan.

It is the object of the invention to provide an improved exhaust line and an improved system with such an exhaust line.

This object is achieved by means of an exhaust line according to claim 1 and a system according to claim 13. Advantageous embodiments are specified in the dependent claims.

It was recognized that an improved exhaust gas line for removing an exhaust gas from a large industrial plant, in particular a metallurgical plant, can be provided in that for removing an exhaust gas from a large industrial plant, in particular a metallurgical plant, the exhaust gas line has a filter device, a first line section, a having a second strand section and a damper section. The filter device is designed to at least partially filter the exhaust gas. The first strand section is fluidically coupled to the filter device at a first end and extends along a first main direction of extent, with the first strand section being mechanically and fluidically connected to the second strand section and the damper section at a second end of the first strand section facing away from the first end. Of the The damper section extends along the first main direction of extent away from the first string section and delimits a predefined damper volume that can be filled with exhaust gas on the inside, the damper section being designed as a pressure fluctuation spreading from the filter device in the direction of the second end in the exhaust gas, at least partially back into the first string section to reflect, wherein the second strand section extends laterally away from the first strand section and is designed to discharge or feed the exhaust gas from the first strand section.

This embodiment has the advantage that the pressure fluctuation in the exhaust gas only partially enters the second branch section due to the damper section. In particular, a pressure-sensitive component which is located in connection with the second strand section can thereby be protected from mechanical damage as a result of the pressure fluctuation.

In a further embodiment, the damper section has a pipe area and a cover area which is inclined to the first main direction of extent, the pipe area extending along the first main direction of extent. On a first side, the tube area is connected to the first strand section, and on a second side opposite the first side in the first main direction of extent, the tube area is mechanically connected to the cover area. On the inside, the cover area and the tube area limit the damper volume. In this case, the cover area can be closed with the tube area in an essentially fluid-tight manner. The cover area is designed to reflect the pressure fluctuation back from the pipe area into the first strand section. For example, a damper structure can be arranged on the cover area, which additionally scatters or dampens the pressure fluctuation upon reflection.

In a further embodiment, the first strand section extends upstream to the second end in a straight line along a first straight line. The tube area is aligned with the first strand section and extends along the first straight line. This configuration has the advantage that the aligned arrangement of the pipe area and the first strand section as well as the arrangement along the first straight line avoids a deflection of the pressure fluctuation in the direction of the second strand section. In this way, an unwanted entry of a larger proportion of the pressure fluctuation into the second strand section is avoided.

In a further embodiment, the strand section has a first cross-sectional area. The tube region has a second cross-sectional area, the first cross-sectional area and the second cross-sectional area being essentially identical. This configuration has the advantage that the first strand section and the tube area can be produced from the same molded parts, for example tubes with a large diameter. Additionally or alternatively, the pipe area and the first strand section have an identical inner contour. This avoids projections, steps or webs at a transition between the pipe region and the first strand section, so that the transition between the first strand section and the pipe region is essentially stepless. The stepless design prevents partial reflection of the pressure fluctuation at the transition.

In a further embodiment, the tube region has a maximum first internal extension perpendicular to the first main extension direction. The maximum first internal extension can be, for example, 1 m to 6 m. The tube area has a maximum length along the first main direction of extent. A ratio of the maximum length to the maximum first internal extension has a value which is in a range from 0.5 to 1.5 inclusive, the ratio preferably being 1.

In a further embodiment, the second strand section preferably extends along a second straight line. As a result, the second strand section can be manufactured from straight pipe material in a particularly cost-effective manner.

The second strand section extends along a second main direction of extent at an angle inclined to the first main direction of extent. The angle is 70 ° to 110 °, in particular 87 ° to 93 °, particularly advantageously 90 °. In particular, the right-angled arrangement makes it more difficult for the pressure fluctuation to enter the second strand section. It is particularly advantageous, for example, if the second strand section and the first strand section butt against one another. An arcuate transition between the first strand section and the second strand section is also possible.

In a further embodiment, a damper device is arranged on a second strand section. The damper device has at least one first reflector plate. The plate-shaped reflector plate extends inclined, for example 45 ° to 135 °, preferably perpendicular, to a second main direction of extent of the second strand section over a first partial area of a second cross-sectional area of the second strand section. The reflector plate is designed to reflect a first part of the pressure fluctuation back on the end face in a direction towards the first strand section, so that the pressure fluctuation only arrives in a weakened form on the downstream side of the second strand section.

In a further embodiment, the damper device has at least one second reflector plate, the second reflector plate being plate-shaped and inclined, preferably perpendicular, to the second main direction of extent. The second reflector plate is arranged offset in the second main direction of extent to the first reflector plate. In the transverse direction, the second reflector plate is arranged opposite the first reflector plate. The second reflector plate extends in the transverse direction over a second partial area of the second cross-sectional area of the second strand section. If the pressure fluctuation hits a second end face of the second reflector plate, the second reflector plate is designed to reflect it back into the first strand section at the second end face, so that the pressure fluctuation arrives only strongly attenuated in the second strand section downstream of the second reflector plate.

In a further embodiment, the damper device has at least two first reflector plates, the two first reflector plates being arranged offset in the second main direction of extent of the second strand section. The second reflector plate is arranged in the second main direction of extent between the two reflector plates. This configuration has the advantage that a second part of the pressure fluctuation, which passes the first reflector plate laterally without any reflections on the first reflector plate, is reflected back in the direction of the first strand section by the second reflector plate. Likewise, a third part of the pressure fluctuation, which has passed the first of the two first reflector plates and the first and second reflector plates without being reflected, is caused by the further first reflector plate, which is arranged downstream of the first and second reflector plates of the two first reflector plates is reflected back towards the first strand section on the front side. As a result, an amplitude of the pressure fluctuation and thus an intensity of the pressure fluctuation decreases as the length of the damper device increases. As a result, the pressure-sensitive component, for example a fan, can be arranged on the downstream side of the damper device, protected from the pressure fluctuation.

In a further embodiment, the first reflector plate extends with the first partial area over 20 to 50% of the second inner cross-sectional area.

In a preferred embodiment, the exhaust line has a pressure wave-sensitive component and an inlet side, the inlet side being connectable to the industrial plant and the exhaust gas being able to be introduced into the exhaust line via the inlet side, the filter device being upstream of the first line section between the inlet side and the first line section is arranged, wherein the pressure wave-sensitive component is connected downstream of the second strand section and is fluidically connected to the second strand section.

In a further embodiment, the exhaust gas line has a pressure wave-sensitive component, an outlet side and an inlet side, the inlet side being connectable to the industrial plant and the exhaust gas being able to be introduced into the exhaust gas line via the inlet side, the cleaned exhaust gas being able to be discharged via the outlet side, whereby the filter device is arranged downstream of the first strand section between the outlet side and the first strand section, wherein the pressure wave-sensitive component is connected upstream of the second strand section and is fluidically connected to the second strand section.

The pressure-sensitive component can have at least one fan and / or a pressure relief flap and / or a switchover station. The fan can be designed, for example, as an axial fan or a radial fan. The blower can also be designed as a fan or compressor and, depending on the arrangement, used as an induced draft or booster blower.

A system has a large-scale industrial plant, in particular a metallurgical plant, and an exhaust gas line. Of the The exhaust line is designed as described above. The large-scale industrial system is designed to generate an exhaust gas, the inlet side of the exhaust gas line being fluidically coupled to the large-scale industrial system and designed to at least partially discharge the exhaust gas from the large-scale industrial system.

FIG 1

eine schematische Darstellung eines Systems gemäß einer ersten Ausführungsform;

FIG 2

ein Diagramm eines Drucks eines Abgases des Systems aufgetragen über einer Zeit im ersten Strangabschnitt eines Abgasstrangs des Systems;

FIG 3

eine schematische Darstellung eines Systems gemäß einer zweiten Ausführungsform;

FIG 4

eine schematische Darstellung eines Systems gemäß einer dritten Ausführungsform; und

FIG 5

eine schematische Darstellung eines Systems gemäß einer vierten Ausführungsform.

The invention is explained in more detail below with reference to FIGN. Show:

FIG 1

a schematic representation of a system according to a first embodiment;

FIG 2

a diagram of a pressure of an exhaust gas of the system plotted against a time in the first branch section of an exhaust branch of the system;

FIG 3

a schematic representation of a system according to a second embodiment;

FIG 4

a schematic representation of a system according to a third embodiment; and

FIG 5

a schematic representation of a system according to a fourth embodiment.

In the following FIGN, reference is made to a coordinate system for easier understanding. The coordinate system is designed, for example, as a right system and has an x-axis (longitudinal direction), a y-axis (height direction) and a z-axis (transverse direction).

FIG 1 shows a schematic representation of a system 10 according to a first embodiment.

The system 10 has a large-scale industrial plant 15 and an exhaust line 20. The large-scale industrial plant 15 can, for example, as a metallurgical plant, in particular as Foundry plant or plant for the production of metals. For this purpose, for example, the large-scale industrial installation 15 can have a converter which is designed, for example, as an LD converter (Linz-Donawitz converter). Another embodiment of the large-scale industrial plant 15 is also conceivable.

In the metallurgical sector, d. H. In steel, aluminum and non-ferrous metal production, large amounts of exhaust gas 25 occur due to the process, e.g. B. in the smelting of pig iron or directly reduced sponge iron or in the production of crude steel. The exhaust gas 25 can comprise particulate material and at least partially comprise a combustible gas.

The exhaust gas line 20 is designed to at least receive the exhaust gas 25 from the large-scale industrial plant 15, preferably to at least partially clean it and to divert it for further processing or for the discharge of the exhaust gas 25.

The exhaust gas 25 can for example have at least one of the following gases and / or particulate material: carbon monoxide, carbon dioxide, oxygen, hydrogen, carbon particles, iron oxide particles, lime particles, water vapor, water droplets.

The exhaust line 20 has an inlet side 30, a first line section 35, a second line section 40, a first damper section 45, a filter device 120 and an outlet side 50. In addition, the exhaust line 20 can also have a pressure-sensitive component 55. The pressure-sensitive component 55 can for example have a fan 185 and / or a pressure relief flap and / or sensors and / or a switchover station. Another embodiment of the pressure-sensitive component 55 would also be conceivable.

The first strand section 35 extends along a first straight line 60 in a first main direction of extent. The first straight line 60 runs, for example, parallel to the x-axis. The first strand section 35 has a first wall 65 on. On the inside, the first wall 65 delimits a first interior space 70 in which the exhaust gas 25 flows along the first main direction of extent of the first branch section 35 when the exhaust gas line 20 is in operation. The first wall 65 preferably has an essentially constant first inner cross-sectional area along the first main direction of extent over the first strand section 35.

The first strand section 35 is fluidically coupled to the inlet side 30 at a first end 75. The filter device 120 can be arranged between the inlet side 30 and the first end 75 of the first strand section 35. The filter device 120 can be designed, for example, as a wet filter, in particular a wet electrostatic precipitator, and / or a dry filter, in particular a dry electrostatic precipitator.

A second end 80 of the first strand section 35 is mechanically connected to the first damper section 45 and to the second strand section 40. The second strand section 40 adjoins the first strand section 35 laterally.

The second strand section 40 extends in a second main direction of extent along a second straight line 85. The first straight line 60 encloses a predefined first angle α with the second straight line 85. The predefined first angle α can be, for example, 70 ° to 110 °, preferably 87 ° to 93 °. It is particularly advantageous if the second straight line 85 runs essentially perpendicular to the first straight line 60 and is thus aligned parallel to the y-axis.

The second strand section 40 has a second wall 90, the second wall 90 delimiting a second interior space 95 on the inside. The second interior space 95 has a second inner cross-sectional area. The first inner cross-sectional area of the first interior space 70 is preferably formed identically to the second inner cross-sectional area of the second interior space 95.

The first damper section 45 has a first tube area 100 and a first cover area 105. The first tube region 100 extends in a straight line along the first straight line 60. The first pipe region 100 is aligned with the first strand section 35.

The first wall 65 has a first profile in a cross section in the yz plane, the first profile being, for example, circular, elliptical or rectangular, in particular square. The first tube region 100 has a second profile in cross section, the second profile preferably being identical to the first profile. Over its extension along the first straight line 60, the first tube region 100 has essentially the same second profile as the first strand section 35. A second inner cross-sectional area of the tube region 100 can also be identical to the first inner cross-sectional area.

The first tube region 100 directly adjoins the second end 80 of the first strand section 35 and is mechanically and preferably essentially fluid-tightly connected to the first strand section 35. The first tube region 100 is mechanically connected on a first side to the second end 80 of the first strand section 35, in particular to the first wall 65. In particular, the first strand section 35 and the first tube region 100 can be designed in one piece and of the same material.

The first cover area 105 is fastened to the first tube area 100 on a second side of the pipe area 100 opposite the first side and thus the second end 80. The first cover area 105 runs essentially inclined, in particular perpendicular, to the first straight line 60 and to the first main direction of extent of the first strand section 35. The first cover area 105 closes the first tube area 100, preferably fluid-tight, on the side facing away from the second end 80.

The first cover area 105, together with the first pipe area 100, delimits a first damper volume 110 on the inside, the first damper volume 110 being filled with exhaust gas 25 when the industrial plant 15 is in operation. The damper volume 110 extends as far as the second end 80 of the first strand section 35.

The first tube region 100 has a maximum first internal extension b ₁ in a direction perpendicular to the first straight line 60. The maximum first internal extension b ₁ is 1 m to 5 m. In the case of a tubular configuration with a circular second profile, the first maximum internal extension b ₁ corresponds to a maximum internal diameter of the tube region 100.

In a longitudinal direction along the first straight line 60, the first tube region 100 has a maximum first length l ₁ . The maximum first length l ₁ is defined between the second end 80 or the first side of the tube region 100 and the first cover region 105. It is particularly advantageous if a ratio of the maximum first length l ₁ to the maximum first internal extension b _{1 has} a value which is in a range from 0.5 to 1.5, inclusive.

The second wall 90 has a third profile in a cross section in an xz plane, the third profile being selected to be, for example, identical to the first profile. The third profile can also be different from the first profile and / or the second profile. In this case it is also advantageous if the first inner cross-sectional area is identical to a third inner cross-sectional area of the second strand section 40.

On a side of the second strand section 40 facing away from the first strand section 35, the second strand section 40 can be fluidically connected to the outlet side 50. Included For example, the pressure-sensitive component 55, for example the fan 185, can be arranged between the outlet side 50 and the second strand section 40.

When the large-scale industrial installation 15 is in operation, the fan 185 is activated and generates a negative pressure. The fan 185 sucks the exhaust gas 25 from the large-scale industrial plant 15 into the exhaust line 20 via the inlet side 30.

The exhaust gas 25 flows from the inlet side 30 into the filter device 120. The filter device 120 filters the exhaust gas 25. For example, the filter device 120 can remove the particulate matter and / or certain harmful gases, e.g. B. carbon monoxide, filter from the exhaust gas 25 / remove.

After flowing through the filter device 120, the filtered exhaust gas 25 enters the first branch section 35 at the first end 75 from the filter device 120. The filtered exhaust gas 25 flows in the first branch section 35 from the first end 75 to the second end 80 along the first main direction of extent. At the second end 80, the exhaust gas 25 enters the second branch section 40 and fills the first damper volume. The exhaust gas 25 is deflected by the first angle α and flows into the second strand section 40 along the second main direction of extent of the second strand section 40.

In the embodiment, the exhaust gas 25 is sucked in from the second branch section 40 by the fan 185. After flowing through the fan 185, the fan 185 conveys the exhaust gas 25 on the downstream side to the outlet side 50. At the outlet side 50, the exhaust gas 25 emerges from the exhaust gas line 20.

Deflagration can occur in the filter device 120 during operation of the exhaust line 20. The deflagration can result from the ignition of a combustible gas mixture, for example carbon monoxide, hydrogen and oxygen. The inflammation can be caused by sparks or flashovers in the filter device 120. The deflagration causes a pressure fluctuation in the exhaust gas 25. The pressure fluctuation can in particular be designed as a pressure wave. The pressure fluctuation propagates in the exhaust line 20 from the filter device 120 to the inlet side 30 and to the outlet side 50.

FIG 2 FIG. 8 shows a diagram of a pressure p of the exhaust gas 25 plotted against a time t in the first strand section 35 at the first end 75.

A pressure curve of the pressure p over the time t of the pressure fluctuation upon entry into the first branch section 35 is shown in FIG FIG 2 represented by means of a first graph 101.

The pressure fluctuation can have a first maximum pressure p _DS of 0.5 bar above normal pressure (approximately 1 bar) of the exhaust gas 25.

With a first maximum pressure p _{DS, the} pressure fluctuation exceeds a predefined maximum pressure p _MAX , which the pressure-sensitive component 55 can cope with without being damaged. The maximum pressure p _MAX is in FIG 2 represented by a line 102 running parallel to the abscissa.

The pressure fluctuation in the first strand section 35 is so great that if the pressure-sensitive component 55 were arranged in the first strand section 35, the pressure fluctuation would lead to damage or destruction of the pressure-sensitive component 55.

The pressure fluctuation moves along the first main direction of extent of the first strand section 35 in the direction of the second end 80. At the connection of the second strand section 40 to the first strand section 35, the pressure fluctuation is divided essentially in half into a first portion and a first remaining portion. A first part of the pressure fluctuation occurs with a second maximum pressure p ₂ into the second strand section 40. The pressure fluctuation that runs in the second interior space 95 is shown in FIG FIG 2 represented by a second graph 103, which is drawn with a solid line.

At the second end 80, the first remaining portion of the pressure fluctuation enters the first damper volume 110. The first remaining portion of the pressure fluctuation spreads in the first damper volume 110 from the second end 80 to the first cover area 105. At the first cover region 105, the first remaining portion is reflected on the inside by the first cover region 105, which is preferably arranged perpendicularly to the first straight line 60. A first damper structure can be arranged on the inside of the first cover region 105 in order to scatter and / or attenuate the first remaining portion of the pressure fluctuation during the reflection. The first damper structure can have an elastic material and / or be honeycomb-like and / or have a corrugation.

The reflected first residual portion of the pressure fluctuation again passes through the first damper volume 110 and re-enters the first strand section 35 at the second end 80 and spreads from the second end 80 to the first end 75 in the first strand section 35.

At the connection, the reflected first remaining portion is divided into a second portion and a second remaining portion in each case approximately in half. The second portion of the reflected first residual portion enters the second strand section 40 with a third maximum pressure p ₃ . The second remaining portion runs in the direction of the first end of the first strand section 35.

In the FIG 1 The embodiment of the exhaust gas line 20 shown has the advantage that the pressure fluctuation from the first line section 35 into the second line section 40 is reduced.

The pressure fluctuation propagates in the second interior space 95 towards the pressure-sensitive component 55. As a result, the pressure curve of the pressure p in the second strand section has, for example, two waves (cf. FIG 2 ) which do not fall below the maximum pressure p _MAX. The second maximum pressure p ₂ and the third maximum pressure p ₃ are smaller than the maximum pressure p _MAX . The weakening, which is reflected in the amplitude reduction of the pressure fluctuation, prevents damage to the pressure-sensitive component 55, e.g.

FIG 3 shows a schematic representation of a system 10 according to a second embodiment.

The system 10 is essentially identical to that in FIG FIGS. 1 and 2 illustrated system 10 formed. In the following, the differences between the in FIG 3 system 10 shown compared to that in FIGS FIGS. 1 and 2 System 10 shown was received.

In addition, a damper device 125 is arranged in the second strand section 40. The damper device 125 is located in the second interior space 95. The damper device 125 has at least one first reflector plate 130. In addition, the damper device 125 can have a second reflector plate 135.

The first reflector plate 130 is arranged on a side facing the first strand section 35. The first reflector plate 130 is arranged on the inside of the second wall 85 and is preferably fastened to an inside of the second wall 85. The first reflector plate 130 extends inclined, preferably perpendicular, to the second straight line 85. The first reflector plate 130 extends over a first sub-area of the second inner cross-sectional area of the second interior 95. It is particularly advantageous if the first sub-area extends over 20% to 50% of the second inner cross-sectional area of the second interior 95 extends. the The first reflector plate 130 can, for example, be plate-shaped and can be planar on a first end face 140 facing the first strand section 35. The first reflector plate 130 can also have a predefined second damper structure, for example a honeycomb structure, on the first end face 140.

The second reflector plate 135 is arranged in the transverse direction perpendicular to the second straight line 85 opposite the first reflector plate 130 in the second interior space 95. The second reflector plate 135 is connected on the circumferential side to the inside of the second wall 90. The second reflector plate 135 extends over a second sub-area of the second inner cross-sectional area of the second interior space 95, the second sub-area being approximately 20% to approximately 50% inclusive of the second inner cross-sectional area.

The second reflector plate 135 is plate-shaped and is preferably inclined, in particular perpendicular, aligned with the second straight line 85. In FIG 3 the second reflector plate 135 thus extends in an xz plane. The second reflector plate 135 is arranged parallel in the y-direction and thus offset in the direction of the second straight line 85 to the first reflector plate 130.

In the embodiment, the damper device 125 has a plurality of first reflector plates 130, the first reflector plates 130 preferably being designed to be identical to one another. The first reflector plates 130 are arranged offset from one another in the second main direction of extent and thus in the y direction. Two first reflector plates 130 arranged closest to one another each have a first spacing a ₁ .

The second reflector plate 135 is in the second main direction of extent between the two closest first Reflector plates 130 arranged. The second reflector plate 135 can be arranged on the downstream side of the first reflector plate 130 and thus on a side facing away from the first strand section 35 of the first reflector plate 130. The second reflector plate 135 is preferably arranged in a central position between two closest first reflector plates 130. Thus, a second distance a ₂ of the second reflector plate 135 to the upstream-side to the second reflector plate 135 first reflector plate 130 equal to a third distance a ₃ to that based on the second reflector plate 135 is arranged downstream the first reflector plate 130. Also, the second distance a ₂ can be different from the third distance a _3. The second distance a ₂ and the third distance a ₃ are selected such that a passage area between the first reflector plate 130 and the second reflector plate 135 has at least 40 to 70% of the second inner cross-sectional area.

In FIG 3 the damper device 125 has a plurality of first reflector plates 130 and a plurality of second reflector plates 135, which are arranged alternately in relation to the second straight line 85 in the second interior space 95. By way of example, the first reflector plates 130 and the second reflector plates 135 are arranged at a regular distance from one another. A fourth distance a ₄ between two second reflector plates 135 arranged closest in the second main direction of extent can also correspond to _{the first distance a 1. The fourth distance a 4} can also be selected to be different from the first distance a ₁ .

A second end face 145 of the second reflector plate 135, which is on the upstream side and thus faces the first strand section 35, can be designed to be planar. A third damper structure can also be arranged on the second end face 145. The third damper structure can, for example, be embodied identically to the second damper structure on the first end face 140 of the first reflector plate and / or the first damper structure on the first cover region 105. So For example, the third damper structure can be honeycomb-like or have a corrugation.

In the operation of the system 10, as in FIGN 1 to 2 explained, the pressure fluctuation is introduced into the first strand section 35 via the first end 75. The first portion of the pressure fluctuation and the second portion of the reflected pressure fluctuation enter from the first strand section 35 into the second strand section 40 with a time delay. The first portion and the second portion spread in the second strand section 40 towards the outlet side 50. In the following, only the influence of the damper device 125 on the first portion of the pressure fluctuation is explained. For the second portion of the reflected pressure fluctuation, the same applies to the first portion explained below.

The first portion of the pressure fluctuation runs along the second straight line 85 in the second strand section 40 in the direction of the outlet side 55 Pressure fluctuation. If the second damper structure is arranged on the first end face 140, the first reflector plate 130 can additionally not only reflect the first part of the first portion of the pressure fluctuation, but also reflect it in a scattered manner and / or reflect it attenuated. The reflected first part is essentially reflected back in the direction of the first strand section 35. A second part of the first portion of the pressure fluctuation flows around the first reflector plate 130 and then strikes the second reflector plate 135 on the way on the outlet side 50.

The second reflector plate 135, like the reflector plate 130, reflects a third part of the first portion of the pressure fluctuation in the direction of the first strand section 35 on the second end face 145. The third damper structure can also not only reflect the third part of the pressure fluctuation reflect, but also reflect in a scattered manner and / or reflect and / or attenuate attenuated.

As a result of the plurality of first and second reflector plates 130, 135, the first and second components of the pressure fluctuation running in the second strand section 40 from the first strand section 35 to the outlet side 50 are partially reflected by each of the reflector plates 130, 135 back in the direction of the first strand section 35, so that the amplitude of the first part of the pressure fluctuation decreases with each reflection.

This has the consequence that the first and second components of the pressure fluctuation in the second branch section 40 are further reduced by the damper device 125, so that when the first component or the second component of the pressure fluctuation hits the pressure-sensitive component 55, for example the fan 185, it will not be damaged.

FIG 4 shows a schematic representation of a system 10 according to a third embodiment.

The system 10 is essentially identical to that in FIG FIGN 1 to 3 illustrated system 10 formed. In the following, the differences between the in FIG 4 system 10 shown compared to the in FIG 3 System 10 shown was received.

In FIG 4 are opposite FIG 3 the inlet side 30 and the outlet side 50 interchanged. As a result, the direction of flow of the exhaust gas 25 in the exhaust gas line 20 is opposite FIG 3 in reverse. The pressure-sensitive component 55 is arranged downstream of the inlet side 30 in connection. The filter device 120 is arranged on the downstream side of the first line section 35 between the first line section 35 and the outlet side 50. The pressure-sensitive component 55 is arranged on the upstream side of the filter device 120 and the strand sections 35, 40, the first damper section 45 and the damper device 125. This is the pressure wave-sensitive component 55 is fluidically connected upstream of the second strand section 40.

How the in FIG 4 essentially corresponds to the one shown in FIG FIGN 1 to 3 Functioning of the system 10. In contrast to this, the pressure fluctuation, coming from the filter device 120, spreads against the flow direction of the exhaust gas 25 in the exhaust line 20 and thus in the direction of the inlet side 30 via the first line section 35 to the second line section 40.

In this embodiment, too, the first damper section 45 dampens the pressure fluctuation as it propagates from the filter device 120 to the inlet side 30. The damper device 125 further dampens the pressure fluctuation on the way against the flow of the exhaust gas 25. In this embodiment, too, the upstream side of the damper device 125 pressure-sensitive component 55 arranged between the damper device 120 and the inlet side 30 is protected from overloading due to the pressure fluctuation.

FIG 5 shows a schematic representation of a system 10 according to a fourth embodiment.

The system 10 is essentially a further development and combination of the FIGN 1 to 3 In addition to the first and second line sections 35, 40 and the first damper section 45, the system 10 has a second damper section 155 and a third line section 160 as well as the pressure-sensitive component 55. A modification of the in FIG 5 system 10 shown with reversed flow direction and thus exchanged inlet side 30 and outlet side 50 as in FIG FIG 4 shown is possible.

The first strand section 35, the first damper section 45 and the second strand section 40 are as in FIG FIG 1 explained trained. Closes to the second strand section 40 the second damper section 155 adjoins, the second damper section 155 being straight and in alignment with the second strand section 40. The second damper section 155 is arranged on a side of the second strand section 40 facing away from the first strand section 35 and is connected both mechanically and fluidically to the second strand section 40. The second damper section 155 extends along the second straight line 85.

The second damper section 155 is essentially identical to the first damper section 45 and includes a second damper volume 156.

A second pipe section 158 of the second damper section 155 has a smaller second maximum length l ₂ along the second straight line 85 than the first pipe area 100 of the first damper section 45. It is particularly advantageous if a ratio of the second maximum length l ₂ to the maximum second Inner extension b _{2 has} a value which is in a range from 0.5 to 1.5 inclusive. It is particularly advantageous if the ratio is approximately 1.

The maximum first internal extension b ₁ and the maximum second internal extension b ₂ are in FIG FIG 5 exemplary identical. The maximum second internal extension b ₂ can also be different, preferably smaller, than the maximum first internal extension b ₁ . Furthermore, the second maximum length l _{2 is,} for example, shorter than the first maximum length l ₁ . As a result, the second damper volume 156 is, for example, smaller than the first damper volume 110.

The third strand section 160 is arranged on the downstream side of the second strand section 40. The third strand section 160 is fluidically connected to the second strand section 40 on the upstream side and to the pressure-sensitive component 55 on the downstream side.

The fan 185 is designed to suck in the exhaust gas 25 from the inlet side 30 and convey it to the outlet side 50.

The third strand section 160 is subdivided into two subregions 190, 195, which are embodied in a straight line, for example, the two subregions 190, 195 being connected to one another by an arched section 200 of the third strand section 160. The damper device 125 is arranged in each case in a third interior space 170 of the two subregions 190, 195. The arrangement of the damper device 125 in the curved section 200 can be dispensed with.

During the operation of the system 10, as explained above, the pressure fluctuation can arise as a result of the deflagration in the filter device 120. The pressure fluctuation flows together with the exhaust gas 25 via the first branch section 35 in the direction of the first damper section 45. The pressure fluctuation is thereby via the first damper section 45, as in FIG FIG 1 explained, reflected. The first and second portions enter the second strand section 40 with a time lag and move along the second main direction of extent in the direction of the third strand section 160. At the connection of the third strand section 160, the first portion and the second portion each split into a third remaining portion and a third Share about half.

The function of the second damper section 155 corresponds to the function of the first damper section 45. The third remaining portion enters the second damper section 155 and is reflected on a second cover area 157 of the second damper section 155 in the direction of the first strand section 35. At the connection of the third strand section 160, the third remaining portion is divided approximately in half into a fourth remaining portion and a fourth portion. The fourth remaining portion moves in the direction of the first strand section 35. The fourth portion enters the third strand section 160 at a time offset from the third portion.

A third component and the fourth component move in the direction of the outlet side 50 with a time delay, the third component and the fourth component being further attenuated by the damper device 125 in the third branch section 160.

In front of the fan 185, the pressure fluctuation is weakened to such an extent that it does not damage the pressure-sensitive component 55. The second and third maximum pressure p ₂ , p _{3 of} the pressure fluctuation at the end of the third line section 160 on the pressure-sensitive component is essentially about 10% to 25% of the first maximum pressure p ₁ when the pressure fluctuation enters the first line section 35. This creates an overload of the pressure sensitive component 55, in FIG 5 of the fan 185, avoided. This prevents mechanical damage to the pressure-sensitive component 55. This ensures a long service life for the exhaust line 20. Furthermore, a pressure-stable design of the pressure-sensitive component 55 can be dispensed with, so that it is particularly cost-effective. Furthermore, there is no need for additional pressure relief flaps.

It should be noted that analogous to FIG 4 the inlet side 30 and the outlet side 50 can also be interchanged, so that the flow direction of the exhaust gas 25 in FIG FIG 5 is opposite to that described above.

Claims (14)

Exhaust gas line (20) for discharging an exhaust gas from a large industrial plant (15), in particular a metallurgical plant, - Having a filter device (120), a first strand section (35), a second strand section (40) and a damper section (45), - The filter device (120) being designed to at least partially filter the exhaust gas (25), - wherein the first strand section (35) is fluidically coupled to the filter device (120) at a first end (75) and extends along a first main direction of extent, - wherein at a second end (80) of the first strand section (35) facing away from the first end (75), the first strand section (35) is mechanically and fluidically connected to the second strand section (40) and the damper section (45), - wherein the damper section (45) extends along the first main direction of extent away from the first strand section (35) and delimits a predefined damper volume (110) that can be filled with exhaust gas (25) on the inside, - wherein the damper section (45) is designed to at least partially reflect a pressure fluctuation spreading from the filter device (120) in the direction of the second end (80) in the exhaust gas (25) back into the first strand section (35), - wherein the second strand section (40) extends laterally away from the first strand section (35) and is designed to discharge or feed the exhaust gas (25) from the first strand section (35). Exhaust line (20) according to claim 1, - wherein the damper section (45) has a tube region (100) extending along the first main direction of extent and one inclined to the first Having the main extension direction formed cover area (105), - wherein the tube area (100) is mechanically connected on a first side to the first strand section (35) and on a second side opposite to the first side in the first main direction of extent to the cover area (105), - the inside of the cover area (105) and the tube area (100) delimiting the damper volume (110). Exhaust line (20) according to claim 2, - wherein the first strand section (35) extends upstream to the second end (80) in a straight line along a first straight line (60), - The tube region (100) being aligned with the first strand section (35) and extending in a straight line along the first straight line (60). Exhaust line (20) according to claim 2 or 3, - wherein the first strand section (35) has a first inner cross-sectional area, - wherein the tube region (100) has a second inner cross-sectional area, - wherein the first cross-sectional area and the second cross-sectional area are essentially identical. Exhaust line (20) according to one of claims 2 to 4, - wherein the tube region (100) has a maximum internal extent (b ₁ , b ₂ ) perpendicular to the first main direction of extent, - wherein the tube region (100) has a maximum length (l ₁ , l ₂ ) along the first main direction of extent, - wherein a ratio of the maximum length (l ₁ , l ₂ ) to the maximum internal extension (b ₁ , b ₂ ) has a value which is in a range from 0.5 to 1.5 inclusive, - The ratio is preferably 1. Exhaust line (20) according to one of the preceding claims, - wherein the second strand section (40) extends downstream to the first strand section (35), preferably along a second straight line (85), - wherein the second strand section (40) extends along a second main direction of extent inclined at an angle to the first main direction of extent, - The angle being 70 ° to 110 °, in particular 87 ° to 93 °, particularly advantageously 90 °. Exhaust line (20) according to one of the preceding claims, - A damper device (125) being arranged on the second strand section (40), - wherein the damper device (125) has at least one first reflector plate (130), - wherein the plate-shaped first reflector plate (130) extends inclined, preferably perpendicular, to a second main direction of extent of the second strand section (40) over a first partial area of a second cross-sectional area of the second strand section (40), - wherein the first reflector plate (135) extends in a transverse direction inclined to the second main direction of extent over a first partial area of a second cross-sectional area of the second strand section (40). Exhaust line (20) according to claim 7, - wherein the damper device (125) has at least one second reflector plate (135), - The plate-shaped second reflector plate (135) being inclined, preferably perpendicular, to the second main direction of extent, - wherein the second reflector plate (135) is arranged offset in the second main direction of extent to the first reflector plate (130), - The second reflector plate (135) being arranged opposite the first reflector plate (130) in the transverse direction, - wherein the second reflector plate (135) extends in the transverse direction over a second partial area of the second cross-sectional area of the second strand section (40). Exhaust line (20) according to claim 8, - wherein the damper device (125) has at least two first reflector plates (130), - wherein the two first reflector plates (130) are arranged offset in the second main direction of extent of the second strand section, - wherein the second reflector plate (135) is arranged in the second main direction of extent between the two first reflector plates (130). Exhaust line (20) according to claim 8 or 9, - wherein the first reflector plate (130) extends with the first partial area over 20% to 50% percent of the second inner cross-sectional area. Exhaust line (20) according to one of the preceding claims, - Having a pressure wave sensitive component (55) and an inlet side (30), - wherein the inlet side (30) can be connected to the large-scale industrial plant (15) and the exhaust gas (25) can be introduced into the exhaust gas line (20) via the inlet side (30), - wherein the filter device (120) is arranged upstream of the first strand section (35) between the inlet side (30) and the first strand section (35), - wherein the pressure wave-sensitive component (55) is connected downstream of the second string section (40) and is fluidically connected to the second string section (40). Exhaust line (20) according to one of the preceding claims, - Having a pressure wave sensitive component (55), an outlet side (50) and an inlet side (30), - wherein the inlet side (30) can be connected to the large-scale industrial plant (15) and the exhaust gas (25) can be introduced into the exhaust gas line (20) via the inlet side (30), - The cleaned exhaust gas (25) can be discharged via the outlet side (50), - wherein the filter device (120) is arranged downstream of the first strand section (35) between the outlet side (50) and the first strand section (35), - wherein the pressure wave-sensitive component (55) is connected upstream of the second string section (40) and is fluidically connected to the second string section (40). Exhaust line (20) according to claim 11 or 12, - wherein the pressure-sensitive component (55) has at least one fan (185) and / or a pressure relief flap (165) and / or a switching station. System (10) - Having a large-scale industrial plant (15), in particular a metallurgical plant, and an exhaust gas line (20) according to one of the preceding claims, - The large-scale industrial plant (15) being designed to generate an exhaust gas (25), - wherein the exhaust gas line (20) is fluidically coupled and formed with the large-scale industrial plant (15) is to at least partially discharge the exhaust gas (25) of the large-scale industrial plant (15).

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