DE3107664A1 - Installation for post-combustion of organic constituents of process waste gases - Google Patents

Abstract

An installation for post-combustion of organic constituents in process waste gases has, at the inlet into a reaction chamber, an annular-cylindrical supply line for the crude gases which surrounds the burner flame. A heat exchanger is connected upstream of the reaction chamber on the crude gas side and downstream of the reaction chamber on the clean gas side, in order to transfer heat from emerging clean gases to the crude gases supplied to the installation. In the direction of the crude gas stream, there is first of all an outer, first crude gas supply line surrounding the installation in the form of twin bases (7, 13) and twin cylindrical casings (3, 9) in order to cool the outer casing of the installation. Connected in series to this first crude gas supply line is a clean gas heat exchanger and crude gas heat exchanger (13, 13', 25) and a second internal crude gas supply line between the base (13') of the heat exchanger and that of the reaction chamber (17), and also between the inner cylindrical casing (9) of the first crude gas supply line and that of the reaction chamber (15), in order to cool the casing (15) of the reaction chamber. <IMAGE>

Description

The present invention relates to a device for

Post-combustion of organic components in process exhaust gases with a die Ring-cylindrical feed of the raw gases at the inlet, encompassing the burner flame into a reaction space and a raw gas side upstream and clean gas side of the reaction space downstream T, 7 heat exchanger for transferring the heat from the clean gases emerging to the raw gases supplied to the facility.

Containing organic components in post-combustion facilities Process exhaust gases are often used for intensive mixing of the process exhaust gases into the burner flame, this one Interfering upstream, the raw gases a rotary flow through corresponding internals, in usually guide vanes, imposed and before the introduction into the burner flame. and downstream of the exit from the reaction chamber, a heat exchanger for recovery the clean gas heat for preheating the raw gases introduced into the facility intended.

It is already an incinerator for afterburning organic pollutants in exhaust gases known, in which the reaction space in a flame tube and a combustion chamber immediately following this in the gas flow is subdivided. the Combustion chamber also serves as a deflection chamber and has a larger volume and larger Diameter than the flame tube, which protrudes centrally into the combustion chamber empties.

The heat exchanger for the raw gas / clean gas heat exchange encloses here the flame tube (AS 23 52 204). Here, the clean gases are used for a pressurization the tubes of the heat exchanger from the outside in a cross-countercurrent duct several times diverted. The jacket of the flame tube is either through the clean gases to the heat exchanger upstream or acted upon downstream of the same by the raw gases.

The heat exchanger and combustion chamber are inside the combustion device locally separated from each other and possibly several combustion devices structurally via the combustion chamber or the flame tube as a central and at the same time connecting link connected to one another to form a unit.

This previously known device is primarily based on the task with complete combustion of the pollutants or contaminants in the exhaust gases enable high throughput with a compact design.

The object of the present invention is to have a compact design the reaction space and the outer shell of the device in an economical way and Way to isolate from the environment and easy assembly and disassembly and to provide access to all fixtures in the device for maintenance and cleaning.

This task is carried out by a facility of the type mentioned at the beginning solved according to the invention by the one behind the other circuit in the direction of the raw gas flow an outer first raw gas duct in the form of double ones surrounding the device Floors and double cylinder jackets for cooling the outer jacket of the facility, of the clean gas / raw gas heat exchanger and an inner second Rohaasführung between the bottom of the heat exchanger and that of the reaction chamber as well as the inner jacket of the cylinder the first raw gas feed and that of the reaction chamber for cooling the reaction chamber jacket. With this configuration, the cooling of the outer jacket becomes primary and that of the reaction space secondarily in a simple manner through the raw gases supplied to the device causes. The consequences are only inexpensive thermal insulation from the environment and at the same time a simple, inexpensive preliminary or

Reheating of the raw gases for heating in the intermediate heat exchanger.

The arrangement of the axis of the burner is particularly advantageous in a plane substantially perpendicular to the main axis of the device.

This arrangement of the burner axis, approximately perpendicular to the axis of the Facility, the raw gas stream after entering the reaction chamber on the burner exhaust gas jet accumulated and deflected to the walls and the gas mixture of burner exhaust gases and these supplied raw gases when they reach the opposite of the burner flame Wall areas of the reaction space forced a rotary flow, which is within of the reaction chamber up to its axial clean gas outlet and beyond. Simply by assigning the burner axis and the axis of the reaction chamber below an angle, in particular in an axially perpendicular arrangement, and one on top of it related design of the reaction space is free of internals the mixing of the gases caused by the rotary flow and thus the flow path or the time extended to the end of the reaction.

Particularly advantageous with regard to a free choice of the inlet cross-section for the preheated raw gases that are supplied around the burner flame the inner cylinder jacket of the device and the cylinder jacket of the reaction chamber additional floors on the side opposite the clean gas outlet. The floor the reaction space here has one or more openings, for example one central opening for dividing the preheated raw gases into partial flows. In addition to a partial flow surrounding the burner flame, perpendicular to the axis of the Device, in this way one or more additional ones, roughly in the axis fed to the device or parallel to it to the reaction chamber.

To the outer first raw gas duct, which surrounds the device on all sides, which is connected upstream of the clean gas / raw gas heat exchanger, another occurs at the same time the clean gas / raw gas heat exchanger downstream of the inner second, which is the reaction chamber encloses for itself shielding on all sides.

A raw gas inlet connection in an axially perpendicular can be advantageous Be on the level of the facility, possibly offset parallel to the axis perpendicular, to then continue using the corresponding side sheets for Dissipation of the radiant heat from the reaction space by cooling the outer jacket Raw gases introduced into the facility within the all-round enclosing to lead outer first raw gas guidance more specifically.

On the other hand, there is also an axial raw gas inlet on the clean gas outlet opposite side of the facility possible.

Through these measures, not only the side of the clean gas outlet is advantageous, but also the opposite in an all-round shielding of the device included in relation to the environment.

In an advantageous embodiment of the invention, it is in series one behind the other a central clean gas outlet from the reaction chamber one that extends in the axial direction downstream central passage and within it at least one regulating body arranged, optionally between a jam and a free passage the position causing the clean gases is to be set, the tubes of the clean gas-raw gas heat exchanger enclose the central passage in a ring.

There are several regulating organs one after the other within the central passage switched, so is for a multiple exposure to the tubes of the heat exchanger through the clean gases alternating from outside to inside and vice versa between successive control organs a guide plate in a plane perpendicular to the axis provided within the pipe register extending from the surrounding jacket and extends to the central flow cross-section.

In order to achieve a more targeted application of the tubes of the heat exchanger in the To achieve cross-countercurrent, it is advisable to add further baffles to the control organs to be assigned directly in their axially perpendicular planes that adjoin their scope and an annulus to enclose the pipe register Innehmantei Leave blank of the double label of the facility. The regulatory bodies allow a change the heat transfer from the pure to the raw gases in adaptation to the fluctuations in the physical properties of the process exhaust gases, such as calorific value, volume flow and temperature.

For free access to the internals, especially the pipes of the heat exchanger to clean it from the outside and inside, the device is axial in the plane of the clean gas outlet from the reaction space into a first, the reaction space, and to divide a second section containing the pipe register. Here the fixed point is expediently in the plane of the tube sheet on the side of the reaction chamber placed. The tube sheet and inner jacket of the device are to be connected to one another for this purpose. A gas-tight connection is required between the tube sheet and the floor of the reaction chamber or Provide their nozzle on the clean gas outlet side in order to mix the feed To prevent raw and derived clean gases. For this purpose, the tube sheet is used einhohrplatte in front of the tubes, the inner jacket of the device and Welded gas-tight to the central connecting piece, which complements the floor on the clean gas side is. For a separation of the reaction space from the heat exchanger are in the area of the nozzles complementing their bottoms, separation points near the plane of the fixed point intended.

The tube sheet of the heat exchanger is on the outlet side of the clean gases sliding out of the device on the inside of the inner jacket of the double jacket the establishment led so that after opening the bottom on this side, interrupt the connection between the reaction space and heat exchangers in the area of the separation point, Loosen the sleeves between the inner jacket and the tube sheet on the reaction chamber remote side the tube bundle from the facility for inspection and cleaning the pipe interior and exterior can be pulled out. That is advantageous central passage of the tube sheet directly on the side facing away from the reaction chamber connected to a pipe socket, which is freely movable, but gas-tight, within of the pipe socket leading to the outside in the floor of the facility on the clean gas outlet side guided is. In this way, different thermal expansions of the jackets Device and that of the internals, in particular the reaction chamber and the heat exchanger approved without tension.

To explain the concept of the invention is in the drawing in a Vertical section an embodiment of a device for afterburning organic Proportions in process exhaust gases shown schematically.

The process exhaust gases laden with organic components pass through the Nozzle 1 in an outer raw gas duct, which is from the outer jacket 3 and the these complementary outer floors 5, 7 and the inner jacket 9 as well as the complementary one inner bottom 11 and the tube sheet 13 of the clean gas / raw gas heat exchanger on the Side of the clean gas outlet is formed. After overflowing this the establishment In the space that isolates outward on all sides, the pre-warmed when flowing through occurs Raw gases on the clean gas outlet side of the device into the pipes of the clean gas-raw gas heat exchanger 13, 13 ', 25, flow through this for further heating, in order to enter another, Only the space shielding the reaction space, the space between the inner jacket the device 9 and the jacket 15 of the reaction chamber, the tube sheet 13 'and the Bottom 17 of the reaction space as well as its bottom 18 and the bottom 11 is formed For effective cooling of the thermally highly stressed bottom 18 of the reaction space after cooling the bottom 17 and the jacket 15, a partial flow of the process exhaust gases axially into the same via a central opening 16 in the bottom 18 of the reaction chamber initiated, while another partial flow enters through the annulus, from one inwardly protruding into the reaction space connector 19 in the jacket of the reaction space and the jacket 21a of the burner 21 is formed. With this central arrangement of the burner in a perpendicular to the axis of the device are the mixed gases when it hits the walls of the reaction space in two counter-rotating currents dissolved within of the reaction space up to the clean gas outlet and continue beyond. After leaving the reaction space, the clean gases are depending on the position of the control organs designed as circular baffle plates 23,23 'more or less strongly deflected and returned through the guide plates 27, that they are up to the gas outlet in the tube sheet 13 of the heat exchanger whose tubes 25 in Apply cross countercurrent from the outside. Annular disks 24,24 'within of the pipe register, which the regulating organs in the plane of their closed position to the outside supplement, serve a more targeted guidance of the gases in cross countercurrent. on the with the tube plate 13 connected nozzle 29, the clean gases emerge from the device the end. This connecting piece 29 is freely displaceable, but gas-tight, through the connecting piece 30 and flange 31 of the outlet opening in the bottom 7 of the device. For a gas-tight Separation of the raw gas space between the bottom 7 of the device and the tube sheet 13 as well as the clean gas inlet 33 in the transition area to the downstream device serve circular ring-shaped, screwed-together ring disks, of which the inner 35 with the nozzle 29 of the tube sheet 13 and the outer 37 with a jacket section 39 is connected.

Collars 41, 42 form in connection with the flange 31 of the connecting piece 30 or with that of the downstream device the gas-tight seal outward. Between the nozzles 29,30, ring flanges 35,37 and the sleeves 41, 42 insulation material 43 is included. For easier disassembly of the Brenners il and the better accessibility of the interior of the reaction chamber the outer jacket faces the burner shaft. 3 a connecting piece 45 with a flange 46 and the inner jacket 9 has a nozzle 47 with a flange 48, which in connection with the flange of the burner 21 and an intermediate insert 50 as well associated seals conditions a separation of the gas paths on the one hand and easy disassembly of the burner 21,21a going from the outside to the inside.

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Claims (13)

11 Device for the afterburning of organic components in the process 1. Device for the afterburning of organic components in process exhaust gases with a The ring-cylindrical feed of the raw gases at the inlet, encompassing the burner flame into a reaction space and a raw gas side upstream and clean gas side of the reaction space downstream heat exchanger for the transfer of the heat from emerging clean gases the raw gases supplied to the device, shown by the series connection in the direction of the raw gas flow of a first outer one surrounding the device Raw gas flow in the form of double bottoms (7.13) and double cylinder jackets (3.9) for cooling the outer jacket of the device, the clean gas / raw gas heat exchanger (13,13 ', 25) and an inner second raw gas duct between the bottom of the heat exchanger (13 ') and that of the reaction chamber (17) and the inner cylinder jacket (9) of the first Raw gas flow and that of the reaction chamber (15) for cooling the reaction chamber jacket. 2. Device according to claim 1, g e k e n n z e i c h n e t through the arrangement of the axis of the burner (21) in one to the main axis of the device essentially vertical plane. 3. Device according to claim 1 or 2, g e k e n n z e i c hn e t through the inner cylinder jacket (9) of the device and that of the reaction chamber (15) additional floors (11,18) on the opposite of the clean gas outlet (33) Side, the one of the reaction space with one or more openings (16) for the overflow of one or more partial flows of preheated raw gases is provided. 4. Device according to claim 1, 2 or 3, g e k e n n -z e i c h n e t through a raw gas inlet nozzle (1) into the device in an axially perpendicular Level of the device on its side opposite the clean gas outlet (33). 5. Device according to claim 4, g e k e n n z e i c h n e t through an eccentric offset of the raw gas inlet nozzle within the axis perpendicular Facility level. 6. Device according to claim 5, g e'k e n n z e i c h n e t through preferably axially extending guide plates (34) on the inside of the outer jacket (3) and / or the outside of the inner jacket (9) of the device. 7. Device according to claim 1, 2 or 3, g e k e n n -z e i c h n e t through an axial raw gas inlet nozzle (1) on the clean gas outlet (33) opposite side of the facility. 8. Device according to one or more of the preceding claims, not shown by the connection in series of a central clean gas outlet (20) from the reaction space, a central one extending it in the axial direction Passage (22), within this passage at least one between the jam and an adjustable regulating element that ensures the free passage of the clean gases (23), f e r n e r through a clean gas / raw gas heat exchanger (13, 13 ', 25), which the enclosing central passage. 9. Device according to claim 8, g e k e n n z e i c h -n e t through several control elements (23, 23 ') connected one behind the other in the axial direction within of the central passage (22) and a baffle switched between them (27) in a plane perpendicular to the axis of the device, that of the jacket of the pipe register (9) goes out and extends to the central passage (22). 10. Device according to claim 8 or 9, g e k e n n -z e i c h n e t further guide plates (24,24 ') directly assigned by the regulating elements (23,23') in planes perpendicular to the axis, which connect to the circumference of the control element (23,23 ') and an annular space to the inner jacket (91 of the double jacket) surrounding the pipe register (3.9) of the facility. 11. Device according to claim 1 or the following, g e k e n n -z e i c h n e t by dividing the device axially in the area of the clean gas outlet. (20) of the reaction space into a first, the reaction space (15, 17, 18), and one second, the pipe register (13,13 ', 25) containing construction section under gas-tight Overlapping overlap between the central clean gas outlet (20) from the reaction space and central opening of the tube sheet (13 ') of the clean gas / raw gas heat exchanger the side of the reaction space in the area of unilateral or bilateral connections. 12. Device according to claim 11, g e k e n n z e i c h -n e t through a detachable connection (28) between the reaction space (15, 17, 18) and the tube sheet (13 ') additional detachable connection (26) in the outer casing (3) of the device. 13. Device according to claim 3 or the following, g e k e n n z e i c h n e t through one with the central passage of the tube sheet (13) of the heat exchanger directly connected pipe socket on the side facing away from the reaction chamber (29) and a freely movable, gas-tight guide for the pipe socket in the floor (7) the device and / or its nozzle (30) on the clean gas outlet side.