Thermal post-combustion device

Information

  • Patent Grant
  • 6780004
  • Patent Number
    6,780,004
  • Date Filed
    Friday, August 16, 2002
    22 years ago
  • Date Issued
    Tuesday, August 24, 2004
    20 years ago
Abstract
A thermal post-combustion device for the purification of exhaust air comprises an outer housing surrounded by an insulating jacket, a combustion chamber bounded by a combustion chamber housing and arranged within the outer housing, and a burner chargeable with fuel and that comprises a burner nozzle and a first flame tube that surrounds the burner nozzle and connects the space between the outer housing and the combustion chamber housing to the combustion chamber. The burner includes at least one further flame tube that is arranged completely within the combustion chamber, and the end of the first flame tube lying inside the combustion chamber is surrounded by a further flame tube of larger radius so as to form an annular gap between the first flame tube and the further flame tube. In this way a circulating flow of the combustion air becomes possible inside the combustion chamber, which flow is guided repeatedly through the annular gap and the flame of the burner. This improves the completeness of the combustion and produces a uniform temperature within the combustion chamber, with the result that the post-combustion device can be operated at a lower flame temperature.
Description




BACKGROUND OF INVENTION




The present invention relates to a thermal post-combustion device for the purification of exhaust air, comprising




a) an outer housing surrounded by an insulating jacket;




b) a combustion chamber bounded by a combustion chamber housing and arranged inside the outer housing;




c) a burner chargeable with a fuel and that comprises a burner nozzle and a first flame tube that surrounds the burner nozzle and connects the space between the outer housing and the combustion chamber housing to the combustion chamber.




Thermal post-combustion devices likewise serve in the same way as regenerative post-combustion devices for the purification of industrial waste gases that contain combustible substances. Regenerative post-combustion devices are employed in particular in cases where the purified gases are to be passed at as low a temperature as possible directly to a flue and the energy efficiency should be as high as possible so that the combustion process proceeds without the addition of external energy. This takes place through a relatively complicated heat exchange between the fed exhaust air and discharged purified combustion air.




Thermal post-combustion devices on the other hand employ a so-called “surface burner” for the combustion of the impurities entrained in the exhaust air, to which burner external energy is fed in the form of fuel. These surface burners operate without fans and extract the oxygen required for the combustion from the exhaust air to be purified, which is supplied under pressure. Also, thermal post-combustion devices generally comprise a heat exchanger in which heat is extracted from the combustion gases so that the latter flow out at a lower temperature; some of the heat is fed to the exhaust air to be purified, with the result that this is introduced already preheated into the actual combustion process. In general process heat is extracted from a thermal post-combustion device for use in another heat-consuming procedure taking place adjacent thereto, e.g. for heating purposes.




With the known thermal post-combustion devices available on the market of the type mentioned in the introduction, the burner has only a single flame tube, through which the exhaust air to be treated is introduced into the combustion chamber and fed to the flame generated by the burner nozzle. Since hot and cold air do not readily mix, with these known thermal post-combustion devices the complete combustion of all impurities is complicated despite the use of air vortexing means, with the result that higher flame temperatures have to be used for the combustion. This is associated with a threefold disadvantage: on the one hand the energy consumption is high. Secondly, materials that can withstand relatively high temperatures have to be used in the device and, finally, more undesirable nitrogen oxides are formed due to the high flame temperature.




The object of the present invention is to modify a thermal post-combustion device so that a complete combustion of the impurities in the exhaust air takes place already at relatively low flame temperatures.




This object is achieved according to the invention if




d) the burner has at least one further (“second”) flame tube that is arranged completely within the combustion chamber and the end of the first flame tube lying within the combustion chamber is surrounded by the further flame tube of larger radius so that an annular gap is formed between the first flame tube and the further flame tube.




The design of the burner according to the invention permits a circulating flow within the combustion chamber itself, the circulating flow passing through the gap between the first flame tube and the second/further flame tube and being assisted by the suction effect generated by the gas flow streaming through the inner flame tube. The exhaust air to be treated accordingly does not pass through the combustion chamber in a single passage, but is guided, possibly several times, through the flame of the burner nozzle before it finally leaves the combustion chamber in the direction of the heat exchanger. The circulating flow confers several benefits: there is a better air vortexing and thus mixing of cold and hot air streams, which improves the combustion. All the regions of the whole combustion chamber are heated uniformly. A complete combustion is ensured due to the multiple passage of the combustion gases through the flame. Overall it is thereby possible to reduce the flame temperature without impairing the complete combustion. Tests have shown that considerable energy savings of up to 10% may thereby be obtained. Also, cheaper materials may be employed for the various structural elements of the thermal post-combustion devices since they are not exposed to such high temperatures.




Particularly preferred is that modification of the invention in which a deflection means is provided spaced from the outlet opening of the further flame tube in the radially outer region of the combustion chamber, which device redeflects combustion air incident on the latter along the wall of the combustion chamber housing in the direction of the annular gap between the first flame tube and further flame tube. The deflection means thus assists the circulating flow mentioned above since it prevents the greater part of the air from already leaving the combustion chamber during its first passage through the flame.




It is furthermore convenient if the burner nozzle comprises a nozzle housing provided with passage openings and a fuel channel that has, in the region adjacent to the outlet opening, a venturi-like cross-sectional profile. The flow velocity of the fuel can be increased by this venturi-like cross-sectional profile and foreign gases can be aspirated through the passage openings of the nozzle housing so that the energy content of the fuel is reduced by “dilution”. The result is a flame of lower temperature that produces fewer nitrogen oxides. Also, the generated flame is broadened in the radial direction due to the acceleration of the fuel. This facilitates the introduction into the flame of the air flowing through the first flame tube and possibly through the air vortexing means located in the latter.











BRIEF DESCRIPTION OF THE DRAWINGS




One embodiment of the invention is described in more detail hereinafter with the aid of the drawings, in which:





FIG. 1

is an axial section along line


1





1


of FIG.


2


through the region in the vicinity of the burner of a thermal post-combustion device;





FIG. 2

is a section along line II—II of

FIG. 1

;





FIG. 3

is an axial section on an enlarged scale through the burner nozzle of the thermal post-combustion device of

FIG. 1

;





FIG. 4

shows an enlarged sectional view of the region in the vicinity of the burner of FIG.


1


.











DETAILED DESCRIPTION OF THE DRAWINGS




While this invention is susceptible of embodiment in many different forms, there is shown in the drawings and will be described in detail, one specific embodiment with the understanding that the present disclosure is to be considered as an exemplification of the principles of the invention and is not intended to limit the invention to the embodiment illustrated.




As

FIGS. 1 and 2

show, the illustrated thermal post-combustion device comprises an outer housing


1


that is surrounded by an insulating jacket


2


shown only diagrammatically. A combustion chamber


4


, which is bounded by a combustion chamber housing


3


, is located within the outer housing


1


. A burner, which is identified overall by the reference numeral


8


and whose outlet opening


9


terminates in the combustion chamber


4


, is inserted through an opening


5


in the insulating jacket


2


, through an opening


6


in the outer housing


1


, and through an opening


7


in the combustion chamber housing


3


.




As best seen in

FIG. 4

, the burner


8


comprises a cylindrical burner housing


10


and a first, cylindrical flame tube


11


that is inseted into the opening


7


of the combustion chamber housing


3


, as well as a second flame tube


12


coaxially aligned to the burner housing


10


and the first flame tube


11


. This second flame tube is displaced axially relative to the first flame tube


11


in the direction of the interior of the combustion chamber


4


and has a larger diameter than the first flame tube


11


, with the result that an annular gap


13


extending coaxially with respect to the flame tubes


11


,


12


is formed in an overlapping region the two flame tubes


11


,


12


.




A deflection device that is identified overall by the reference numeral


14


is installed, axially spaced from the outlet opening


9


of the burner


8


, on the inner jacket surface of the combustion chamber housing


3


. This deflection device consists of a plurality of blades


15


that are mounted at an acute angle with respect to the axis of the combustion chamber housing


3


and that optionally have a certain degree of torsion. A substantially freely traversible space


16


remains radially within the deflection means


14


, as can be seen in particular from FIG.


2


.




At the right-hand end of the combustion chamber


4


, which is no longer shown in the drawing, a heat exchanger is connected in a known manner, through which flows combustion gas generated in the combustion chamber


4


, on its path to the outlet. Also not shown is the inlet for the exhaust air to be treated, which communicates via the aforementioned heat exchanger with the space


17


lying between the outer housing


1


and the combustion chamber housing


3


.




The burner housing


10


carries on its outer jacket surface at the inner end two coaxial rows of air vortexing blades


18


,


19


, which are arranged at uniform angular interspacings over the whole circumference at an angle to the axis of the burner and are in addition tensioned, in a manner known per se.




A burner nozzle


20


, part of which is highlighted in

FIG. 3

in an axial section and on an enlarged scale, extends through the burner housing


10


. The nozzle housing


21


, which is cylindrical and is sealed at the internally lying end, is provided with a plurality of passage openings


22


in the jacket surface as well as in the front surface of the nozzle housing


21


. A nozzle insert


23


is mounted and secured in the interior of the nozzle housing


21


, and has a fuel channel


24


tapering in the manner of a venturi tube in the direction of the front surface of the burner housing


20


. The fuel channel


24


communicates with a fuel inlet


25


located outside the insulating jacket


2


.




The thermal post-combustion device described above operates as follows:




The exhaust air to be treated is, as already mentioned above, introduced via the inlet (not shown in the drawing) into the heat exchanger (likewise not shown), where it is heated up. The exhaust air then flows through the space


17


between the outer housing


1


and combustion chamber housing


3


to the annular inlet opening of the first flame tube


11


, which is bounded at its radially inner-lying edge by the burner housing


10


. From here on the air flows axially through the first flame tube


11


and is caused to execute a vortex motion by the air vortexing blades


18


and


19


. Following its further axial flow through the second flame tube


12


the air reaches the region of the flame generated by the burner nozzle


20


. The impurities contained in the exhaust air are combusted and thereby rendered harmless.




The air vortex generated by the air vortexing blades


18


,


19


expands in the form of a cone with increasing distance from the outlet opening


9


and its main volume strikes the deflection device


14


; only a certain proportion of the combustion air flows through the free space


16


and thence via the heat exchanger, where its heat is extracted, to the outlet of the thermal post-combustion device.




The greater part of the combustion air on the other hand is deflected towards the left by the deflection means


14


, along the wall of the combustion chamber housing


3


in FIG.


1


and reaches the annular gap


13


between the first flame tube


11


and the second flame tube


12


. The combustion air is sucked through this annular gap


13


and in this way reaches once more the region of the flame generated by the burner nozzle


20


, so that a renewed combustion of combustible impurities that may still be present takes place. A circulating flow is generated in this way within the combustion chamber


4


, which depending on the circumstances flows repeatedly over the deflection means


14


and through the annular gap


13


between the first flame tube


11


and the second flame tube


12


. The overall result is a substantially improved purification of the exhaust air, which moreover may take place at lower temperatures and is associated with considerable energy savings and furthermore with a lesser production of nitrogen oxides. The temperature distribution is very largely homogeneous inside the combustion chamber


4


; in particular, the regions of the combustion chamber


4


adjacent to the combustion chamber housing


3


are also heated up to a greater extent than was the case with known thermal post-combustion devices.




The fuels fed via the fuel channel


24


to the burner nozzle


20


are accelerated inside the said burner nozzle


20


on account of the venturi-like tapering of the fuel channel


24


. As a result air is sucked in, especially at the passage openings


22


of the nozzle housing


21


that are adjacent to the outlet opening of the fuel channel


24


. This additional air leads to a reduction of the energy density of the fuel, with the result that the combustion takes place at a lower temperature. The acceleration of the fuel by means of the venturi-like tapering in the fuel channel


24


also leads to a radial expansion of the generated flame. In this way the exhaust air flowing through the air vortexing blades


18


,


19


can be introduced more efficiently into the flame for the post-combustion of the impurities.




Gas was used as fuel in the embodiment of a thermal post-combustion device described above. It is obviously also possible to replace the gas burner nozzle


20


by an oil atomiser nozzle.




The foregoing description merely explains and illustrates the invention and the invention is not limited thereto except insofar as the appended claims are so limited, as those skilled in the art who have the disclosure before them will be able to make modifications without departing from the scope of the invention.



Claims
  • 1. Thermal post-combustion device for the purification of exhaust air, comprisinga) an outer housing surrounded by an insulating jacket; b) a combustion chamber bounded by a combustion chamber housing and arranged inside the outer housing; c) a burner chargeable with a fuel and that comprises a burner nozzle and a first flame tube surrounds the burner nozzle and connects the combustion chamber to a space which is disposed between the outer housing and the combustion chamber housing, characterized in that d) the burner has at least one second flame tube that is arranged completely within the combustion chamber and the end of the first flame tube lying within the combustion chamber is surrounded by the second flame tube of larger radius so that an annular gap is formed between the first flame tube and the second flame tube.
  • 2. Thermal post-combustion device according to claim 1, characterized in that a deflection means is provided spaced from an outlet opening of the further flame tube in the radially outer region of the combustion chamber, which deflection device redeflects combustion air incident thereon along the wall of the combustion chamber housing in the direction of the gap between the first flame tube and second flame tube.
  • 3. Technical post-combustion device according to claim 1 or 2, characterized in that the burner nozzle has a nozzle housing provided with passage openings and a fuel channel that has, in the region adjacent to the outlet opening, a venturi-like cross-sectional profile.
US Referenced Citations (23)
Number Name Date Kind
1235855 Stillman Aug 1917 A
2497480 Walshin Feb 1950 A
2796923 Fiske et al. Jun 1957 A
2857961 Brown et al. Oct 1958 A
2918117 Griffin Dec 1959 A
3748853 Jones et al. Jul 1973 A
4240784 Dauvergne Dec 1980 A
4380429 LaHaye et al. Apr 1983 A
4561841 Korenyi Dec 1985 A
4725223 Coppin et al. Feb 1988 A
4845940 Beer Jul 1989 A
5369679 Sliski et al. Nov 1994 A
5388985 Musil et al. Feb 1995 A
5490775 Joshi et al. Feb 1996 A
5540213 Shell et al. Jul 1996 A
5961315 Haumann et al. Oct 1999 A
6065957 Kondo et al. May 2000 A
6093018 Avshalumov Jul 2000 A
6102687 Butcher et al. Aug 2000 A
6106276 Sams et al. Aug 2000 A
6145450 Vatsky Nov 2000 A
6386863 Sarv et al. May 2002 B1
20020076669 Riepenhoff et al. Jun 2002 A1
Foreign Referenced Citations (7)
Number Date Country
591 656 Sep 1977 CH
30 43 286 Jun 1982 DE
695 15 109 Jul 2000 DE
421903 Apr 1991 EP
674134 Sep 1995 EP
2094464 Sep 1982 GB
62000762 Jan 1987 JP