DE19739704A1 - Heater with catalytic burner giving compact gas heater - Google Patents

Abstract

The heater has a heating shaft (1) containing a catalytic burner and a heat exchanger (9), with an ignition electrode (11) positioned between two axially spaced ceramic or metal bodies (3,4), each incorporating flow channels (2) and provided with a catalytic coating. The heat exchanger lies on the output side of the downstream ceramic or metal body, with an additional heat exchanger (13) in the path of the gas/air mixture fed to the heating shaft, for absorbing radiation heat.

Description

The invention relates to a heating device according to the preamble of claim ches 1.

In known heating devices of this type, usually only one is catalytically coated Flow channels provided ceramic or metal honeycomb body. It is but a complete implementation of the supplied fuel gas mixture is not always possible reach, especially not if the heating device is in a larger area is operated modulating.

Furthermore, heating devices of the type mentioned at the outset are known, in which meh rere honeycomb bodies are successively flowed through by the fuel gas mixture. Here results However, there is the disadvantage of a very wide design of the heating device, whereby also significant problems in removing heat from the innermost area of the heater well result.

The aim of the invention is to avoid these disadvantages and a heating device Propose the type mentioned, in which a compact structure is possible and the removal of heat even from the innermost area is easily possible.

According to the invention, this is achieved in the case of a heating device of the type mentioned at the beginning characteristic features of claim 1 achieved.  

The proposed measures result in the possibility of the heating device very compact to build because the two ceramic bodies are coaxially aligned. Furthermore is due to the arrangement of two catalytically coated Kera through which there is a flow mikkörper given the possibility of a practically 100% implementation of the fuel gas mix without ensuring overheating of the honeycomb body, even if the hot z device is operated modulating in a wide range.

The features of claim 2 have the advantage that the heat is very good and can be dissipated quickly. In addition, this also has the advantage that the inflow-side ceramic or metal honeycomb body flowing fuel gas mixture in front of the Thermal radiation is largely protected and there is therefore no reignition of the Mix comes.

The advantage of claim 3 is that the two Wa body can be made relatively small and still a complete implementation of the fuel gas mixture is ensured.

The features of claim 4 have the advantage that the implementation of Fuel gas mixture essentially only on the outflow side of the inflow side Wa takes place and therefore generates the heat essentially in this area becomes. As a result, there is only relatively little heat in the direction of the inflowing fuel gas mixture radiated so that it is not heated excessively and therefore it too kei ner overheating of the catalyst comes.

The features of claim 5 have the advantage that radiation losses largely avoided, so that the outside of the heating shaft accordingly is cooled.  

The features of claim 6 ensure that both ceramic or metal honeycomb bodies are kept at a catalytically active temperature.

The features of claim 7 result in the advantage of a very simple construction, where a good and rapid heat dissipation from the inflow-side honeycomb body is ensured is. The further heat exchanger through which the mixture flowing flows and this preheats, can be easily dimensioned according to the respective requirements sion. In addition, this heat exchanger forms a kind of barrier between the distribution device, for example a distributor plate, and the ignition electrode or the Honeycomb catalyst, which prevents the mixture from reigniting.

The features of claim 8 result in the advantage of the high flexibility of the order.

The flow direction of the inflowing Gemi makes sense when using condensing technology arrange from top to bottom as it offers an advantage that the condensate cannot drip onto the burner or catalyst.

The invention will now be explained in more detail with reference to the drawing. The Figs. 1 and 2 schematically show two different embodiments of the invention Heizeinrichtun gene.

The same reference numerals mean the same details in both figures.

The heating devices have a heating shaft 1 , in which two ceramic or metal honeycomb bodies 3 , 4 provided with flow channels 2 are arranged.

The two ceramic or metal honeycomb bodies 3 , 4 are aligned coaxially and spaced from one another. In the space between the two ceramic or Metallwa benkörpern 3 , 4 , of which the ceramic body 4 is provided over its entire height with a catalytic coating, which is located on the walls of the flow channels 2 , an ignition electrode 11 is arranged for ignition of the mixture during the starting phase. During the start phase, the mixture is burned in the form of flames. The resulting heat causes the catalytic coating to quickly reach its operating temperature and the mixture is converted catalytically.

The ceramic or metal honeycomb body 3 can be coated partially or fully catalytically.

The supply of a fuel gas mixture takes place via a mixing tube 5 , which opens into a mixture chamber 6 , which is connected to the heating shaft 1 . For more uniform distribution of the mixture in the mixture are a space provided with through holes 7 and downstream of this distribution plate 7, a separation grid Verteilbleches 8 or a finely perforated diffuser plate arranged.

On the outflow side of the second ceramic or metal honeycomb body 4 , a heat exchanger 8 is arranged in the heating shaft 1 and is connected to an exhaust gas line 10 .

An ignition electrode 11 is arranged between the two ceramic or metal honeycomb bodies 3 , 4 and is connected to an ignition device, not shown.

On the outside of the heating shaft 1 , a cooling coil 12 is arranged, through which egg nem heat-absorbing medium flows.

In the embodiment according to FIG. 1, a further heat exchanger 13 is arranged between the mixture space and the ceramic or metal honeycomb body 3 to the flow side, which is also provided with a catalytic coating over its entire height, which is connected to the heat exchanger 9 via a connecting line 14 is connected.

The fresh fuel gas mixture flows through the heat exchanger 13 and absorbs the thermal radiation from the inflow-side ceramic or metal honeycomb body 3 .

The embodiment according to FIG. 2 differs from that according to FIG. 1 only in that the additional heat exchanger 13 is missing and the inflow-side ceramic body 3 'is seen only in its downstream end region 15 with a catalytic coating.

When the heating device is operating, a fuel gas / air mixture flows via the mixture pipe 5 into the mixture chamber 6 and flows from the latter into the heating shaft 1 in an evenly distributed manner. In this case, the combustible gas mixture 3 flows through the ceramic or metal honeycomb body 3 'and the heating device in the outflow region of the ceramic or Metallwa benkörpers 3 at the start, 3' ignited and burns in small flames.

As a result, the ceramic or metal honeycomb body 3 , 3 'is heated by the heat of the flames. As a result, the catalytic coating of the ceramic or metal tall honeycomb body 3 , 3 'reaches its reaction temperature and the fuel gas mixture is implemented more and more catalytically. This also generates heat, and the flames gradually extinguish, since the gas emerging from the ceramic body 3 , 3 'does not contain a sufficient amount of fuel gas for combustion in flames.

The exhaust gases generated by the flames heat the ceramic or metal honeycomb body 4 , so that its catalytic coating also reaches its reaction temperature, and the fuel gas still contained in the gas mixture flowing through the ceramic body 4 is converted catalytically.

The resulting hot exhaust gases give their heat to the heat exchanger 9 and flow off via the exhaust line 10 .

In the embodiment of FIG. 1, the incoming fuel gas mixture is reacted over the entire height of the ceramic or metal honeycomb body 3, the Ke ramikkörper 3 thereby heating it. The heat radiated in the direction of the mixture space is absorbed by the heat exchanger 13 , as a result of which significant heating of the mixture space 6 is avoided.

In the embodiment according to FIG. 2, the implementation of the fuel gas mixture takes place only in the end region 15 of the inflow-side ceramic or metal honeycomb body 3 '. Since this heats up essentially only in this area, so that there is no significant heat radiation in the direction of the mixture chamber 6 .

The further conversion of the fuel gas mixture takes place in the ceramic body 4 .

The radiated to the radiator shaft 1 is abge leads via the cooling coil 12 , so that there are only small radiation losses.

Claims (8)

1. Heating device with a catalytically coated burner, which is arranged in a heating shaft ( 1 ) in which a heat exchanger ( 9 ) is arranged, with an ignition electrode ( 11 ) on the outflow side of a through-flow channels ( 2 ) having the ceramic or metal honeycomb body ( 3 , 3 ') is arranged, which is provided with a catalytic coating, characterized in that the ignition electrode ( 11 ) between two axially aligned ceramic or Metallwa benkörpern ( 3 , 3 '; 4 ) is arranged, the Heat exchanger ( 9 ) is arranged downstream of the downstream ceramic or metal honeycomb body ( 4 ). 2. Heating device according to claim 1, characterized in that seen in the flow direction of the fuel gas mixture, upstream of the inflow-side n catalytically coated ceramic or metal honeycomb body ( 3 ), a further heat exchanger ( 13 ) is arranged, which is flowed through by the fuel gas mixture and absorbs the radiant heat. 3. Heating device according to claim 1 or 2, characterized in that the two ceramic bodies ( 3 , 4 ) are provided over their entire height with a catalytic coating. 4. Heating device according to claim 1, characterized in that the inflow-side ceramic or metal product body ( 3 ') is provided exclusively in its outflow end region ( 15 ) with a catalytic coating, whereas the downstream ceramic or metal honeycomb body ( 4 ) is provided over its entire length Height is provided with a catalytic coating. 5. Heating device according to one of claims 1 to 4, characterized in that the heating shaft ( 1 ) ausgebil det at least in sections as a water-permeable double jacket or outside is provided with a water-permeable cooling coil ( 12 ). 6. Heating device according to one of claims 1 to 5, characterized in that the heating shaft ( 1 ) in the area between the two ceramic or metal honeycomb body ( 2 , 3 ) is insulated. 7. Heating device according to claim 1, characterized in that the further heat exchanger ( 13 ) between immediately downstream an opening of the mixing tube ( 5 ) the inflowing mixture distributing distribution device ( 7 , 8 ) and the inflow-side honeycomb body ( 3 ) is arranged. 8. Heating device according to one of claims 1 to 7, characterized characterized in that the flow direction of the inflow orien the mixture from top to bottom or vice versa is.