DE19624933A1 - Exhaust heat exchanger, especially for boilers with fume condensers - Google Patents

Abstract

The heat exchanger has a combustion chamber (2) or a hot gas inlet, which opens into a hot gas guide chamber (3). Water-carrying heat exchanger pipes (7) pass through the latter, and at least the combustion chamber is surrounded by a water chamber (4). In operation, the pipes are inclined to the horizontal and are connected at their ends to the water chamber. The hot gases may pass through the guide chamber in a roughly vertical direction, and both the combustion and guide chambers may be enclosed by the water chamber. In operation, the combustion chamber may extend in a roughly horizontal direction, and may be arranged above the guide chamber.

Description

The invention relates to an exhaust gas heat exchange device, ins special a condensing boiler, with a burner room or a hot gas inlet that adheres to it Closing heating gas lead room opens with a heating water-conducting heat exchanger penetrating the gas guide space and with a water space at least surrounding the burner space.

Such a condensing boiler is for example in the DE-OS 44 06 030 A1 described. DE 44 06 030 discloses a condensing boiler with a horizontal burner chamber and one below, from the end of the burner chamber horizontal flow of hot gas, the vertical with itself extending heat exchanger tubes is penetrated.

In such a condensing boiler, the heating gas temperature cooled down to below the condensation point, the by the phase change used condensation heat used becomes. Accordingly, the boiler's heating gas flue must be so dimensioned sen that the desired cooling of the heating gases is achieved. Furthermore, heat must be as uniform as possible transmission to the boiler water.

To ensure this is the case in DE 44 06 030 described condensing boiler a complex management of Heating gases provided. The heating gases emerge from the overhead arranged combustion chamber by a vertically running  Neck in an adjoining one below Hot gas flue on. This heating gas flue consists of a middle one and two adjoining side pulls. The Heating gas first flows horizontally through the middle heating gas train and then distributes itself on the side trains, a cross flow of the heating gas through the gaps between the vertically extending heat exchanger tubes follows. The trains are interconnected by a water-bearing Partition separated.

In the known condensing boiler is that of Heizga coated area extremely high. Because when cooling the heating gases below the condensation point or dew point necessarily a corrosive condensate, all surfaces coming into contact with the heating gases, ins especially the exchanger surfaces made of corrosion-resistant steel be made. As a result, the known arrangement is exceptional really expensive. In addition, the construction of the be knew kettles consuming and the space requirement is very high.

The object of the invention is therefore, an exhaust gas heat exchange direction, in particular to create a condensing boiler, the while maintaining the benefits of the known calorific value boilers particularly compact and space-saving as well as cost is inexpensive to manufacture.

The object is achieved by an exhaust gas heat exchange device, in particular the condensing boiler solved type mentioned, which is characterized in that the heating gas duct from inclined to Hori in the position of use zontal running heat exchanger tubes is crossed, the are connected at the end to the water space.

In the preferred embodiment of the invention, the heating gas routing space from the heating gases approximately vertically flows. This also becomes the preferred cross flow the heating gases are obtained in relation to the heat exchanger tubes, whereby a particularly good heat transfer from the heating gas to the  Boiler water takes place, at the same time one becomes special multiple hot gas flow possible, which in turn is a compact and simple design of the boiler allows. The be from the heating gas Painted area is extremely small, which makes expensive Stainless steel installations can be saved, at the same time extraordinarily large volume of water for heat transfer Available. Due to the inclination of the heat exchanger tubes Heating the boiler water a natural circulation or a natural one Liche circulation of the boiler water is reached, whereby a damaging formation of vapor bubbles in the heat exchanger tubes is prevented. This also ensures adequate circulation of the boiler water in the heat exchanger pipes.

In a development of the invention it is provided that both the Burner room as well as the heating gas guide room from the water are surrounded. Such an arrangement can be particularly accomplish compact. The compact construction of the Kes sels, in particular the arrangement of the heat exchanger tubes, ver gives it a high compressive strength.

In the condensing boiler according to the invention can at for example the heat exchanger tubes and the inner jacket surface of the water space made of corrosion-resistant steel stand, whereas the outer surface or the outer Walls made of non-corrosion-resistant simple steel can exist. This will result in a significant cost savings achieved.

The burner chamber preferably extends in the position of use roughly horizontal and the heating gas duct is below the burner chamber.

It can be provided, for example, that only the lower heat exchanger tubes that have a temperature below the Heating gas dew point are exposed to corrosion-resistant Stainless steel. The burner is expedient to that underneath this arranged heating gas guide room open.  

According to a preferred embodiment of the invention is pre see that the inclination of the heat exchanger tubes through their Installation position is specified. This tendency can, for example be at least 3 °, so that just a circulation of the Boiler water is guaranteed. The greater the inclination of the Heat exchanger tubes, the stronger the boiler water circulation.

Alternatively, it can be provided that the inclination of the heat build-up shear tubes by an inclined arrangement or installation of the Boiler is specified.

A return water connection preferably opens into the lower one Area of the water space and the return water experienced in the Mouth area a positive guidance in the heat exchanger tubes. This reliably prevents part of the heating boiler water by the shortest route in the reaches the upper area of the water space.

It is expediently provided that the water space for Forced management of the return water in the mouth area of the return has a prechamber. To the with the Cooling of the heating gas accompanying decrease in speed the heating gas flow due to the volume reduction at continued to avoid progressive cooling and thus a possible uniform heat transfer to the boiler water ensure, it is provided that the heating gas guide room is tapered on the outlet side.

The tapering of the heating gas guide space is preferably this way chosen that the flow rate of the heating gas over the height of the heating gas guide room is approximately constant.

According to a particularly preferred embodiment of the invention the heat exchanger is formed by a tube bundle, in which the tube ends expanded on both sides, preferably hexagonal are and at their widening edges with the widening edges the neighboring pipes are welded. This gives the heat  exchanger the shape of a particularly compact tube bundle. The compact design enables one compared to conventional manufactured heat exchangers a higher heating surface on weni space and better efficiency. The polygonal preferably hexagonal, widening of the tube bundle end surface parqueting without gaps; that completely with each other welded tube bundle can be relatively easily in the inner Boundary surface or inner surface of the wastewater chamber be welded in. The use of such tube bundles enables light a particularly high material saving.

Of course, normal heat exchanger tubes can also be used Consistently the same cross-section as smooth tubes or as Find finned tubes.

The bundle of pipes in the condensing boiler according to the Er find preferred application are in the patent application application 195 01 276.3 of the applicant.

The exhaust gas heat exchange device according to the invention does not have to must be designed as a condensing boiler, rather, a lying arrangement can also be used as exhaust gas heat exchangers with high performance. At a Such an arrangement extends the heat exchanger tubes in Position almost vertical and the heating gas experiences an in about horizontal guidance.

The invention is described below with reference to one of the drawings illustrated embodiment explained.

They show:

Fig. 1 is a schematic side view of a first exporting approximate shape of the condensing boiler according to the OF INVENTION dung,

Fig. 2 is a front view of the combustion shown in Fig. 1 of the boiler,

Fig. 3 is a front view of a second embodiment of the condensing boiler according to the invention and

Fig. 4 shows another embodiment of the condensing boiler according to the invention.

The designated 1 condensing boiler has a lying arranged burner chamber 2 , which opens on its side remote from the burner, not shown, in a heating gas duct 3 arranged below the burner chamber 2 . The heating gases are passed vertically through the heating gas guide space 3 , ie the heating gas guide space 3 is formed as a shaft extending below the burner chamber 2 .

The burner chamber 2 and the heating gas guide chamber 3 are surrounded on all sides by a water chamber 4 . In the lower area of the water chamber 4 , a return water nozzle 5 is provided; At the highest point of the water space 4 , a supply water nozzle 6 is provided. The return water connector 5 and the supply water connector 6 are connected to a heating circuit, not shown.

The heating gas guide space 3 is interspersed with heat exchanger tubes 7 arranged essentially transversely to the heating gas flow, which are installed in the condensing boiler 1 in the example shown in FIG. 1 with a slight inclination with respect to the horizontal. The heat exchanger tubes, which are only shown schematically in the figures, are connected to the water space 4 on both sides. The heat exchanger tubes 7 are preferably tubes which are flared conically at their ends to form a hexagon and are welded to one another at the widening edges, so that the end faces of the tube bundle are completely parquetted, as can be seen particularly from FIGS. 2 and 3.

Below the heat exchanger tubes 7 , a condensate collecting chamber 8 , as well as an adjoining exhaust pipe 9 and a condensate drain pipe 10 are provided.

In the area of the mouth of the return water nozzle into the water chamber 4 , the latter is divided into a prechamber 11 , through which the return water first experiences a forced guidance into the heat exchanger tubes 7 forming the heat exchanger.

At firing of the gas burner used for example in the torch receptacle 12, not shown, which up to well over 1,000 ° heated flue gases from the combustion chamber 2 enter the Heizgasführungsraum 3 and penetrate there spaces between the side by side and superimposed heat exchanger tubes 7, the gap combined of a tube bundle Heat exchanger. The ears 7 is scherr water contained is heated in the Wärmetau and begins to circulate due to the inclination of the heat exchanger tubes 7 therethrough and into the water space. 4 The return water entering through the return water pipe 5 first penetrates into the antechamber 11 , which prevents the immediate rise of this return water. Here, the cold return water experiences a forced flow through the lower heat exchanger tubes 7 , in the area of which the heating gases have already cooled down considerably. Above half of the prechamber 11 there is a natural circulation in the water space 4 and in the heat exchanger tubes 7 .

In the embodiment shown in Fig. 3 is seen before that the heating gas guide space 3 tapers in the direction of the exhaust gas outlet. This conical taper serves to keep the speed of the heating gases approximately constant over the height of the heating gas guide space.

In the embodiment shown in Fig. 4, the heat exchanger tubes 7 are not inclined in the heating gas guiding space 3 , but the entire condensing boiler 1 is installed inclined. This also achieves the inclination of the heat exchanger tubes 7 in the use position with simple means.

Reference list

1 condensing boiler
2 burner room
3 hot gas duct
4 water room
5 return water connection
6 flow water connection
7 heat exchanger tubes
8 condensate trap
9 exhaust pipe
10 condensate drain pipe
11 prechamber
12 burner holder

Claims (12)

1.Exhaust gas heat exchanger, in particular condensing boiler with a burner chamber or a heating gas inlet, which opens into a subsequent Heizgasführung room, with a Heizgasführungraum by settling water-carrying heat exchanger and with at least the burner chamber surrounding water chamber, as characterized in that the heating gas duct ( 3 ) of heat exchanger tubes ( 7 ) which are inclined to the horizontal in the position of use and which are connected at the end to the water space ( 4 ). 2. Exhaust gas heat exchange device according to claim 1, characterized in that the heating gas guide space ( 3 ) is flowed through approximately vertically by the heating gases. 3. Exhaust gas heat exchange device according to claim 1 or 2, characterized in that both the burner chamber ( 2 ) and the heating gas guide space ( 3 ) are surrounded by the water space ( 4 ). 4. Exhaust gas heat exchange device according to one of claims 1 to 3, characterized in that the burner chamber ( 2 ) extends approximately horizontally in the position of use and that the heating gas guide space ( 3 ) is arranged below the burner chamber ( 2 ). 5. Exhaust gas heat exchange device according to one of claims 1 to 4, characterized in that the burner chamber ( 2 ) to the heating gas guide chamber arranged below this is open ( 3 ). 6. Exhaust gas heat exchange device according to one of claims 1 to 5, characterized in that the inclination of the heat exchanger tubes ( 7 ) is predetermined by their installation position. 7. Exhaust gas heat exchange device according to one of claims 1 to 5, characterized in that the inclination of the heat exchanger tubes ( 7 ) is predetermined by an inclined arrangement of the condensing boiler ( 1 ). 8. Exhaust gas heat exchange device according to one of claims 1 to 7, characterized in that a return water nozzle ( 6 ) in the lower region of the What serraums ( 4 ) opens and that the return water in the Mün tion area is forced into the heat exchanger tubes ( 7 ). 9. Exhaust gas heat exchange device according to one of claims 1 to 8, characterized in that the water space ( 4 ) for positive guidance of the return water in the mouth region of the return water connector ( 5 ) has a front chamber ( 11 ). 10. Exhaust gas heat exchange device according to one of claims 1 to 9, characterized in that the heating gas guide space ( 3 ) is tapered on the outlet side. 11. A condensing boiler according to one of claims 1 to 10, characterized in that the youngening of the heating gas guide space ( 3 ) is selected such that the flow rate of the heating gas is approximately constant over the height of the heating gas guide space ( 3 ). 12. Exhaust gas heat exchange device according to one of claims 1 to 11, characterized in that the Heat exchanger is formed by a tube bundle which the tube ends on both sides, preferably hexagonal are expanded and at their expansion edges with the Widening edges of the neighboring pipes are welded.