WO1996036840A1 - Chimney system for a condensing boiler - Google Patents

Abstract

The invention relates to a chimney system for a condensing boiler with at least one flue gas pipe (20) and at least one air pipe (10) which are arranged to surround each other in such a way that the outer wall (22) of one pipe (20) forms a surrounding wall for the other (10). Such an arrangement is also referred to as an air-flue gas chimney and is used in small heating plants to preheat the air of combustion supplied to the condensing boiler. In order also to make it possible to humidify the air of combustion using simple constitutive means and thus to raise the dew-point of the water vapour in the flue gas and allow better use of condensation enthalpy, according to the invention there are condensate collector plates (28) on the flue gas side of the shared wall, in the region of each condensate collector plate there is at least one bore (34) connecting the flue gas and air sides and there is a condensate distributor (36) on the air side in the region of each bore. The disributor preferably consists of a mat (36) with a capillary action with which the wall (22) on the air side is lined. The condensate derived from the flue gas is thus effectively evaporated on the air side of the arrangement.

Description

Chimney system for a condensing boiler

The invention relates to a chimney system for a condensing boiler, with at least one exhaust pipe and at least one air pipe, which are arranged in such a way that the outer wall of one pipe forms an inner wall of the other pipe (air chimney).

The combustion of fossil fuels in heating systems mainly produces CO ₂ and water vapor. The energy content of the fuel is usually indicated by the calorific value, which results from the enthalpy difference of the products of the

Combustion process and the input enthalpies of the fuel and the supplied combustion air results. The calorific value of a fuel is higher than the calorific value by the condensation enthalpy of the gaseous water vapor in the exhaust gas. Boilers in which the enthalpy of condensation contained in the flue gas

Water dispenser is used are referred to as condensing boilers. Since the reference value for calculating the efficiency of a heating system is usually based on the calorific value, condensing boilers can achieve efficiencies> 100%.

In heating systems in which the enthalpy of condensation of the gaseous water vapor is to be used, the exhaust gas is passed through a heat exchanger in which the water vapor condenses and the enthalpy of condensation increases the energy content of the heating medium flowing around, generally water. Such systems generally have the problem that the return temperature of the heating water must be below the water vapor dew point in the exhaust gas in order to effect the condensation effect. In temperate climates, the return temperature of the heating water is only so low in the transition period, ie in spring and autumn that the water vapor contained in the exhaust gas can condense out. In winter, on the other hand, when the energy consumption is greatest and therefore an increase in efficiency is most desirable, the temperature of the heating water must be high enough to achieve a sufficient heating effect, so that the return temperature of the heating water is also comparatively high and in any case too high to allow for the heating effect Bring water vapor to condense.

Since it is difficult to lower the return temperature of the heating water for obvious reasons, attempts have been made to increase the water vapor dew point by increasing the partial pressure of the water vapor in the exhaust gas. For this purpose, so-called water vapor pumps have been developed, for example from the

EP-OS 0 425 363 are known. In such a device, the condensate collected is conveyed by means of a pump to a heat exchanger, in which the exiting exhaust gas preheats the supplied combustion air. In addition to the preheating of the combustion air, the collected condensate is injected into the air flow, so that the partial pressure of the water vapor in the air rises and thus also the partial pressure of the water vapor in the exhaust gas leaving the boiler. In this way, the water vapor dew point in the exhaust gas is shifted upward, so that condensation and thus a recovery of the condensation enthalpy of the water vapor contained in the exhaust gas is made possible even at comparatively high temperatures of the process water or heating medium. Furthermore, heat exchangers have become known in which the wall between the combustion air to be preheated and humidified and the exhausting flue gas (exhaust gas) consists of an absorbent technical fabric. In the case of these so-called porous heat exchangers, the condensation water arising from the water vapor soaks in the flue gases the tissue that forms the wall alone, migrates through the pores of the tissue and becomes water vapor in the combustion air. Since the exhaust gas contains only small amounts of water vapor after flowing through the heat exchanger operated with the refluxing heating water, accordingly only a small amount of condensed water is formed, so that especially when starting up such a plant, it is not guaranteed that the tissue that alone the wall of the Heat exchanger forms, is soaked with condensed water overall. However, this is a prerequisite for the proper functioning of this device, because otherwise the CO ₂ contained in the combustion exhaust gases will force into the supplied combustion air due to the partial pressure drop and, on the other hand, oxygen (0 ₂ ) from the combustion air will be forced into the exhaust gas. In order to ensure that the wall of the porous heat exchanger consisting of a fabric is gas-tight, it is therefore necessary to install a condensate pump, as in the previously described device, which pumps condensate to the fabric in sufficient quantity.

The known devices which humidify the combustion air with condensate obtained from the exhaust gas therefore have the disadvantage that they require a condensate pump which is susceptible to faults and other complex design measures which are used in simple condensing boilers because of the high investment sums to forbid.

The invention is therefore based on the object of making it possible, using simple constructional means, to humidify the combustion air supplied to a condensing boiler with condensate obtained from the exhaust gas. Starting from a generic

Chimney system for a condensing boiler, as it is already known, the solution according to the invention consists in that arranged on the exhaust side of the common wall, that at least one bore connecting the exhaust side to the air side is arranged in the region of each condensate collection plate, and that a distribution device for the condensate is arranged on the air side in the region of the bore.

In the context of this description, the term "sheet metal" is used to describe a component, regardless of whether it is made of a metallic material or not. For example, the condensate collecting sheets according to the invention can also be made from a plastic. In particular, they can also be formed in one piece with the wall on which they are arranged.

By means of the condensate collecting plates provided according to the invention on the flue gas side of the common wall, the condensate deposited on the wall, which runs down the wall due to gravity, is collected and passed through the bore to the air side of the chimney system. Since the amounts of condensate which are conducted in this way to the air side of the chimney system are comparatively small, care must be taken to ensure that they are distributed on the air side of the common wall to form a film of the largest possible area in order to prevent evaporation in the bypassing, humidified and heated combustion air.

For this purpose, a distribution device is provided, which is arranged in the region of the respective bore. Various constructive designs of the distribution device, which are in turn inventive, are conceivable. According to a particularly preferred embodiment, the distribution device consists of a fleece or fabric with a capillary effect, with which the wall is covered on the air side. The individual hygroscopic fibers that make up the fleece or the fabric suck the condensate out of the mouth area in the wall provided hole and distribute it over a large area, so that good evaporation is guaranteed.

Another embodiment of a distribution device according to the invention provides individual baffles which are arranged in the region of the mouth of the respective bore or bores. It can in particular be provided that the baffles are bowl-shaped in the region of the bore. The shell-shaped baffle plates preferably have overflow incisions at their upper peripheral edge, so that the condensate flowing through the bore, which is distributed within the shell, runs over the edge at various points on the peripheral edge of the shell and a distribution effect is thereby produced . The partial flows flowing through the individual overflow incisions likewise lead to good to complete wetting of the air-side outer surface of the common wall between the air pipe and the exhaust pipe, so that a good evaporation effect is ensured.

A combination of the two embodiments is also conceivable. Thus, in the embodiment described last, to support the wetting, the air-side surface of the common wall can in each case be lined with absorbent fleece below the guide plates.

In order to increase the total area available for evaporation and the heat transfer areas within the heat exchanger, it can be provided in particular to arrange a plurality of parallel-connected exhaust gas pipes of small diameter in a common air pipe of larger diameter.

Further preferred embodiments are described in the subclaims. The invention is described in more detail below with reference to exemplary embodiments shown in the drawing. The drawing shows:

Figure 1 - a chimney system according to the invention, in which the distribution device is formed as an absorbent fleece, and

Figure 2 - a chimney system according to the invention, in which the distribution device is formed by shell-shaped condensate baffles.

The chimney system for a condensing boiler shown in FIG. 1 consists of an outer air pipe 10 with a circular cross section, in which an inner exhaust pipe 20 with a likewise circular cross section is arranged concentrically. The wall 22 of the exhaust pipe 20 simultaneously forms the inner wall of the air pipe 10 and thus represents a common wall of both the air pipe and the exhaust pipe. The smoke or exhaust gas originating from a boiler (not shown) flows through a likewise not shown Heat exchanger in which it releases a large part of its entrained enthalpy of entrainment to the heating medium. The exhaust gas, which still contains water vapor, then flows through a supply nozzle 24 into the exhaust pipe 20 and rises to the top of the exhaust, not shown. The exhaust gas flowing past the wall 22 is cooled and the heat passing through the wall 22 heats up the combustion air flowing through the air pipe 10 in the opposite direction. The air flows through a nozzle 26 and is conducted from there to the boiler.

The rising exhaust gas is cooled down on the wall 22 to such an extent that condensation occurs there and a condensate film flows downward on the wall 22 due to the force of gravity. On the wall 22 are spaced apart on the exhaust side Condensate collecting plates 28 are arranged, only one of which is shown in FIG. 1. The annular condensate collecting plate 28 is provided with a concave cross section in a radially placed section towards the wall 22, so that an annular collecting space 30 for the condensate 32 is formed. In the circumferential area of the condensate collecting plate 28, bores 34 are regularly distributed in the wall 22 through which the accumulated condensate 32 can flow from the exhaust side to the air side of the wall. The air side of the wall 22 is covered with a fleece 36, which consists of hygroscopic fibers.

The combustion air flowing past the fleece 36 through the air tube 10 evaporates the condensate, which is distributed over a large area, and is thus moistened. Without a distribution device in the form of the fleece 36, condensate, which has flowed through a bore 34 onto the air side of the wall 22, would flow downward in the form of a thin trickle following the influence of gravity. Since the ratio of liquid surface to liquid volume would then be very unfavorable, the desired effect of humidifying the air would only be achieved very incompletely.

Both the air pipe 10 and the exhaust pipe 20 are each closed at their lower ends and each have a siphon system 38 or 40 in order to discharge excess condensate.

FIG. 2 shows an alternative embodiment of the distribution device, in which shell-shaped condensate baffles 42 are arranged on the air side of the common wall 22. The condensate 32 flows here through the holes 34, which are also distributed uniformly in the circumferential direction in the wall, whereupon a hydrostatic equilibrium is established, so that the level of the condensate in the annular shells formed on the exhaust gas side of the wall and on the air side of the wall is equally high (due to pressure differences in exhaust gas and Air, there may also be level differences). The level of the condensate in the air-side shell 42 rises until overflow incisions 44 are reached which are arranged in the upper edge 46 of the shell or the condensate baffle 42. Because of the large number of overflow incisions 44, the condensate 32, 32 'is distributed. This also ensures that the largest possible surface is wetted for a given condensate volume, so that the air flowing past causes complete evaporation and is in turn moistened.

Both in FIG. 1 and in FIG. 2, an exhaust pipe 20 is arranged concentrically in an air pipe 10. However, it is also conceivable to arrange a plurality of exhaust pipes 20 connected in parallel in a common air pipe 10 of larger diameter. In this way, the total area available for heat and mass transport is increased with the same flow cross-sections for the exhaust gas being drawn off.

Claims

Expectations

1. chimney system for a condensing boiler, with at least one exhaust pipe (20) and at least one air pipe (10), which are arranged surrounding each other in such a way that the outer wall (22) of one pipe (20) an inner wall (22) of the other pipe ( 10) forms (air exhaust chimney), characterized in that condensate collecting plates (28) are arranged on the exhaust side of the common wall, that at least one bore (34) connecting the exhaust side to the air side is arranged in the region of each condensate collecting plate , and that a distributing device (36, 42) for the condensate is arranged on the air side in the region of each bore.

2. Chimney system according to claim 1, characterized in that the distribution device consists of a capillary effect fleece (36) or fabric with which the wall (22) is clad on the air side.

3. chimney system according to claim I, characterized in that the distribution device for the condensate consists of baffles (42) arranged on the air side of the wall (22).

4. chimney system according to claim 3, characterized in that the guide plates (42) in the region of the associated bore (34) are cup-shaped.

Chimney system according to claim 4, characterized in that the bowl-shaped guide plates (42) have overflow incisions (44) for the condensate at an upper edge (46).

6. Chimney system according to one of the preceding claims, characterized in that the air pipe (10) is designed concentrically surrounding the exhaust pipe (20).

7. chimney system according to claim 6, characterized in that air (10) and exhaust pipe (20) have circular cross sections.

8. chimney system according to any one of the preceding claims, characterized in that on the inside of the exhaust pipe (20) a plurality of annular condensate collecting plates (28) are staggered in height one above the other.

9. chimney system according to claim 8, characterized in that the condensate collecting plates (28) in a radial plane of the

Exhaust pipe (20) have a cross-section (30) which is concavely shaped towards the wall (22) of the exhaust pipe.

10. Chimney system according to claim 8, characterized in that the condensate collecting plates (28) have the geometric basic shape of a conical section.

11. Chimney system according to claim 8 or 9, characterized gekenn¬ characterized in that in the region of each condensate collecting plate (28) a plurality of holes (34) directed towards the air side of the wall (22) are arranged uniformly distributed in the circumferential direction.

12. Chimney system according to one or more of the preceding claims, characterized in that a plurality of parallel-connected flue pipes (20) of smaller diameter are arranged in an air pipe (10) of larger diameter.

13. Chimney system according to one of the preceding claims, characterized in that the exhaust pipe (20) is closed at its lower end and is connected to a siphon system (40) for discharging excess condensate.

14. Chimney system according to one of the preceding claims, characterized in that the air pipe (10) is closed at its lower end and is connected to a siphon system (38) for discharging excess condensate.

15. Chimney system according to one or more of the preceding claims, characterized in that the condensate collecting plates and / or optionally the condensate guiding plates are formed in one piece with the wall on which they are arranged.

16. Use of a chimney system with the following features for a condensing boiler:

- Double-shell structure with at least one exhaust pipe

(20) and at least one air pipe (10), which are arranged surrounding one another in such a way that the outer wall (22) of one pipe (20) forms an inner wall (22) of the other pipe (10) (air flue ),

- The common wall is designed so that heat and mass transfer from the exhaust side to the air side is made possible.