DE2943924A1 - Waste gas heat recovery system - has surface absorber temporarily absorbing condensate and vapour for subsequent discharge - Google Patents

Abstract

The system recovers heat from the waste gases of a gas- or oil-fired heating installation, the hot gases being cooled to an appreciable degree and the heat thus recovered being transferred to a central heating or hot water system, and part of the vapour in the gases being condensed. A surface absorber (8) following the heat-recovery unit temporarily absorbs the condensate mist and a large part of the vapour content below the saturation point. When the burner is shut down, this is discharged to atmosphere via the chimney in a weakened form by a desorption air current, constituting a mixture of air, vapour and pollutant gas.

Description

Wilhelm Krämer - October 23, 1979

Chief engineer Hegelstrasse 2 6902 Sandhausen

"Exhaust gas control device for heating and service water systems"

The invention relates to a method with an exhaust gas recovery device from hot exhaust gases from heating systems, primarily Oil and gas heating systems that are used in the current heating systems Atmosphere is conducted, heat energy wins.

There are exhaust heat control systems known, dia the steam content for the most part condense as it cools.

The disadvantage of this technique is that the condensation also takes SO and other chemical compounds dissolve in the condensate.

Condensates of this type are extremely aggressive and are known to be allowed not be discharged into the sewage system. Nevertheless, there is a risk to the immediate vicinity from condensation mist and Concentrated pollutant gases when strongly cooled exhaust gases are passed through the chimney.

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October 23, 1979 - / -

In addition, there is condensation in the chimney, which causes moisture to soak the chimney mandrel results.

The object of the invention is to avoid all these disadvantages and yet the exhaust heat in large measure with a simple, safe and inexpensive To make the solution usable.

An essential aspect when designing the technical solution the subject of the invention was, inter alia. the retrofitting of existing Heating systems.

The object according to the invention is achieved by the fact that they are still called Exhaust gases 1 after leaving the boiler via a heat exchanger 3 through an open exhaust flap 4 and then via a flow area adsorber 8 are directed. During this process, the exhaust gas temperature cooled to a considerable extent by the highly effective heat exchanger 3.

The resulting condensation mist and a considerable part of the The vapor content is withdrawn from the exhaust gas and absorbed by the adsorbent, which is arranged in layers in layers below one another. The cooled exhaust gas that now enters the chimney has a vapor content that is well below the saturation limit. Condensation can therefore does not take place in the chimney.

A part of the pollutant gases is in the aforementioned process by a corresponding Mixture of adsorbents also withdrawn.

The li / ärmeenerqis, which is steeped in the cooling of the exhaust gases to the heat exchanger 3 _t 15 wK ^. _ν ± τχί derived through water or a conduction pipe and 3G «is described below» fed to the boiler or the brewing water tank. Oil flow direction is according to Figure 1 from 2 to 4, ie from the ^ Ucalten * to the ** & äarrasn ^M side of the heat exchanger, which is also described below.

An inefficient fan 5 runs continuously or intermittently, when the burner is switched off and blows air through the suction cup adsorber » The "dry" oeserction air that passes through

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October 23, 1979

the temperature increase in the boiler room and the flow adsorber is created via the adsorbent and the moisture and harmful gases stored during the burner run in a steam and Harmful gas air mixture passed through the chimney 25, Figure 3 into the atmosphere. The steam content of this is enriched with moisture Desorption air before entry 9 into the chimney is so low that even now no condensation occurs in the chimney.

The exhaust flap 4, Figure 1 bezui. 14, FIG. 2 is closed during the desorption of the flow layer surface dryer. In this method, the runtime / downtime ratio of the burner is used in such a way that the moisture is extracted from the adsorbent at relatively low air temperatures during the downtime, which is several times that of the runtime of the burner. If the burner is switched on for a long time, e.g. B. greater than 50 % bezui. A parallel connection of 2 exhaust gas heat recovery devices according to FIG. 4 is provided for continuous operation. I * lit Figure 2, 3 and 4 are called further embodiments of the exhaust gas heat control device shown according to the invention.

Through an Ulärleitrohr 15 uird with a solid metal cooler

absorbed heat the boiler or the domestic water 16 directly fed.

In a further embodiment, the exhaust flap 14 is not included an electrically operated actuator operated but opened by the gas flow 19 and falls in when the burner is at a standstill the starting position 14 back.

A thin-layer surface adsorber is sketched in item 13. At this

Execution, consisting of large-area perforated sheets with thinly poured, Coarse-grained adsorption granules with = 1 floors and large-volume spaces to even out the flow. This execution requires more powerful fans. It is therefore for Exhaust gas heat recovery systems are provided, which from the outset in the Heating boilers are integrated.

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October 23, 1979 - / -

The desorption also takes place via an underperforming one Fan 5 or if the boiler is coupled to a heat pump is with the exhaust air of an air, water heat pump Figure 3, 34. Such a combination is particularly advantageous because in the heat pump part of the vapor content of the sucked in air condenses and: " after rewarming in the boiler room. in the · flow or thin-layer surface adsorber is heated and therefore the relative humidity of this desorption air is particularly low effectively removed the stored moisture from the adsorbent.

The adsorbent used in this process is its mixture from silica gel, alumina gel and molecular sieves, which are suitably made remove steam, condensation mist, pollutant gases from the exhaust gas and how described, can be desorbed again by a gentle stream of atmospheric air (8, 13).

This ensures safety, especially when the burner is running is, the exhaust flap 14 is coupled to a wind vane relay, which ensures via a drop flap relay that the burner is only at opened exhaust flap continues to run after ignition. If the exhaust flap 14 does not go to position 19 when the burner is running, the Burner forcibly switched off. Analogue to this is also the energy-driven one Exhaust flap 4 and the fan 5 coupled to the burner.

The check valve (flap) 6 is used to ensure that the case of non-function of the fan S or with intermittent operation of 5 one Huck flow is blocked.

The insulating sheaths 7 Figure 1 beaw. 18, Figure 2 prevent during operation together with the exhaust flaps 4 respectively. 14 at standstill the UJarma drain into the Heizungsraiiss teezsi, into the chimney and with it into the atmosphere.

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October 23, 1979 -A -

In addition to the regeneration of the adsorbent, the fan 5, FIG. 2, also presses the exhaust gas non-return valve 14 when the burner is at a standstill. This also causes the boiler to cool down internally through the lift of the air in the chimney prevented and the overall efficiency especially with longer Significantly increased downtimes. The fuel saving, which is achieved by an exhaust gas heat recovery device connected downstream of the boiler, is = 30 %,

Figure 3 shows which preferred hydraulic circuits to derive the thermal energy obtained with the exhaust gas heat recovery device bezu. the introduction into the heating or Customized water system are to be carried out. The each in the Temperature at the lowest point of the circuits and the exhaust gas heat recovery device interposed at points 2 and 4. In Figure 1 it is shown that the inflow into the Heat exchanger 3 takes place at point 2, at which the bJärmegeuinnung used exhaust gas has reached its lowest temperature.

Through this direction of flow, in connection with the star-shaped Fins 10 of the heat exchanger 3 which is densely occupied with longitudinal ribs in the exhaust gas flow direction, an intensive heat transfer from the exhaust gas to the flowing water from 2 to 4 or else in a very small space with a Uärleitrohr 15 the heat energy gained to the heating or

Domestic hot water circuit supplied.

FIG. 3 shows the preferred circuits: The exhaust gas heat recovery device is interposed in the boiler return 26. If a service water ring is available, the exhaust gas heat recovery device ¹ ! be interposed in the return. In the case of a bivalent heating system - oil or gas heating with heat pump - interconnection according to item 28 with disconnection of the water inlet line

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October 23, 1979 - 0 -

The technical solutions shown according to the invention in FIGS. 1, 2, 3 preferably deal with common oil and gas heating systems with intermittent operation, ie with duty cycle rates of = 50 %.

In the case of systems with a high duty cycle or continuous operation, so the parallel connection of 2 exhaust gas heat recovery devices necessary. Via an exhaust gas switchover flap 36, FIG. 4, the hot ' Exhaust gas switched over in certain time or start-up cycles and the side 24 not exposed to exhaust gas with a common fan regenerated as described above. The outlet openings 9, Fig. are guided into the chimney 25 individually or together. In Figure 1 it is further shown that the flow layer surface adsorper maintenance can be carried out through a side wall which can be removed for service purposes »an indicator 20, at the lowest point of the adsorber cultivated, shows eirs ~; possible moisture breakthrough in the adsorber. By this precaution can, if necessary, the adsorbent 8, 13 be replaced in good time.

2Ö / 020S

Claims (1)

Wilhelm Krämar on October 23, 1979 Chief engineer Hegelstrasse 2 6902 Sandhausen Expectations 1. h / experienced for generating energy from the still hot exhaust gases from oil and gas heating systems, in which the hot gases are considerably cooled and the energy obtained is fed to the heating or domestic water circuit and part of the steam contained in the exhaust gas is condensed, characterized in that that through a downstream 5trömungsschichtflächenadsorber (8) the resulting condensate mist and a large part of the steam content below the saturation limit as well as harmful gases are temporarily adsorbed that when the burner is idle by a stream of desorption air as a mixture of air, steam, pollutant gas in a diluted form the chimney into the atmosphere. 2. Exhaust heat recovery device according to claim 1, characterized marked 130020/0209 Oct. 23, 1979 - 2 - 2. exhaust heat control device according to claim 1, characterized characterized in that the exhaust gas flow is guided in a neandering manner over the flow layers downwards and from the lowest floor goes vertically up to the outlet nozzle (9) 3 · Exhaust heat recovery device according to claim 2 »thereby characterized in that the floors of the flow schichtflächenadsorbers a thin layer of adsorbent made of silica gel, alumina gel and Molecular sieves is occupied. 4. exhaust heat control device according to one of claims 1 to 3, characterized in that between "heat exchanger ^ 3) (15) and the Strümungsschichtflächenadsorber (8) an actuator-driven exhaust flap is arranged. 5. exhaust gas control device according to one of claims 1 to 3, characterized in that a gravity and air pressure actuated Non-return flap (19), (14) between the heat exchanger and the flow layer surface adsorber arranged, and BEZW when the burner is at a standstill. closes when the fan (5) is in operation. 6. A bgasuärmegeujinnungs device according to one of claims 1 to 5, characterized in that for regeneration of the flow layer surface dryer with an atmospheric air stream (5) after the Exhaust flaps is supplied. 7 * exhaust gas recovery device according to claim 6, characterized characterized in that a non-return valve (6) blocks an exhaust gas flow against the fan {5). 8 · Process for heat recovery from hot exhaust gases, from oil and Gas heating systems according to Claims 1 to 6, characterized in that - ■ the circuit water at the lowest temperature is supplied to the exhaust gas outlet side (2) of the heat exchanger (3). 9 · Exhaust gas control device according to claim β, characterized characterized in that the heat exchanger (3) consists of a star-shaped, longitudinal ribs, flooded with water and an axial wing in exhaust gas flow direction ba ± ^ / η? 0 9 October 23, 1979 - 3 - 10. exhaust gas control device according to claims 8 and 9, characterized in that a metal profile (10) in solid design encased a Uärleitrohr. 11. exhaust gas guiinnungsv / orrichtüng according to claims 9 and 10, characterized in that the housing of the heat exchanger consists of one Extruded profile that is closed at the ends. 12. exhaust gas control device according to claim 1, characterized characterized in that, as an alternative to claim 2, large-area adsorber layers (13) with '= - one level the heat exchanger (3) and (15) are downstream. 13. Process for the generation of heat energy from hot exhaust gases of oil and gas heating systems, characterized in that to / ei exhaust gas heat regulation devices according to Figure 1 and / or 2 in parallel are switched and alternately gain heat energy from the exhaust gas and feed it to the heating system and with an air stream from the Atmosphere alternately one of the exhaust gas heat recovery devices regenerate. 14. Exhaust heat recovery device according to claims 4 to 6, characterized in that the exhaust flap (4) or non-return flap (14) settle fans (5) are electrically locked, that if not or Malfunction the heating system (27) switched off or the start-up of the Burner is blocked. 15. exhaust gas control device according to claim 2 or 12, characterized in that the detachable side wall (11) all floors of the flow or thin-layer surface adsorber (8) and (13) covered over the whole area. 16. Exhaust heat recovery device according to claims 1, 2 or 12, characterized in that a moisture indicator on the lowest Place of the flow or thin-layer surface adsorber is arranged. 1 30020/0209 October 23, 1979 - 4 - 17 · Exhaust gas heat recovery device according to claims 8 to 11, characterized in that the heat exchanger (3), (15) is encased by a heat insulating body which is rotationally symmetrical at the point of exhaust gas outlet and which is shaped underneath at the exhaust gas outlet. 18. An exhaust gas co-ordination device and according to claim 5, characterized in that the non-return flap (14) is arranged obliquely downwards between = 0 ° and 15 ° to the vertical. 130020/0209