DE3228885A1 - Plant for recovering energy from exhaust gases from flue gases emitted from combustion devices, and for purifying exhaust gas - Google Patents

Abstract

In a plant for recovering energy from exhaust gases from combustion devices, these gases are simultaneously fed for purification via a heat exchanger (20) to heat heating water or utility water and are fed from this to a flue gas scrubber (30) and passed to a conventional exhaust gas stack composed of a galvanised metal tube, the condensate withdrawn from the flue gas scrubber (30) being neutralised in a device (40), so that the purified and neutralised condensate can be fed as scrubbing liquid to the flue gas scrubber (30) and/or can be fed directly to an existing waste water system, without, as a result, producing any environmental damage. <IMAGE>

Description

The invention relates to a plant for recovery

of energy from high or low temperature exhaust gases of flue gases emerging from combustion equipment and for exhaust gas cleaning.

When heating oil, gas or solid fuels are burned by falling below the dew point condensate, in connection with sulfur or chlorides has a corrosive effect. These are mainly sulphurous acids, sulfuric acid or hydrochloric acid can also be formed. Because of the aggressiveness of the condensate, it cannot be discharged directly into the sewage system. It it is therefore necessary to collect the condensate in corrosion-resistant containers and then have it removed periodically.

It is also known to increase the efficiency of combustion systems To extract so much energy from the flue gases that the R, also gas temperature is only low is above the dew point temperature. There is a risk that in particular the dew point temperature is undershot in predominantly partial load operation with the result that the water contained in the flue gas condenses and the chimney damaged. There is also the risk that the chimney will no longer lift sufficient to discharge the flue gas through the chimney by natural draft, so that, unless a boiler with an overpressure burner is used, additional Measures such as using a chimney fan or one special induced draft system are required.

Added to this is the fact that in the case of firing systems, which are of an order of magnitude As around 1500 kW and run on light heating oil, the emission of pollutants is much greater than when using natural gas, with an economy is initially only given with oil. The use of O1 as a fuel has however the disadvantage that with regard to the smoke gas discharge devices, such as chimneys, high requirements are imposed insofar as extremely tall chimneys are used have to.

It is therefore the object of the present invention to provide a system for Recovery of energy from flue gases from combustion equipment To create flue gases in which the order of magnitude from about 1500 kW and the disadvantages resulting from combustion systems operated with light heating oil are avoided that also works economically with conventional chimneys the remaining exhaust gas only contains carbon dioxide and nitrogen with a little water and which is also environmentally friendly, as the neutralized condensate can be fed to conventional sewage systems.

This task is achieved by the characterizing part of the claim 1 and of claim 2 specified features solved.

While with combustion systems from 1500 kW, those with light heating oil are operated, there is a high level of pollutant emissions and those with extremely high Chimneys have to work to avoid excessive environmental pollution, the system according to the invention enables the exhaust gases to be cleaned from firing devices emerging flue gases insofar as the remaining exhaust gas released into the environment no pollutants, just carbon dioxide and nitrogen with a little water contains. All pollutants are removed by switching on the flue gas scrubber, while the acidic water (condensate) is treated in this way by the neutralization device is that the condensate can be discharged into the sewer system without it this leads to environmental pollution. A high profitability of the system is given insofar as there are no special chimneys and no extreme high chimneys are required, but the existing masonry, otherwise insufficient chimneys, as well as chimneys made of galvanized sheet metal pipe apply in the present case. As the released, from the smoke gases originating exhaust gases no more pollutants and in particular no more sulfur oxide contain no damage to the chimneys and neither is It is necessary that there are corrosion-resistant chimneys. Simultaneously the system yields high energy savings.

After neutralization, the condensate obtained can be used directly in the existing condensate Sewer systems are discharged without having to go to the sewers and sewers damage is to be feared.

The exhaust gas coming from the furnace flows through or through several heat exchangers and from these passes into a scrubber with a subsequent Neutralization of the acidic water. The rest of the exhaust gas can be used in a reheater be performed, but this is not absolutely necessary. It is only beneficial when the exhaust gas flows into an existing, non-corrosion-resistant chimney is directed. Since the exhaust gas is absolutely saturated when it leaves the scrubber, would condensate formation and thus further condensation without increasing the temperature Sooting of a brick chimney or a chimney with a ceramic lining come, which is particularly disadvantageous if the chimney was previously flue gas from combustion equipment, which are operated with solid fuel or oil has been supplied. Is against a new exhaust system, e.g. Post-heating is provided in completely new systems of the exhaust gas is not required, as a pipe made of galvanized sheet metal, aluminum or stainless steel can be used, although other suitable materials are also possible can come.

For systems that are operated with so-called saving boilers, the So work with exhaust gas temperatures of a maximum of 1500C, it is an advantage if the exhaust gas is fed directly into the scrubber and the acidic water from the scrubber, that leaves this with about 700C to 900C, then serves to heat heating or Domestic water through a heat exchanger of an appropriately designed system. In this system there is no fan in connection with an overpressure burner on the boiler respectively.

Flue gas fan required because of the resistance of the scrubber from the burner is overcome. A reheating of the exhaust gases is advantageous here, too to avoid condensation and to obtain additional buoyancy.

It is particularly advantageous that the systems, with the exception of the boiler system, can be installed in a transportable container or can be accommodated in it, see above that such a compact system can be used wherever larger Chimney repairs need to be carried out only in conjunction with a longer shutdowns of the chimney are possible, or in the case of district heating plants that because of expansion over a period of two to three years with such Container power plant in connection with a temporary chimney, the must be up to 50 m high depending on the location of the power plant.

In such cases, the system with the flue gas scrubber is sufficient of neutralization. A heat recovery is then not required.

Further advantageous refinements of the invention can be found in FIGS Subclaims.

The invention is illustrated schematically below with reference to the drawing shown systems for the recovery of energy from exhaust gases from combustion equipment escaping flue gases and for exhaust gas cleaning explained in more detail, namely shows F i g. 1 a system in which the exhaust gases coming from the furnace are a Heat exchanger supplied with a downstream scrubber and neutralization device and F i g. 2 a system in which the coming from the furnace Exhaust gases are fed directly to a gas scrubber, to which a heat exchanger and a Neutralization device are connected downstream.

In the system shown in Fig. 1 for the recovery of energy Exhaust gases with high temperatures above 150 ° C get them off the firing device 10 via an exhaust pipe 11 into one or more heat exchangers, which are indicated at 20. Heating medium flowing through the heat exchanger 20 or domestic water is passed through the heat exchanger by means of the hot exhaust gas heated.

The exhaust gas flows from the heat exchanger 20 via a feed line 21 with a th flue gas fan 22 into one Flue gas scrubber 30, the exhaust gas outlet nozzle 32a of which has a flue gas discharge 32 is connected, which is in a brick chimney, not shown in the drawing or a chimney consisting of a galvanized sheet metal pipe opens, wherein A reheater 35 can be installed in the exhaust pipe 32.

The flue gas scrubber 30 is processed condensate, possibly also mixed with fresh water, supplied, which will be discussed in more detail below will.

The flue gas scrubber 30 is at the bottom with a condensate discharge line 31, in which a control valve 34 designed as a solenoid valve is arranged and which opens into a neutralization device 40.

A line 41 with a opens into the neutralization device 40 Shut-off valve 45. Fresh water is supplied to the neutralization device 40 via this line 41 or neutralized condensate supplied. The supply of the neutralization medium, such as lye or the like., takes place via a feed line 51 in which a metering device 52 is arranged and with a feed pump not shown in the drawing can be provided. This supply line 51 is connected to a storage container 50 for the neutralization medium in connection, which is provided with an agitator 53 is.

The neutralization device 40 itself is provided with an agitator 42, a Float switch 43 and a pH value control and measuring device 44 are provided. the The neutralized and cleaned condensate is monitored by means of this pH control and measuring device 44, which with a pen, printer or the like. tied together can be and via which the respective pH values of the condensate can be monitored. The pH value monitoring can be done with a program control unit, not shown in the drawing are connected, via which the shut-off valves provided in the system each are controllable according to the required work processes.

The neutralized condensate comes out of the neutralization device 40 via a discharge line 56 with a feed pump 57 arranged in this into a Intermediate container 60, which is provided with a float switch 63 and the above a feed line 61 with an interposed feed pump 67 with the flue gas scrubber 30 is connected and also has a drain line 64. Above the feed line. 61 is the supply. of the cleaned condensate in the Flue gas scrubber 30, so that the flue gas scrubber 30 purified condensate as fresh water can be fed. A fresh water supply is then only required to fill up the missing amount of fresh water to a target value.

Above the derivation 64 is a derivation of the purified and neutralized Condensate in an existing sewage system 68 possible. Also in the area of derivation of the cleaned and neutralized condensate into the existing sewage system 68, a pH value regulating and measuring device indicated at 69 can also be provided so that the condensate to be drained is checked again.

With the system according to FIG. 1, this is done by the furnace incoming exhaust gas is fed to at least one heat exchanger 20, via the brewery and Heating water can be heated up. The exhaust gas then passes from the heat exchanger 20 in the flue gas scrubber 30. The cleaned exhaust gas is in the upper area of the flue gas scrubber 30 withdrawn, while the accumulating condensate of the neutralization device 40 is fed. This is done by adding a neutralization medium, such as Lye or the like., The neutralization of the condensate, which with the interposition an intermediate container 60 then in cleaned and neutralized form in the flue gas scrubber 30 is used and if use in the flue gas scrubber 30 is not required the cleaned and neutralized condensate can go straight to the sewage system be derived.

The system shown in Fig. 2 is used to recover energy and for the purification of exhaust gases from combustion equipment that have a maximum Have a temperature of about 1500c.

In this embodiment of the system, the exhaust gas comes from the furnace 100 in-line flue gas scrubber 130 via an exhaust pipe 111. This flue gas scrubber 130 is provided with an exhaust gas outlet connection 132a to which a discharge line is attached 132 connects to a brick chimney, not shown in the drawing or a chimney consisting of a galvanized sheet metal pipe. In these A reheater 135 can be arranged on the exhaust gas discharge line 132.

The flue gas scrubber 130 has a condensate discharge line on the bottom 131, which leads to a neutralization device 140. In this condensate drain line 131 a shut-off valve 133 is arranged, which is designed as a solenoid control valve is. In addition, one in the drawing cannot enter the condensate discharge line 131 The feed pump shown must be switched on.

The neutralization device 140 corresponds to that for the system according to FIG. 1 described neutralization device 40 formed and consists from a container with an agitator 142, a float switch 143 and a pH value control and measuring device 144.

The neutralization device 140 is connected to a supply line 141 with a shut-off valve 145 in connection. Via this line 141, the neutralization device Fresh water or neutralized and cleaned condensate is supplied.

The neutralization medium, such as lye or the like, is supplied from a storage container 150 with an agitator 153 via a supply line 151 with a metering device 152 arranged in this and one possibly also provided Feed pump.

The flue gas scrubber 130 also has a further condensate discharge line 136, in which a feed pump can be switched on. This condensate drain pipe 136 leads to a heat exchanger via which the heat exchanger is passed Domestic or heating water can be heated. The withdrawn from the flue gas scrubber 130 Condensate has one for heating domestic or heating water in the heat exchanger 120 required temperatures. However, there is also the option of instead a single heat exchanger to arrange several heat exchangers one behind the other.

The condensate passes from the heat exchanger 120 via a feed line 121 into the neutralization device 140 and is mixed here with that via the Discharge line 131 supplied condensate in the container of the neutralization device 140

The neutralization device 140 is provided with a discharge line 156 provided with intermediate feed pump 157. Via this drain line 156 the cleaned and neutralized condensate enters an intermediate container 160, from which the purified and neutralized condensate via a line 161 with intermediary Feed pump 167 is fed to the flue gas scrubber 130 is, so that the flue gas scrubber 130 with cleaned and neutralized condensate is operated.

A fresh water supply to the flue gas scrubber 130 is then only necessary, if missing fresh water quantities are to be supplemented to a target value.

The intermediate container 160 is provided with a float switch 163, Via which the liquid level in the container 160 is kept constant.

The intermediate container 160 is also provided with a discharge line 164, about the cleaned and neutralized in the intermediate container 160 Condensate can be discharged directly into an existing neF sewage system 168. .In the derivation area of the purified and neutralized condensate in the sewage system 168 can still a further pH value monitoring device 169 can be provided, which in the same In the same way as the pH value control and measuring device 144 in the neutralization device 140 with a printer, a writer or the like. can be connected via which the the respective pH values of the condensate can be monitored. Also this pH value rule and Measuring devices 144, 169 can work together with a program switching mechanism provided, if the condensate is insufficiently neutralized, a corresponding feed of fresh water and neutralization medium to be able to control, with this Program switch, which is not shown in the drawing represents-is, at the same time the shut-off valves provided in the system can be controlled, namely each depending on the respective workflow.

The system shown in FIG. 2 and described above represents represents a further embodiment of the system shown in Fig. 1 and is special suitable for exhaust gases with low temperature. In this system according to claim "l" die.Abgase fed directly to the ~ smoke gas scrubber 130. Part of the in the flue gas scrubber 1.30 accumulating condensate is fed to the neutralization device 140, while the other part with the interposition of at least one heat exchanger 120 is also fed to the neutralization device 140. The so prepared i.e. neutralized and cleaned condensate can then go directly into the flue gas scrubber 130 can be used or discharged into the front sewer system without In the latter case, there may be environmental damage. - Both the system according to Fig. 1 and the system according to FIG. 2 can - with regard to their system parts, such as heat exchangers 20,120 ,, flue gas scrubber 30,13O, neutralization device 40,140, intermediate container 60, 160 and the n supply lines, discharge lines, control valves required for this and monitoring devices can be housed in a container, which is shown in FIG 90 and is arranged at 190 in FIG. 2. This is the deise one compact energy recovery and exhaust gas cleaning system available at any time can be connected to existing firing devices 10.110 if, for example Repairs to the existing chimney or changes are to be made.

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Claims (4)

T i t e 1: Plant for recovering energy from exhaust gases from Combustion equipment and for exhaust gas purification. Plant for the recovery of energy from high, in particular Exhaust gases from furnaces with temperatures above IjO "C emerging flue gases and for exhaust gas cleaning, characterized in that the The system consists of the following features. a) The exhaust pipe (11) of the furnace (10) opens into at least one heat exchanger (20) for heating heating or service water, via a supply line (21) with a Pauchaasqebläse arranged in this (22) is connected to a flue gas scrubber (30) whose bottom-side condensate discharge line (31) is connected to a neutralization device (40), b) which has an agitator (42), a float switch (43) and a pH value control and eating device (44) having neutralization device (40) is with a supply line (41) for fresh water or neutralized condensate, a feed line (51) for Lye in which a metering device (52) is arranged and which is in a lye storage container (50) opens, and a discharge line (56) with a feed pump arranged in this (57) provided for the neutralized condensate c) the discharge line (56) for the neutralized condensate flows into a neutralized condensate collecting, with an intermediate container (60) provided with a float switch (63), which is connected via a supply line (61) connected to the flue gas scrubber (30) with the feed pump (67) switched on and has a discharge line (64), and d) the exhaust gas outlet nozzle (32a) of the flue gas scrubber (30) opens via a flue gas discharge line (32) into a conventional, from a galvanized Sheet metal pipe existing exhaust chimney. 2. Plant for the recovery of energy from lower, in particular Exhaust gases from combustion equipment at temperatures below 1500C emerging flue gases and for exhaust gas cleaning, characterized in that the The system consists of the following features: a) The exhaust pipe (111) of the furnace (100) opens into a flue gas scrubber (130), whose bottom-side condensate discharge line (131) is connected to a neutralization device (140), b) which is an agitator (142), a float switch (143) and a pH value control and measuring device (144) having neutralization device (140) is with a supply line (141) for fresh water or neutralized condensate, a supply line (151) for lye, in which a metering device (152) is arranged and which is in a lye storage container (150) opens, and with a discharge line (156) with a feed pump arranged in this (157) provided for the neutralized condensate, c) the flue gas scrubber (130) has another condensate drain line (136), in which a conveying pump (137) is arranged and in at least one heat exchanger (120) for heating of heating or service water flows out via a supply line (121) with the Neutralization device (140) is connected, d) the discharge line (156) for the neutralized condensate flows into a neutralized condensate collecting, with an intermediate container (160) provided with a float switch (163), which is connected via a supply line (161) connected to the flue gas scrubber (130) with the feed pump (167) switched on and has a discharge line (164), and e) the exhaust gas outlet nozzle (132a) of the flue gas scrubber (130) opens into a conventional, exhaust chimney consisting of a galvanized sheet metal pipe. 3. Plant according to claim 1 and 2, characterized in that in the a flue gas discharge line (32; 132) leading to the exhaust chimney, a reheater (35; 135) is arranged. 4. Plant according to claim 1 to 3, characterized in that the to the firing device (10; 100) subsequent plant parts in a container (90; 190) are arranged.