DE3216561A1 - METHOD FOR PURIFYING EXHAUST GAS AND FOR RECOVERING HEAT AND DEVICE FOR CARRYING OUT THE METHOD - Google Patents

Abstract

A method for purifying exhaust gases containing noxious products as well as an installation for implementing such method particularly intended to boiler rooms are described. In a cheminee (8), an exhaust gas conduit (9) is arranged wherein a purifying liquid conduit (12) opens into its upper portion. The liquid is sprayed counter to the gases to be purified which flow upwardly within the exhaust conduit (9). Moreover, the purifying liquid contains additives which react with and fix the noxious products in the exhaust gases. The liquid, withdrawn from a storage tank (16), finally circulates downwardly within the exhaust conduit (9) and is brought back in said tank (16). The tank is preferably built up as a combined storage, sedimentation and reaction receptacle, wherein the solid products formed during the washing can settle and wherein the purifying liquid regenerate. Heat exchangers (7, 17, 18) are provided to extract from the exhaust gases the heat that would otherwise be exhausted with the gases without being used.

Description

Process for cleaning exhaust gas and for recovering heat and apparatus for carrying out the process

The invention relates to a method for cleaning exhaust gas and for recovering heat from a furnace and a device for performing the method.

Firing systems in which fossil fuels are burned, for example firing systems equipped with oil burners, pollute the environment through the sulfur dioxide SO2 in the exhaust gases. In addition, the hot exhaust gases create high heat losses. This heat loss means that the entire efficiency of a combustion system, with which for example, water is heated, is limited.

The aim of the invention is to remedy the stated disadvantages.

The method according to the invention is characterized in that that in a first step a quantity of heat is removed from the exhaust gas and fed to a heat consumer, with which the temperature of the exhaust gas is lowered so that in a second step a solution that binds pollutants in the exhaust gas guided in countercurrent through the exhaust gas, whereby a further amount of heat and pollutants are extracted from the exhaust gas, what further amount of heat is supplied to a fluid to be heated.

The device for carrying out the method is characterized in that one is heated e.g. by an oil burner.

th boiler through which the fluid to be heated flows is, and a flue gas line connected to the boiler room on the flue gas side with an inlet and an outlet, through a first heat exchanger arranged in the inlet of the exhaust gas line, through a storage container for the solution binding the pollutants in the exhaust gas, from which storage tank a solution supply line runs to an atomizing device arranged in the outlet of the exhaust pipe, through one of the lower end the exhaust line from the return line running to the storage tank, and through at least one further, im Storage tank arranged, flowing from the boiler and fluid to be heated therein flowed through heat exchangers.

The following is the subject matter of the invention. based on Drawing explained by way of example.

The single figure shows schematically a device for Carrying out the method according to the invention.

In the figure, an oil burner 1 is in connection with a Boiler 2 shown. The boiler 2 is used, for example, to heat the domestic water and the heating water of a building. Accordingly, the domestic water supply 3 and the domestic water feed line 4 are available. The heating flow is with reference number 5 and the heating return denoted by the reference number 6. Next is a chimney 8 available, for example from a Masonry is formed. In the chimney 8, an exhaust pipe 9, for example made of stainless steel, is used which

Exhaust pipe 9 from the exhaust gases originating from the oil burner 1 is flowed through. In the chimney socket 19, between the 'boiler 2 and the exhaust pipe 9, there is a first heat exchanger 7 arranged. There is also a storage container 16 which binds with a pollutant of the exhaust gas Solution is filled. From the storage tank 16 leads a line 12 in which a pump 13 and then in Direction of flow an air injector 15 are arranged against the upper end of the exhaust pipe 9 and ends at a spray device 10. This spray device 10 advantageously has spray arms arranged in a star shape 11 on. From the lower, closed end of the exhaust pipe 9, a drain pipe 14 leads to the storage tank 16 back.

From the figure it can also be seen that the domestic water feed 17 is passed through the storage tank 16 and merges into the domestic water feed line, which enters boiler 2. The return of the heating water, e.g. for building heating, is to be compared with the reference number 18 denotes. This return 18 also leads through the storage tank 16 and then to the heating return 6, which also runs into boiler 2.

A practical embodiment provides that the length of the exhaust pipe 9 corresponds at least to the chimney height and is advantageously 6 m or more, and the diameter of the exhaust pipe 9 of this embodiment is 15 cm. The solution that binds pollutants in the exhaust gas is a lime solution in which quicklime and water are in the

- Q -

Verhaltnisante.il of 40 g of lime to 1 liter of water and In addition, formic acid is present in a proportion of 50 g formic acid to 40 g lime.

It should also be mentioned that after the pump 13 in the Pipeline 12 seen in the direction of flow air is introduced, for example by an air injector. The air supply causes the solution to oxidize.

The following operating procedure is now carried out with this system. The exhaust gas resulting from the oil burner 1 contains SO ₂ , although it is known that burning 1 kg of oil in each case _{produces up to about 3 liters of SO 2} gas, which SO _{2 is} known to be a major contributor to environmental pollution. The exhaust gas flowing through the chimney socket 19 and having a ^{temperature of approximately up to 300 °} C. is now cooled by the first heat exchanger 7. The heat exchanger 7 is dimensioned in such a way that the exhaust gas is cooled to 50 to 80 ^° C., for example. The exhaust gas thus enters the exhaust gas line 9 at this temperature. The heat exchanger 7, for example, has water flowing through it, which is heated in the process. This heated water can be used, for example, for heating purposes of the building, for example by means of a further heat exchanger for heating domestic water, for heating a swimming pool, etc.

The 50 to 80 ⁰ C, cooled to, for example, exhaust gas flows through it, the exhaust pipe 9 into the upper end of the described solution is sprayed by the spraying apparatus 10th This emerging from the spray device 10

The solution now absorbs SO2 in the exhaust gas and collects at the lower end of the exhaust pipe 9. In addition, this solution also absorbs heat. It heats up when it comes into contact with the exhaust gas, which is thus further cooled. The mass flow of the solution is so dimensioned relative to the mass flow of the exhaust gas that the outlet temperature of the exhaust gas from the exhaust pipe is less than 40 ^° C. The solution collected at the bottom of the exhaust line 9 flows back through the drain line 14 into the storage container 16.

The lime in the solution and the SO _{2 of} the exhaust gas form calcium sulphite, which is oxidized to calcium sulphate by atmospheric oxygen. The amount of oxygen required for the oxidation is advantageously introduced into the flowing solution by means of an air injector 15 into the pipeline 12 immediately downstream of the pump 13. This sludge is now deposited in the storage tank 16 due to the residence time of the solution in the same and is periodically removed from it. The lime used in this process is continuously replaced by means of a metering device.

The storage container has e.g. a capacity for about 40 liters of the solution. According to the above, this amount of 40 liters is sufficient for the intake from 900 liters SO ». Experience has shown that in one Heating boiler of a family house during the heating season the hourly oil consumption is 2 kg. The burner is As is well known, about a total of 10 hours in operation, so that the daily oil consumption is 20 kg, i.e. monthly thus 600 kg. This shows that during the heating

Period of the storage tank only about once per It has to be cleaned every month, i.e. the sludge containing the pollutants it contains has to be cleaned at most once be paid monthly. In known combustion systems, the SO ^ proportion in the exhaust gas is around 100 to 115 ppm. Practical tests have shown that with the system described, the SO ^ content when exiting the Chimney is only 26.9 to 28.4 ppm. That means, there are only about 30% pollutants in comparison delivered with the building services systems that are customary today.

The recovery of the heat takes place through this plant as follows.

It has already been mentioned at the beginning that the amount of heat dissipated by the first heat exchanger 7 through a water circuit is used for heating purposes and also for heating domestic water.

The herunterregnende in the exhaust pipe 9 solution increases, as already mentioned, from the exhaust gas heat, such that the presence in the reservoir solution may be reached a temperature of 40 to 60 ⁰ C during operation and zruückgewonnen by further heat exchanger.

Claims (11)

Patent attorneys Dipl.-Chem. I. SCHULZE Galsbergstrasse 3 r \ · ι ι r- ~ * ..- ~~~. ._.- 6Θ0Ο HEIDELBERG 1 Dipl.-Ing. E. GUTSCHER phone 06221/23269 Γ Abs. Dlpl.-Chem. I. Schulze, Dipl.-Ing. E. Gutecher, Patentanwälte -] OUR CHARACTERISTICS: GalsbergstraBe 3. 6900 Heidelberg 1 your CHARACTERISTICS: Applicant: Feraton Anstalt, Bürotel,
FL-9494 Schaan EXPECTATIONS Process for cleaning exhaust gas and for recovering heat from a combustion system, characterized in that an amount of heat is withdrawn from the exhaust gas in a first step and fed to a heat consumer, whereby the temperature of the exhaust gas is lowered that in a second step a pollutant of the exhaust gas binding solution is passed in countercurrent through the exhaust gas, the exhaust gas an amount of heat and pollutants are withdrawn, what further amount of heat is from the inlet Authorized representative at the European Patent Office Prof. Representatives before the European Patent Olllce Mandatalres agrfes pres I 'Office europeen des brevets of the fluid to be heated in the combustion system or another heat consumer. 2. The method according to claim 1, characterized in that the solution is passed in a circuit, the one Has storage location for the solution in which during the thus formed residence time of the solution, the reaction products of the pollutants in the exhaust gas with the Absorbents are excreted from the solution and removed periodically, and that the further amount of heat of the Solution taken while it is staying in the storage location of the same and the inlet of a to be heated Fluid is supplied. 3. The method according to claim 1, characterized in that the solution is sprayed into the exhaust gas, then collected again and is returned to the memory location, and that the fluid to be heated is heating and / or service water. 4. The method according to claim 2, characterized in that preferably the solution of lime and water in a proportion of e.g. 40 g quicklime to 1 liter of water, and formic acid in a proportion preferably consists of 50 g of formic acid for 40 g of lime. 5. The method according to claim 4, characterized in that the bound pollutants excreted at the storage location and removed periodically. 6. The method according to one or more of the preceding claims, characterized in that in the pipeline device (12) immediately behind the pump (13), seen in the direction of flow, air into the flowing solution is introduced. 7. The method according to claim 6, characterized in that the supplied air by means of an air injector (15) through which the solution flows and is actuated by this is introduced. 8. The method according to claim 4, characterized in that the residence time of the solution in the storage location is so is dimensioned so that the bound pollutants are deposited. 9. Device for carrying out the method according to claim 1, with a boiler heated, for example, by an oil burner, through which the fluid to be heated flows, and one connected to the boiler room on the exhaust gas side Exhaust pipe with an inlet and an outlet, through a first arranged in the inlet of the exhaust pipe Heat exchanger, through a storage tank for the solution that binds the pollutants in the exhaust gas Storage container from a solution supply line to a spraying device arranged in the outlet of the exhaust gas line runs through a from the lower end of the exhaust pipe to the storage tank Return line, and advantageously through another, arranged in the storage tank, from one Heat exchanger flowing through the heat consumer and fluid to be heated therein. 10. The device according to claim 7, with one of heating water and service water flowed through the boiler, thereby characterized in that two heat exchangers are arranged in the storage tank, one of which is from the return of the heating water and the other is flowed through by the domestic water supply to the boiler. 11. The device according to claim 7, characterized in that that a pump is arranged in the solution feed line and the atomizing device is arranged in a star shape Has spray arms.