DE3029561A1 - Indirect malt kiln heating system - with combustion chamber water and flue gas heat exchangers in intake air duct - Google Patents

Abstract

An air heater for the indirect heating of malt kilns in breweries is built into the air duct leading to the kiln and consists of a combustion chamber with a burner and a boiler attached to a heat exchanger. The flue gases from the combustion chamber are passed through two flue gas heat exchangers, also in the air duct, before they are discharged through a chimney. This prevents the prodn. of nitrosamines NOx which are believed to be carcinogenic and maintains the same energy consumption as direct heating systems for a reasonable capital expenditure.

Description

Air heater for indirect heating

von Mälzerei-Darren The invention relates to an air heater for indirect heating of malting kilns according to the preamble of claim 1.

Malting kilns are usually heated directly by adding to the a flame is introduced into the kiln air flow, and the resulting Air / flue gas mixture is used for kilning.

It has been found that this type of kiln produces nitrosamines (NOx) arise, which are harmful (carcinogenic) substances. There are therefore efforts have already been made to heat the kilns indirectly. the end the article "Indirect kiln heating without additional fuel consumption" (Brauwelt 1980, 448 and 449) a high-performance air heater has become known, in which across the Air flow a combustion chamber with flue gas / air heat exchangers in counterflow is provided. In this case, at least in the low temperature range, there are low-corrosion glass tubes intended. However, the high temperature range, in particular, makes difficulties the combustion chamber, which has a very strong tendency to scale, and therefore the system already put out of operation in a very short time.

A flue gas recirculation is required to lower the temperature of the flue gases provided, through which, however, considerable amounts of smoke gas in the order of magnitude the entire amount of flue gas must be returned.

In the article is already on hot water or steam heated systems pointed out, however, that they are because of high investment costs and higher energy consumption.

The object of the invention is to create an indirect kiln heating, that despite acceptable investment costs and without increasing energy consumption solves the stability problems of the known indirect kiln heating.

This object is achieved according to the invention by the characterizing part of the claim 1 solved.

So it is a combination of a liquid- or steam and flue gas heating created.

In the combustion chamber surrounding the liquid jacket, the temperature of the flue gases is preferably lowered to a value at which the formation of nitrosamines is no longer to be feared and, on the other hand, a premature corrosion of the flue gas / air heat exchanger is no longer to be feared is. This temperature is below 1100K (8300C) and preferably in the Of the order of 900K (630 ° C).

The boiler containing the combustion chamber can preferably be in the air duct arranged and possibly ribbed on its outer surface, so that he himself as Heat exchanger works.

The furnace can therefore with an optimal air ratio and therefore work with high efficiency and the best combustion and normally needs no flue gas recirculation The boiler can be structurally special simple flame tube boiler or a flame tube / smoke tube boiler for greater energy requirements be. If, as preferred, it is a steam boiler, the boiler can be a low-pressure steam boiler with natural circulation. The heat exchangers inclined in the case of a vertical air duct or vertically in the case of a horizontal air duct be provided finned tube coil heat exchangers. In this case there is the condensate return very cheap.

The arrangement of the two types of heat exchangers is preferably like this made that1 seen from the air inlet side, first a low-temperature flue gas heat exchanger is arranged (temperature range of the flue gases, for example 500 to below 350 K (250 to below 80 "C), which may be used for further preheating of the Kiln incoming exhaust air is already preheated in a cross-flow heat exchanger. This is followed by the liquid or steam / air heat exchanger with most of the heat available.

After that (possibly also in front of it) the combustion chamber lies in the air stream and on top of it follows the boiler-side flue gas heat exchanger, the flue gas side between 850 and 500K (600 and 2500C) works. This way it will look without any risk of corrosion the heat exchangers and without overheating, which lead to nitrosamine formation could, made sure that there is always an optimal temperature difference to a good one Heat transfer is present.

As already suggested in the article mentioned above, the flue gas can be fed into the exhaust air side of the cross-flow heat exchanger so that no losses occur here either.

So, contrary to the prejudice expressed in the article, it becomes a Kiln heating created that works with the same efficiency as the previous ones Attachments1 and in the investment costs despite the additional expense of water-cooled combustion chamber is therefore not significantly higher, because with the Liquid or vapor / air heat exchangers are very effective and beyond that Commercially available component can be used. The nitrosamine formation is due to the absolutely clear controllable temperatures avoided particularly effectively, the quality of the combustion, which also influences the efficiency, is due to the optimal combustion air setting without flue gas recirculation particularly good and Above all, the system works trouble-free and is no longer against scaling subsceptible.

Instead of a preferred steam boiler for combustion chamber cooling, could can also be worked with hot water or thermal oil.

Because of the particularly good freedom from interference, there would also be other sources of warm air can be connected in addition to a kiln heating.

Further details, features and advantages of the invention result emerge from the subclaims and the following description of a preferred embodiment of the air heater according to the invention in connection with the drawing in which this preferred embodiment of the air heater according to the invention shown schematically is.

The air heater shown in the drawing has an air duct with a substantially vertically extending air duct section 1, which is below merges into a substantially horizontal air duct section 2. On the horizontal Air duct section 2 includes a leading to a kiln, not shown, essentially vertically extending air duct section 3. In the air duct section 3, an air intake device in the form of an induced draft 4 is arranged, which over an electric motor 5 can be driven. As soon as the electric motor 5 is switched on, is air through the vertical air duct section 1, the look at it subsequent horizontal air duct section 2 and the adjoining vertical air duct section 3 sucked.

In the vertical air duct section 1, there is a combustion chamber containing Boiler 6 arranged. The combustion chamber of the boiler 6 is an UL or gas burner 7 assigned. In the boiler 6 is also arranged in the air duct section 1 Associated heat exchanger 8, through which the water vapor generated in the boiler 6 is passed and which is used to condense this water vapor.

The flue gases generated in the combustion chamber of the boiler 6 are through a pipe 9 passed through a first flue gas heat exchanger 10, the is arranged in the air duct section below the boiler 6 and how this of the sucked-in air flows around it. From there the flue gases arrive via a pipeline 11 to a second flue gas heat exchanger 12, around which intake air flows in Air duct section 1 is arranged above the heat exchanger 8. From there the flue gases then escape via a pipe 13.

The two flue gas heat exchangers shown schematically in the drawing 10, 12 each have pipes through which flue gas flows, for relief of the heat exchange are ribbed. The latter also applies to the external one Shell of the boiler 6.

The air heater shown schematically in the drawing comes the task of using the available intake air while avoiding nitrosamine formation to be heated to the desired drying temperature. The following ¢ dimensions are used for this procedure: First the motor 5 is switched on and with it the induced draft 4 in Set in motion with the result that air from above merges into one another Air duct sections 1 to 3 is sucked, for which a stationary state Set intake temperature of, for example 45 "C, since the intake air from a cross-flow heat exchanger heated by the kiln exhaust air and possibly by the flue gas from line 13 is preheated. When the burner 7 is ignited, the resulting water vapor arrives Via the steam line 14 shown on the left in the drawing into the heat exchanger 8 and is condensed there, giving off heat to the air flowing past there. The condensate flows back into the boiler 6 via the one shown on the right in the drawing Condensate line 15.

The boiler 6, the combustion chamber arranged in it and the flue gas side adjoining two flue gas heat exchangers 10 and 12 are for example designed so that the flue gases generated in the combustion chamber with the combustion chamber about 6000C, the first flue gas heat exchanger 10 with about 2500C and the second Flue gas heat exchanger 12 left with about 100 ° C and that the originally 45 "C warm intake air through the flue gas heat exchanger 12 to about 47.5 ° C, through the Steam heat exchanger 8 and the adjoining boiler 6 to about 74 "C and the flue gas heat exchanger 10 is finally heated to about 80 ° C.

To regulate the in the flue gases and thus in the intake air prevailing temperature conditions it is possible with additional external, outside of the air duct arranged heat exchangers to work, for example in the pipeline 9 or the pipeline 11 can be switched.

Although the arrangement of the boiler 6 in the air duct is particularly advantageous is, this boiler could also be, for example to use commercially available Boiler can be arranged outside of the air duct.

The boiler / combustion chamber can be with a double jacket or with pipes be cooled, both versions are referred to above as a jacket. Of the The boiler can also be switched to forced circulation or circulation.

Claims (14)

Air heater for indirect heating of malting kilns 1. Air heater for indirect heating of malting kilns with an air duct, a burner and a combustion chamber, characterized in that the burner (7) has a liquid-cooled Combustion chamber is assigned, and that in the air duct (1,2,3) at least one with the im Jacket of the combustion chamber heated medium (liquid or steam) acted upon Heat exchanger (8) is arranged. 2. Air heater according to claim 1, characterized in that a die Combustion chamber containing boiler (6) is arranged in the air duct (1,2,3). 3. Air heater according to one of the preceding claims, characterized in that that two can be acted upon with the flue gases generated in the combustion chamber, in the Air supply direction at a distance behind each other arranged flue gas heat exchangers (10,12) are provided. 4. Air heater according to claim 3, characterized in that the liquid or steam / air heat exchanger (8) and possibly the boiler (6) between the two Flue gas heat exchangers (10,12) is arranged. 5. Air heater according to claim 4, characterized in that the two Flue gas heat exchanger (10,12) to the air flow direction in the air duct (1,2,3) in the Are arranged countercurrent. 6. Air heater according to one of the preceding claims, characterized characterized in that the heat exchanger tubes are ribbed. 7. Air heater according to one of the preceding claims, characterized characterized in that the heat exchanger tubes at least in the area of lower flue gas temperatures Corrosion-resistant pipes, especially glass pipes. 8. Air heater according to one of claims 2 to 7, characterized in that that the outer shell of the boiler (6) is ribbed. 9. Air heater according to one of claims 2 to 8, characterized in that that the boiler (6) is a flame tube or flame tube / smoke tube boiler. 10. Air heater according to one of claims 2 to 9, characterized in that that the boiler (6) is dimensioned such that its flue gas outlet temperature is below of 1,100 K, preferably 9-00 K. 11. Air heater according to one of claims 2 to 10, characterized in that that the boiler (6) is a low-pressure steam boiler with natural circulation. 12. Air heater according to one of the preceding claims, characterized characterized in that the liquid or vapor / air heat exchanger (8) is a preferably obliquely in a vertical air duct or in a horizontal air duct is vertically positioned finned tube coil heat exchanger. 13. Air heater according to one of the preceding claims, characterized characterized in that an external, with the smoke gases generated in the combustion chamber actable heat exchanger is provided. 14. Air heater according to one of the preceding claims, characterized indicated that an external water vapor generated in the jacket of the combustion chamber actable heat exchanger is provided.