DE1272304B - Device for heat recovery from the flue gases of a steam generator - Google Patents

Description

Device for heat recovery from the flue gases of a steam generator The invention relates to a device for heat recovery from the withdrawing Flue gases from a steam generator, with two at different points in the flue arranged primary heat exchangers, each in an associated closed Water circuit, each with a secondary heat exchanger for heating the combustion air or downstream of the feed water and one device in both circuits to adjust the temperature of the flowing back to the primary heat exchangers Circulating water is provided.

In a known system of this type, in which the recovered Heat used to heat combustion air is used inside the air supply line lying first secondary heat exchanger charged with circulating water, the in a primary heat exchanger arranged in the area of low temperatures of the flue gases has been heated. To avoid dew point corrosion from sulfur-containing smoke gases on the primary To prevent heat exchangers, this can be short-circuited via a special line by a valve actuated by a heat sensor more or less is opened. The known system contains a second recovery circuit, with which a further heating of the combustion air is intended. To this The purpose is steam from a superheater arranged in the flue gas in a second Secondary heat exchanger arranged in the air supply line condenses and after its condensation in a downstream further, also in the flue gas arranged primary heat exchanger is reheated.

The invention is based on the object of the known device to avoid dew point corrosion on the heat exchangers in the flue to simplify and at the same time enable the production of pure distilled water, without reducing the efficiency of the system.

To solve this problem it is proposed according to the invention that in both circuits the feed lines from the primary to the secondary heat exchangers and the discharges from the secondary to the primary heat exchangers, respectively Lead flash evaporator, in a manner known per se in the steam lines from, the expansion evaporators to the secondary heat exchangers, one pressure control valve each is arranged and from the outlets of the secondary heat exchanger each one condensate tap proceeds, one of which from the first circuit as a supplementary water line leads to the flash evaporator of the second circuit.

Due to the evaporation carried out in the flash evaporators of the water heated by the flue gases in the primary heat exchangers the possibility of using the wall temperatures of the primary heat exchanger the steam pressure regulating valves built into the steam lines in a simple manner To influence sensitively so that corrosion phenomena due to condensing Smoke gases are avoided. In addition to the recovered heat, you get practical free distilled water, which is known to be a considerable economic one Worth it. In the double distillation proposed according to the invention, can the water obtained in this way, also taking into account increased safety conditions. come to use in a high pressure steam boiler. Of course he can If required, water with a lower degree of purity simply distilled water Water can be removed, so that in such a case the second circuit can be dispensed with.

Although it is already known that taking into account in a steam boiler the concentration of soluble salts to be adjusted continuously withdrawn To conduct blowdown liquor into a relaxation vessel and with the resulting there To heat an evaporator to produce distilled make-up water, the vapor condensate itself is also used again as boiler feed water. The liquid portion of the blowdown liquor remaining in the expansion vessel is added Admixture of raw water transfers its heat to it and becomes vasser together with your raw water introduced into the evaporator heated by the vapor. Since the withdrawn from the steam boiler Blow-down liquor neither enough water nor enough heat to produce distilled Contains feed water to compensate for the amount of water withdrawn are to be sent to the Connections between expansion vessel and evaporator a steam supply line as well as a raw water pipe connected. It is in the vapor discharge line behind the expansion vessel there is a valve to regulate the vapor pressure for the purpose of coordination when mixed with the supplementary steam supplied by the consumer (e.g. a turbine) as well as a volume control valve in the caustic discharge line behind the expansion vessel provided in order to maintain a sufficient liquid level in the expansion vessel. The control valve in the vapor discharge line behind the expansion vessel is therefore used only the task of regulating the steam pressure, and beyond that it will not, as in the invention, to control the water circulation and the wall temperatures used in the primary heat exchangers.

The invention is further developed in that the expansion evaporator, from which the make-up water: is taken, a supply line with a pre-cleaning device for raw water is connected. The supply of fresh water to the flash evaporator is necessary when distilled water is withdrawn from the system, which is used as Condensate accumulates in the secondary heat exchangers.

The invention is described in more detail below using an exemplary embodiment explained.

F i g. 1 shows a heat recovery system according to the invention two independent circuits with their primary heat exchangers in different places are arranged in a smoke outlet; F i g. 2 shows the temperature range in a diagram, within which condensing flue gases are particularly corrosive to the walls of the heat exchanger act.

For F i g. 1 it is assumed that the flue gases of a steam boiler; whose heat is to be recovered, at the exit of the shown area of the smoke gas vent 1 at a relatively low temperature, z. B. at 90 ° C. In front of the exit, a primary heat exchanger 2a is arranged within the flue gas exhaust 1, which is fed with water via a line 3a. The water heated in the heat exchanger 2a flows through a line 5a and a spray nozzle 24 into an expansion evaporator 6a, which is connected to a secondary heat exchanger 8a via a steam line 7a. This secondary heat exchanger is a preheater either for boiler feed water or preferably for combustion air. Inside the secondary heat exchanger 8a, the condensation of the vapor brought in via the line 7a takes place under vacuum, with non-condensable vapors or gas components being sucked off by means of a vacuum pump (not shown).

The secondary heat exchanger 8a can in the usual way with finned tubes be equipped in which the supplied steam circulates and by releasing its Heat condenses on the combustion air entering at 9a and discharged at 10a.

The condensate accumulating at the bottom of the secondary heat exchanger 8a is via a line 11a and a suction pump 12a in the flash evaporator 6a, where it mixes with the sprayed, not evaporated water. This water is with the help of a circulation pump 4 a from the bottom of the evaporator 6 a removed and fed to the primary heat exchanger 2 a via line 3 a, whereby the first closed cycle is completed.

The combustion air heated in the secondary heat exchanger 8a is fed to a further secondary heat exchanger 8 b, which is under construction second closed circuit identical to the circuit described above belongs: However, the primary heat exchanger 2b of this second circuit is present a point of higher temperatures within the flue gas outlet 1. This circuit forming plant parts are denoted by the same reference numerals as those in the cycle described first, but with the addition "b".

The condensate from the secondary heat exchanger 8 a leading to the flash evaporator 6a conduit 11a is provided with a tap 13 a, the distilled in the first circulation water the flash evaporator 6b of the second circuit is supplied as replenishing water from which via a line 25th The supply of singly distilled water to the flash evaporator 6 b takes place in accordance with the amount of doubly distilled water taken from the second circuit through a tap line 13 b.

The distilled water removed from the first circuit is replaced via a supplementary line 16 connected to the expansion evaporator 6a. The raw water fed in via line 17 first passes through a pre-cleaning apparatus 18 of conventional design, in which, depending on the quality of the raw water available, decarbonization, filtering or coarse desalination is carried out. In the lines 16, 25 connected to the expansion evaporators 6a, 6b, inflow control valves 19a, 19b are installed, which are controlled by level regulators.

In the steam supply lines 7a, 7b to the secondary heat exchangers 8a, 8b, a pressure control valve 20a, 20b is installed, with which the steam pressure in the evaporators and thus also the temperature of the circulating water can be controlled. If the flue gases have low temperatures during partial load operation of the steam boiler, the valves 20 a, 20 b allow the steam pressure and thus also the temperature of the water in the entire circuit to be increased in a simple manner and thus the wall temperature of the primary heat exchangers 2 a, 2 b to be kept at a value at which dew point corrosion of the flue gases can be reliably avoided. For a specific example, FIG. 2 shows the effects of corrosion on heat exchanger pipes made of steel in a flue gas vent. The temperature of the pipe wall on the flue gas side is entered on the abscissa, while the ordinate shows the weight of the steel destroyed by corrosion per unit of time as a percentage of the weight of the pipes. Repeatable measurements show that the curve has a hump c which, in the example chosen, is between 85 and 135 ° C. If the pipe wall temperature lies within the range given by the two values, a significantly higher level of corrosion takes place than in the adjacent areas a and b . In order to achieve maximum utilization of the heat contained in the flue gases, the in FIG. 1 system according to the invention, the temperatures of the primary heat exchangers 2a, 2b with the help of the remote control valves 20a, 20b are sensitively regulated as close as possible to the dangerous area given by the curve hump c, the water in the heat exchanger 2a then to 75 ° C and the water in the heat exchanger 2b is kept at 135 ° C.

It follows that the system according to the invention for heat recovery at low temperatures of the flue gases in addition to the usual arrangements of economizers and air preheaters. Beneficial application is everywhere given where there is a frequent change in the operating state of the steam boiler between Full-load and part-load operation (e.g. in ship engine systems) takes place or where, due to the use of different fuels, the exhaust gas temperatures change or the temperature range changes within which the exhaust gases are particularly corrosive in the event of condensation.

The withdrawn from the second circuit by means of the tap 13 b Distilled water has a high degree of purity and is suitable under consideration the degassing carried out in the secondary heat exchanger without further ado Use in a superheater or high pressure boiler. In those cases where on A high degree of purity of the water is not particularly important, it goes without saying possible to simply add distilled water to the system via the tap 13 a remove. In this case, only a single circuit is needed for heat recovery and to persist to produce simply distilled water. Such a The circuit corresponds approximately to that in FIG. 1 arrangement shown on the right. The water heated by the flue gases in the primary heat exchanger gets into the an expansion evaporator whose steam is connected to the downstream via a pressure control valve secondary heat exchanger for heating feed water or combustion air and there under vacuum and removing the non-condensable vapor and gas components is condensed. The condensate withdrawn from the bottom of the secondary heat exchanger is either fed back into the flash evaporator or as make-up feed water taken from the circuit. This amount of water removed from the circuit can be replaced by pre-cleaned Fresh water is replaced, its supply via a level controller in the expansion evaporator he follows.

Claims (2)

Claims: 1. Device for heat recovery from the exhausting flue gases of a steam generator, in which two primary heat exchangers arranged at different points in the flue gas, each located in an associated closed water circuit, each followed by a secondary heat exchanger for heating the combustion air or the feed water and in both Circuits a device for adjusting the temperature of the circulating water flowing back to the primary heat exchangers is provided, characterized in that in both circuits the feed lines (5 a, 7 a; 5 b, 7 b) from the primary. (2'a; 2 b) to the secondary heat exchangers (8 a; 8 b) and the discharges (11 a, 3 a; (11 b, 3 b) from the secondary (8 a; 8 b) to the primary. Heat exchangers (2a; 2b) each lead via expansion evaporators (6 a; 6b), in a manner known per se in the steam lines (7 a; 7b) from the expansion evaporators (6a; 6b) to the secondary heat exchangers (8 a; 8 b ) a pressure control valve (20 a; 20 b) is arranged and from the discharge lines (11a; 11b) of the secondary heat exchangers (8a; 8b) a condensate tap line (13 a; 13 b) emanates, one of which (13a) of the first circuit as a supplementary water line (25) leads to the expansion evaporator (6 b) of the second circuit. 2. Device according to Claim 1, characterized in that the expansion evaporator (6a) from from which the make-up water is taken, a supply line (16, 17) with a Pre-cleaning device (18) for raw water is connected. Considered Publications: German Patent No. 517 541; German interpretative document no. 1017 624; Austrian Patent No. 177 859; British Patent Specification No. 299 436, 393 725, 629 298; U.S. Patent No. 1703 093.