RU2193727C1 - Plant to recover heat of stack gases - Google Patents

Abstract

FIELD: power engineering, recovery of waste stack gases in power engineering installations. SUBSTANCE: plant to recover heat of stack gases has recovering heat exchanger and heat exchanger of intermediate transfer agent mounted one opposite another at equal distance from sprinkler installed in front of them. Heated passage of heat exchanger of intermediate heat transfer agent is joined with inlet to moisture collector. Nozzles of sprinkler are directed to side opposite to heat exchangers. Plant is supplemented with another heat exchanger for additional heating of sprinkling water installed in gas passage and placed above sprinkler. Heated passage of it is connected with inlet to heat exchanger of intermediate heat transfer agent and with outlet to sprinkler. EFFECT: increased functional efficiency of plant thanks to more complete recovery of heat. 1 dwg

Description

 The invention relates to energy and can be used to recover heat from gases used in power plants.

 A known installation for heat recovery of flue gases (see ed. Certificate of the USSR 1032273, BI 28, 1993), including a sprinkler with dispensing nozzles installed in a gas duct, a heat exchanger and an intermediate heat exchanger heat exchanger, the heated path of which is connected to the moisture collector at the inlet, and exit to the sprinkler, while the sprinkler is located in front of the specified heat exchangers installed one opposite the other at the same distance from the sprinkler, whose nozzles are directed opposite to the heat exchangers defense, and taken as a prototype.

The reasons that impede the achievement of the technical result indicated below when using the known installation for utilizing flue gas heat adopted as a prototype include the fact that the known installation has reduced efficiency, since the irrigation water in the upper zone of the heat exchangers is simultaneously heated by gases having a maximum temperature, and is cooled by the outer surfaces of the heat exchangers, which reduces the transfer of heat from gases to heated fluids. In addition, irrigation water and water discharged to the heat consumer are heated to a low temperature of 50-55 ^o C, not exceeding the temperature of the wet thermometer.

 The invention consists in the following. To increase the efficiency of the installation for the recovery of flue gas heat, it is advisable to install a heat exchanger in the duct above the irrigator, in which the irrigation water is heated to a higher temperature. In this case, during the heat exchange of the irrigation water with gases, the amount of water vapor evaporated into the combustion products and their partial pressure increase, which causes the water removed to the consumer to heat up to a higher temperature. The heating of the irrigation water further intensifies the heat transfer in the upper zone of the heat exchangers installed after the irrigator.

 The technical result is an increase in the efficiency of the installation for the recovery of flue gas heat by installing in the duct above the sprinkler a heating exchanger for irrigation water heating.

 The specified technical result during the implementation of the invention is achieved by the fact that the known installation for heat recovery of flue gases contains an irrigation nozzle with dispensing nozzles installed in the gas duct, a heat exchanger and an intermediate heat exchanger heat exchanger, the heated path of which is connected to the moisture collector at the inlet, while the irrigator is located in front of the heat exchangers installed one opposite the other at the same distance from the sprinkler, whose nozzles are directed in the opposite direction relative to the heat exchangers side. The peculiarity lies in the fact that the flue gas heat recovery unit is additionally equipped with a heat exchanger for heating the irrigation water installed above the irrigator, the heated path of which is connected at the inlet to the intermediate heat exchanger and at the outlet to the irrigator.

 The drawing shows a diagram of an installation for heat recovery of flue gases.

 The flue gas heat recovery installation comprises a heat exchanger 2 for heating irrigation water installed in a gas duct 1, a recovery heat exchanger 3 and an intermediate heat carrier (irrigation water) heat exchanger 4, connected by its inlet to the moisture collector 5, and the output to an heat exchanger 2 of irrigation water heating, the heated path of which at the output it is connected to the sprinkler 6, the dispensing nozzles 7 of which are directed in the opposite direction with respect to the heat exchangers 3 and 4. Heat exchangers 2, 3 and 4 can be made with fins.

 The operation of the installation for heat recovery of flue gases is as follows.

Flue gases with a temperature of 140-170 ^o C pass through the duct 1, wash the outer surfaces of the heat exchangers 2, 3 and 4 and give them heat, heating the heat carriers passing through them. In the heat exchanger 2 of heating the irrigating water, the combustion products are cooled to a temperature of 90-100 ^o C, not exceeding the dew point, condensation of water vapor does not occur from the gases. In heat exchangers 3 and 4, the combustion products are cooled below the dew point - to a temperature of 30-40 ^o C. In this case, condensation of part of the water vapor from the gases occurs. Thus, both the physical heat of the gases and the latent heat of condensation of a portion of the water vapor contained therein are useful.

Flue gases immediately before the heat exchangers 3 and 4 are irrigated with water supplied by the irrigator 6 connected to the moisture collector 5 through the heat exchanger 4 of the intermediate heat carrier and the heat exchanger 2 of heating the irrigation water. In the heat exchanger 2, the irrigation liquid is heated to a temperature of 80-90 ^o C. Therefore, the amount of moisture evaporated into the flue gases, which determines the partial pressure of water vapor in the combustion products, will be greater, which increases the temperature of the wet thermometer and provides heating of the water in the recovery heat exchanger 3 to a higher temperature.

 Irrigation water washes the outer surfaces of heat exchangers 3 and 4, increases the heat transfer coefficient from the combustion products and, together with the condensate of water vapor from the flue gases, flows into the moisture collector 5. The location of the dispensing nozzles 7 towards the flue gas stream allows heating due to the increased contact time between the gases and the irrigation water last to a higher temperature. Heating the irrigation water to a higher temperature further intensifies the heat transfer in the upper zone of the heat exchangers 3 and 4 installed after the sprinkler.

 The installation in the flue above the sprinkler of the heat exchanger of the irrigation water heating causes the temperature of the wet thermometer to increase and ensures that the water heat removed to the consumer is heated to a higher temperature, which increases the efficiency of the installation for utilizing flue gas heat.

Claims (1)

 A flue gas heat recovery plant comprising a sprinkler with dispensing nozzles installed in a gas duct, a heat exchanger and an intermediate heat exchanger heat exchanger, the heated path of which is connected to the moisture collector at the inlet, while the sprinkler is located in front of the heat exchangers installed one opposite the other at the same distance from the sprinkler, whose nozzles are directed in the opposite direction with respect to the heat exchangers, characterized in that the installation for heat recovery of smoke s gases further provided and installed in the duct located above the sprinkler irrigation water reheating heat exchanger, which is heated at the input path connected to the intermediate heat exchanger, and the output - to the sprinkler.