UA78177C2 - Heat utilizer - Google Patents

Abstract

The invention relates to heat engineering and can be used in equipment for heating and for humidification of blast air of gas-consuming boilers plants in heat engineering. A heat utilizer has the upper and the lower chambers placed in vertical body and separated with partition with draining unit, this is connected to pallet. In the upper chamber sprinkler is placed, heat exchange nozzle and surface heat exchanger, this is placed in the branch pipe for air discharge and connected to sprinkler. The lower chamber has three heat exchangers included to gas section. The second in direction of gas flow heat exchanger additionally is included to air section, and through air duct it is connected to the inlet to heat exchange nozzle. The invention provides deeper cooling of smoke gases with cold air and reguired air heating before it comes to heat exchange nozzle.

Description

Description of the invention

The useful model relates to thermal power engineering and can be used in the equipment for heating and 2 humidification of the ducted air of gas-consuming boiler plants.

A heat recovery device is known, which contains upper and lower chambers located one above the other in a vertical housing, separated from each other by a partition with a drainage device, and the upper chamber is equipped with an air supply nozzle and an air outlet nozzle, a spray device and a heat-mass exchange nozzle placed between the spray device and a partition, and between the nozzle and nozzles there are limiting gratings, in the lower chamber, which is equipped with a tray connected to a drainage device and gas inlet and outlet nozzles, surface heat exchangers are placed, an additional solid partition is placed between the heat exchangers and the tray, and in the side on the wall of the case above the partition there is a nozzle for draining condensate (patent of Ukraine Mo45766, IPK E28С3/06, 2004.

Disadvantages of the known heat exchanger are: low efficiency due to the absence of an external consumer of hot water due to the insufficient moisture content of the air that is humidified, which is caused by the low temperature of the air at the entrance to the contact chamber; the danger of moisture condensation in the air path of the boiler plant in the section from the heat exchanger to the burner, which is caused by the high (about 10095) relative humidity of the air at the exit from the heat exchanger; use of high-potential coolant produced by the boiler unit for drying cooled gases.

The closest analog in terms of technical essence and the result to be achieved to the claimed device, selected as a prototype, is a heat recovery device that contains upper and lower chambers located one above the other in a vertical housing, separated from each other by a partition with a drainage device, and the upper the chamber is equipped with air inlet and outlet nozzles, in which there is one surface heat exchanger, a spray device and a heat exchange nozzle placed between the spray nozzle with the device and the partition, between the nozzle and the nozzles there are limiting grilles, in the lower chamber which (U is equipped with a tray and inlet nozzles and flue gas removal, the first, second and third surface heat exchangers are placed sequentially along the flow of flue gases, an additional solid partition is placed between the heat exchangers and the tray, a condensate drain nozzle is placed in the side wall of the housing above the partition, the circulation circuit of the intermediate heat carrier connecting passing the tray through the second, first and third heat exchangers with the inlet of the surface heat exchanger placed in the air outlet pipe, the drainage device - with the tray, and the outlet of the second heat exchanger - with the spraying device | patent of Ukraine Mo56591,

IPC Eg28S3/06, 2003.1. --

Disadvantages of the known heat utilization device are: low efficiency due to insufficient cooling of flue gases. o warm water in the second heat exchanger; increased metal density Due to the indirect heating of air 325 before entering the heat-mass exchange nozzle with the use of an intermediate coolant and, accordingly, the increased area of the heating surface.

The useful model is based on the task of improving the heat exchanger, in which, by using a second heat exchanger to preheat the air before entering the heat and mass exchange nozzle, a deeper cooling of the flue gases is ensured directly by cold air and extraction of the surface heat exchanger 50, placed in the air supply pipe of the upper chamber with the combination of its From c functions with the functions of the second heat exchanger of the lower chamber. This increases efficiency

I" of the heat-utilizer and its metal density decreases.

The task is solved by the fact that in the heat exchanger, which contains the upper and lower chambers, they are located one above the other in a vertical housing, separated from each other by a partition with a drainage device, and the upper chamber is equipped with an air inlet pipe and an air outlet pipe, in which the surface a heat exchanger, a spraying device and a heat exchange nozzle placed between the spraying device and the partition, limiting grids are installed between the nozzle and nozzles, in the lower chamber, which is equipped with flue gas inlet and outlet nozzles and a pallet, the first, second and third surface heat exchangers, an additional continuous partition is installed between the heat exchangers and the -I 20 tray, a condensate drain pipe is placed in the side wall of the housing above the partition, the circulation circuit of the intermediate coolant connecting the tray through the first and third heat exchangers of the lower chamber with the inlet ohm of the surface heat exchanger placed in the air outlet of the upper chamber, and the drainage device - with a tray, according to the useful model, the lower chamber is additionally equipped with air inlet and outlet pipes, which are connected to the second surface 22 heat exchanger, the air outlet pipe of the lower chamber is connected an air duct with an air supply nozzle

GF) of the upper chamber, and the output of the surface heat exchanger, placed in the air outlet of the upper chamber, is connected to the spraying device. o The proposed design ensures constant cooling of the flue gases with ducted air due to the fact that cold air drawn from the environment passes through the second flue gas surface heat exchanger with the help of additionally installed 60 air inlet and outlet nozzles of the lower chamber. The use of the proposed design allows reducing the temperature of flue gases in front of the third surface heat exchanger of the lower chamber. At the same time, due to the increase in the use of the heat of the gases, the efficiency of the heat exchanger increases, and due to the decrease in the dew point temperature of the flue gases due to the additional release of condensate from the gases, the loss of heat for heating the gases in the third surface heat exchanger of the lower chamber is reduced, i.e. the loss to the heat exchanger’s own needs,

as a result of which its effectiveness also increases.

Air heated in the second surface heat exchanger of the lower chamber enters the upper chamber through the air outlet pipe through the air duct and the air supply pipe of the upper chamber and does not require additional heating at the entrance to the upper chamber.

The use of direct heat transfer instead of a system of heat exchangers with an intermediate heat carrier to heat the air before it enters the heat mass transfer nozzle of the heat exchanger provides a reduction in the total surface area of the heat exchanger and, thus, its metal content.

The essence of the proposed invention is explained by the drawing, which shows the circuit of the heat exchanger. 70 The heat exchanger consists of an upper chamber 1 and a lower chamber 2, which are placed in a vertical housing

With and are separated from each other by a partition 4. The upper chamber 1 is equipped with a nozzle 5 for air supply and a nozzle 6 for air removal. A heat exchanger 7 is built into the air outlet nozzle 6. In the upper part of the upper chamber 1, a sprinkler device consisting of a collector 8 and irrigation pipes 9 is installed. A heat exchange nozzle 10 is placed between the sprinkler device and the partition 4, which is supported on the side of nozzles 5 and 6 by limiting grids 11 and 12. A drainage device 13 is mounted in partition 4.

The lower chamber 2 of the heat exchanger is equipped with a flue gas supply pipe 14 and a flue gas outlet pipe 15, as well as an air inlet pipe 16 and an air outlet pipe 17. The nozzle 17 of the air outlet of the lower chamber is connected by an air duct 18 to the nozzle 5 of the air supply of the upper chamber. The lower chamber 2 is partially divided by a vertical partition 19 into the lowering and lifting gas ducts. The first heat exchanger 20 in the flow of flue gases is placed in the downward flue 2o, and the heat exchanger 21 is the third in the flow of flue gases. Under the heat exchangers 20 and 21, between the air inlet nozzle 16 and the air outlet nozzle 17, the second two-way heat exchanger 22 is placed in the flow of flue gases. In the lower part of the lower chamber 2 there is an additional solid partition 23 and a tray 24 with hydraulic valves 25 and 26. In the side wall of the housing above the partition 23 there is a nozzle 27 for draining condensate. The tray 24 is sequentially connected through the control valve 28, the first heat exchanger 20 in the course of the flue gases, the third heat exchanger 21 in the course of the flue gases of the lower chamber and the heat exchanger 7 of the upper chamber are connected to the collector 8 of the spraying device. at);

The heat exchanger 7 of the upper chamber is equipped with a bypass pipeline 29 with a control valve 30.

Drainage device 13 is connected to tray 24 by pipeline 31.

The heat exchanger works as follows. The humidified flue gases from the boiler enter the lower chamber 2, located in the housing 3, through the nozzle 14, pass through the first heat exchanger 20, where they are cooled, then pass in two passes through the second heat exchanger 22, where they are further cooled with the condensation of part of the water vapor, and then they are heated in the third "- heat exchanger 21 and through the pipe 15 they leave the heat exchanger. The resulting condensate is removed from the heat recovery unit through pipe 217. co

Water from the tray 24 is taken by the pump and pumped first through the first heat exchanger 20 of the lower chamber, where it is heated, then through the third heat exchanger 21, where it is cooled, and further through the heat exchanger 7 of the upper chamber, where it is further cooled, and enters the collector 8 of the spraying device. Next, through the irrigation pipes 9, water enters the upper chamber 1 and, flowing down the heat exchange nozzle 10, cools with partial evaporation, collects on the partition 4 and through the drainage device 13 through the pipeline 31, "passing the hydraulic seal 26, enters the pallet 24. Then the cycle is repeated. Air from the air inlet 16 of the lower chamber enters the second heat exchanger 22 along the flow of flue gases, where it is heated, then through the air outlet 17, air duct 18, air inlet 5)" and the limiting grid 11 enters the upper chamber 1, passes through the heat exchange nozzle 10, where it is heated and humidified, and through the limiting grid 12, the heat exchanger 7 of the upper

The chamber, where it is reheated, and the pipe would be diverted from the heat exchanger. The parameters of exhaust gas and heated air are adjusted using control valves 28 and 30. (ee)

Claims (1)

The formula of the invention - , what, , , , - Heat exchanger, which contains the upper and lower chambers, located one above the other in a vertical housing, "M are separated from each other by a partition with a drainage device, and the upper chamber is equipped with an air supply nozzle and an air outlet nozzle, which houses a surface heat exchanger, a spray device and a heat exchange nozzle placed between the spray device and the partition, and between the nozzle and the nozzles, limiting grilles are installed , in the lower chamber, which is equipped with flue gas inlet and outlet pipes and a tray, placed sequentially along the flow of flue gases (F) the first, second and third surface heat exchangers, an additional GI solid partition, and in the side wall of the case above the partition there is a condensate drain nozzle, a circulation circuit of the intermediate heat carrier connecting the tray through the first and third heat exchangers to the entrance of the surface heat exchanger located in the air outlet nozzle of the upper chamber, and a drainage device to the tray, which differs in that the lower chamber is additionally equipped with air inlet and outlet nozzles, which are connected to the second surface heat exchanger, the air outlet nozzle of the lower chamber is connected by an air duct to the air supply nozzle of the upper chamber, and the outlet of the surface heat exchanger placed in the air outlet nozzle of the upper chamber , connected to the spraying device. b5