RU65618U1 - WASTE HEATER OF GAS-FUEL COMBUSTION PRODUCTS - Google Patents

Abstract

The utility model relates to a power system. A heat utilizer of gaseous fuel combustion products comprising a low-pressure economizer including a contact water heater in communication with a gaseous fuel combustion product gas duct and through which a water passage is passed, and a heat and mass transfer apparatus in communication with a gaseous fuel combustion product outlet channel from the contact water heater and configured to function of mass transfer of combustion products of gaseous fuels and separation of non-condensable gases directed by a smoke exhauster for subsequent discharge to the atmosphere or neutralizer. In the utilizer, the water passage pipe connected to the source of cold water is first passed through the cavity of the contact water heater at the inlet of the heat and mass transfer apparatus for partial condensation of water vapor from the combustion products, then it is passed through the cavity of the contact water heater communicated by the inlet with the gas duct of the combustion products of gaseous fuel to cool the combustion products to temperature, which does not allow the formation of dew points on cooling surfaces, and then passed through an additional contact Heater for communication with the consumer of hot water. The heat and mass transfer apparatus in the lower part of the mass transfer chamber is made with a device for the formation of a finely dispersed fraction of cold water sprayed on the separation nozzles to form condensation centers for water vapor of the gas products of combustion, while the water collection zone in this chamber is communicated by a pipeline through the pump with the cavity of the heat exchange apparatus, which the output is communicated with a device for the formation of a finely divided fraction of cold water. 1 ill.

Description

The utility model relates to the power system and can be used in the modernization of thermal power plants and heating boilers burning natural gas as fuel.

A device for heat recovery of exhaust gases is known, consisting of several heat exchangers connected in parallel, the lower part of which is designed to collect and settle condensate, and the upper one is to remove exhaust gases and supply an intermediate liquid medium to the irrigation device, as well as from a smoke exhauster and chimney (SU No. 1359556, CL F22B 33/18, 1986).

A heat recovery plant is known, which includes a contact heat exchanger, a compressor, a pressure economizer, a condensing heat exchanger, a moisture collector, a separator and a turboexpander (SU No. 1089351, class F22B 1/18, 1982).

The flue gases in this unit enter the contact heat exchanger, where they are cooled by direct contact with irrigated water. Cooled gases are compressed in a compressor and cooled in a pressure economizer with the utilization of their heat. In the heating path of the condensing heat exchanger, the gases are cooled down with the release of droplet moisture, which is additionally released in the separator. In a turboexpander, gas expands to produce useful power. The expansion of gases in a turboexpander is accompanied by their cooling. Then the gases are heated in the heat exchanger and the chimney is removed. The condensate extracted from the combustion products is sent to a contact heat exchanger.

The installation achieves the utilization of the heat of the combustion products due to condensation of water vapor, however it has a complex circuit design in which there is a compressor, a turboexpander, a contact chamber with forced atomization and a number of heat exchangers. Indicated mechanisms

leads to additional energy costs necessary to drive them and make up for losses associated with the transportation of combustion products to a turboexpander with their release into the environment. The feasibility of using a compressor with a turboexpander to increase the efficiency of heat transfer is ineffective. In a heat exchanger, where the convective form of heat exchange predominates, the overheating of water vapor is first removed, and only then the excess water is condensed, which moistens the combustion products in the contact chamber. In the known device, only the condensation process is considered. The heat transfer process in the heat exchanger proceeds at P = const.

In the heat exchanger, further cooling of water vapor from the combustion products occurs, the degree of cooling of which depends on the temperature of the combustion products at the outlet of the turbine expander. It is determined by the final pressure, which in this case is not lower than atmospheric, and, in addition, takes only positive values. Condensation of water vapor occurs in a turboexpander. This condensate again evaporates in the heat exchanger and is removed to the outside with combustion products.

Known heat recovery unit containing a contact water heater connected to the boiler flue in front of the exhaust fan and equipped with a bypass flue having a damper and a decarbonizer of heated water with an air exhaust line (SU No. 1128063, F24H 1/10, F22B 33/18, 1984). The disadvantage of this utilizer is its lack of effectiveness in using the latent heat of vaporization of water vapor present in the fuel combustion products.

The closest in technical essence to the proposed technical solution is a heat recovery unit containing a contact water heater connected to the flue of the boiler unit in front of the exhaust fan and equipped with a bypass flue having a damper, characterized in that it comprises a cleaning chamber, a cyclone, a heat exchange pipe and two cellular heat exchangers, one of which is the main one, which are installed parallel to the bypass duct, while the cleaning chamber with vertical

by partitions attached alternately to its bottom and ceiling, respectively, as well as with rows of funnels fixed in its bottom and placed in a dust collector, installed between the vertical part of the duct and the contact water heater and connected through a sleeve to the cyclone, which is installed on the duct in front of the cellular heat exchanger, exit the contact water heater is pneumatically connected to the gas passage coil associated with the main honeycomb heat exchanger and the lower part of the gas duct, and a flapper is installed on the upper joint duct and the cleaning chamber, moreover, said heat exchange tube with fan pins installed in the duct before the cleaning chamber and fluidly communicates through the air with a contact heater (RU №2209366, F22B 1/18, publ. 2003.07.27).

The disadvantage of this known solution is its structural complexity and lack of efficiency in the implementation of the process of heat transfer of combustion products to a liquid heat carrier used for heating and hot water supply of consumers.

This utility model is aimed at solving the technical problem of implementing an economical method of condensing water vapor from fuel combustion products while preserving and further beneficial use of the heat of the latent energy of vaporization.

The technical result achieved in this case is to increase the efficiency of power plants by utilizing the latent heat of vaporization of water vapor present in the fuel combustion products and using this heat energy for heating and hot water supply of consumers.

The specified technical result is achieved in that a heat utilizer of gaseous fuel combustion products comprising a low-pressure economizer including a contact water heater in communication with a gaseous fuel combustion products duct and through which a water passage is passed, and a heat and mass transfer apparatus in communication with a gaseous combustion products outlet channel fuel from

contact water heater and performed with the function of mass transfer of gaseous fuel combustion products and separation of non-condensable gases sent by the exhaust fan for subsequent exhaust into the atmosphere or neutralizer, while the heat and mass transfer device at the inlet is equipped with dampers for regulating the passage section of the movement channels in the direction of the exhaust fan and in the direction of the mass transfer zone, equipped the heat exchanger communicating with the cold water source, the water passage pipe is first passed through the cavity an active water heater at the inlet of the heat and mass transfer apparatus for partial condensation of water vapor from the combustion products, then passed through the cavity of the contact water heater communicated by the inlet of the combustion products of gaseous fuels to cool the combustion products to a temperature that prevents the formation of dew points on the cooling surfaces, and then allowed through an additional contact water heater to communicate with the consumer of hot water, and the heat and mass transfer device in the lower part of the chamber The exchange is performed with a device for the formation of a finely dispersed fraction of cold water sprayed on the separation nozzles to form centers of condensation of water vapor of the gas products of combustion, while the water collection zone in this chamber is communicated by a pipeline through the pump with a cavity of the heat exchanger, which is in communication with the device for forming the finely dispersed cold water fractions.

These features are significant and are interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

The present utility model is illustrated by a specific example of execution, which, however, is not the only possible one, but clearly demonstrates the possibility of achieving the desired technical result.

Figure 1 is a schematic diagram of a heat recovery apparatus for the combustion products of gaseous fuels.

According to this utility model, the design of a heat utilizer of gaseous fuel combustion products is considered, which works on the principle of utilizing the latent heat of vaporization of water vapor present in the fuel combustion products and the use of this thermal energy for heating and hot water supply of consumers.

The utility model is based on the task of implementing a method for condensing water vapor from fuel combustion products with the conservation and further useful use of the heat of the latent energy of vaporization.

For this, the utilizer performs an up-and-coming two-stage cooling of the combustion products: “dry” using inexpensive non-corrosion resistant materials and “wet” with partial condensation on corrosion-resistant cooling surfaces. A decrease in the portioned pressure of the water vapor of the combustion products at the inlet to the heat and mass exchanger with a decrease in the kinetic energy of the vapor molecules and the creation of finely dispersed centers for condensation of water vapor from atomized cold water provides sufficient heat and mass transfer to condense the water vapor and heat the cooling water with a hot condenser while maintaining the vapor condensation heat. Drained non-condensable gases: nitrogen and carbon dioxide are removed by a smoke exhauster into the chimney.

Below is an example of a specific implementation of the utility model (figure 1).

The heat utilizer of the products of combustion of gaseous fuel contains a low-pressure economizer, which includes a contact water heater in communication with the gas duct 1 of the products of combustion of gaseous fuel, and a heat and mass transfer apparatus 2 in communication with the channel for the exit of the products of combustion of gaseous fuel from the contact water heater and configured to mass transfer the products of combustion of gaseous fuel fuel and separation of non-condensable gases sent by the exhaust fan 3 for subsequent exhaust into the atmosphere or neutralization torus.

The heat and mass transfer apparatus 2 at the inlet is equipped with shutters 4 for regulating the passage section of the movement channels in the direction of the exhaust fan 3 and in the direction of the mass transfer zone 5.

The contact water heater in communication with the heat and mass transfer apparatus 2 is made in the form of two separate water heaters 6 and 7, the cavities of which are interconnected to pass the combustion products of gaseous fuel in the direction from the gas duct 1 of these products to the outlet channel of these products into the heat and mass transfer apparatus, while one of the water heaters is connected with the gas duct of the combustion products of gaseous fuel with the formation of stage I, and the cavity of the other is connected with the cavity of the first with the formation of stage II.

The utilizer is equipped with an additional heat exchanger 8.

The heat and mass transfer apparatus in the lower part of the mass transfer chamber is made with a device for the formation of a finely dispersed fraction of cold water sprayed on the separation nozzles 9 to form centers of condensation of water vapor of the combustion gases in the form of water collected in the lower part of the chamber. In this case, the water collection zone in this chamber is communicated by a pipeline 10 through a pump 11 with a cavity of an additional contact water heater 8, which at the outlet is in communication with a device for the formation of a finely divided fraction of cold water.

The water passage pipe 13 connected to the cold water source 12 is first passed through the cavity of the contact water heater 7 for partial condensation of water vapor from the combustion products, then it is passed through the cavity of the contact water heater 6 connected by the inlet to the gas duct 1 of the combustion product of gaseous fuel to cool the combustion products to a temperature , which does not allow the formation of dew points on cooling surfaces, and then passed through an additional contact water heater 8 for communication with the consumer 14 cm hot water.

In the heat exchanger in the first stage I, the products are cooled to a temperature that does not allow the formation of a dew point on

cooling surfaces. The second stage II of the water economizer, operating under conditions of partial condensation of water vapor from the combustion products, is located in the inlet chamber of the heat and mass transfer apparatus 2. The removal of part of the heat of the combustion products of the fuel to the heat and mass transfer apparatus can reduce the kinetic energy of the vapor molecules and reduce the distance between the molecules, which will subsequently be promote better condensation of water vapor. Combustion products containing more than 10% water vapor enter the lower part of the heat and mass transfer apparatus and enter the mass transfer with a finely divided fraction of cold water sprayed on the separation nozzles. Microdroplets of atomized fine cold water will be the centers of flue gas water vapor condensation. Condensable water vapor, mixed with cooling water, heat it to a temperature above 90 ° C. Non-condensable gases: СО ₂ and N ₂ are removed by a smoke exhauster into the chimney. Hot water is pumped by the pump 11 through the heat exchanger 8, where it gives its heat to the heat carrier used for heating and hot water supply. Chilled water after heat and mass transfer apparatus 2 is returned back to the cycle to condense water vapor from the combustion products.

The excess part of the water is used in the scheme of the CHPP or boiler room for industrial or economic purposes. Drained non-condensable gases: nitrogen and carbon dioxide are removed by the exhaust fan 6 into the chimney. For this, at the output of the heat exchanger 8, the communication line with the device for the formation of a finely divided fraction of cold water is made with the device 15 for draining the excess part of the water.

Thus, the efficiency of the thermal installation of a thermal power plant or a boiler room is increased due to the utilization of heat and fuel combustion products by using this energy for heating and hot water supply to consumers.

This industrial model is industrially applicable, can be based on the implementation of the steam condensation method described in the book:

“Turbines of thermal and nuclear power plants. Ed. A.G. Kostyuk, B. B. Frolov. M.: Publishing House MPEI, 2001 "p. 213-237. This method involves exposing the steam by removing heat from it by transferring heat to the cooling water through the surface of the tubes inside which it circulates. In this case, the latent heat of conversion during condensation of water vapor is perceived by a low potential source and is discharged into the environment - water or air.

Claims (2)

1. A heat utilizer of gaseous fuel combustion products, comprising a low-pressure economizer including a contact water heater in communication with a gaseous fuel combustion products duct and through which a water passage is passed, and a heat and mass transfer apparatus in communication with a gaseous fuel combustion products outlet channel from the contact water heater and made with the function of mass transfer of combustion products of gaseous fuels and separation of non-condensable gases directed by a smoke exhaust fan For subsequent discharge to the atmosphere or the neutralizer, the heat-mass transfer apparatus at the inlet is equipped with dampers for regulating the passage section of the displacement channels in the direction of the smoke exhauster and in the direction of the mass transfer zone, characterized in that it is equipped with a heat exchanger, the contact water heater in communication with the heat-mass transfer apparatus is made in in the form of two separate water heaters, the cavities of which are interconnected for the passage of combustion products of gaseous fuel in the direction from the gas duct of these products to the outlet channel of these products, the water passage pipe connected to the cold water source is first passed through the cavity of the contact water heater at the inlet of the heat and mass transfer apparatus for partial condensation of water vapor from the combustion products, then it is passed through the cavity of the contact water heater communicated by the inlet to the gas duct of the combustion products of gaseous fuel, for cooling the combustion products to a temperature that does not allow the formation of dew points on cooling surfaces, and then let through a heat exchanger for communication with a hot water consumer is cut, and a heat and mass exchanger in the lower part of the mass transfer chamber is made with a device for forming a finely divided fraction of cold water sprayed on separation nozzles to form centers of condensation of water vapor of the combustion gas products, while the water collection zone in this chamber communicated by a pipeline through a pump with a cavity of a heat exchanger, which at the outlet is in communication with a device for forming a finely divided fraction of cold water. 2. The utilizer according to claim 1, characterized in that at the outlet of the heat exchanger the communication line with the device for the formation of a finely divided fraction of cold water is made with the device for draining the excess part of the water.