RU69211U1 - HEAT GENERATOR - Google Patents

Abstract

The utility model relates to heat engineering. The heat generator comprises a chamber with a solution of lithium bromide salt, in communication with a heating source for heating a solution of lithium bromide and evaporation of water from it, an absorber representing a separate volume in the form of a heat exchanger, the inlet of which is connected to the water supply source, and the outlet to the hot water consumer, and a spray gun in the form of a nozzle tube drawn through an absorber connected to a chamber with a solution of lithium bromide salt to spray the evaporated solution onto the surface of a heat exchanger, a cooler representing the heat exchanger in a separate volume with water in the bottom part, the inlet of which is connected to the water supply source, and the outlet with the discharge line of this water, the outlet temperature of which is lower than the temperature of the water at the inlet to this heat exchanger, and the sprayer in the form of a pipe stretched through the cooler with nozzles communicated through a pump with a water collection zone in the bottom of this volume, a pump for creating a vacuum in the volumes, a heater in the form of a heat exchanger, the input of which is communicated by the discharge line to the discharge pump communicated with the don part of a separate volume of the absorber, where a collection zone of the washed surface of the tubular heat exchanger of a solution of lithium bromide salt with a 50% concentration is formed, and the outlet is connected to a chamber with a solution of lithium bromide salt above the level of the latter, while the specified heater is placed in a shell in communication with the exhaust channel hot products from a heating source, in the upper part of the chamber with a solution of lithium bromide there is a water collector communicated by the main with the volume of the cooler, and both of these volumes of images us generally sealed

the case is divided into two volumes by a partition with the message windows of the volumes among themselves. 1 ill.

Description

The utility model relates to heat engineering, in particular to heat generation plants for use in various technological processes or in heating systems. In particular, a utility model considers the design of an absorption bromine-lithium thermal plant (heat generator). It can be used to produce hot water for heating and hot water supply, for heating and cooling process fluids in industry, energy, agriculture, etc.

This type of heat generator is a highly efficient energy-saving equipment for heating various objects and is designed to heat water up to 50-90 ° C, using heat of heating steam with a pressure of up to 0.75 MPa or fuel - natural gas as a source of energy, as well as low-potential waste or natural heat from various sources with a temperature of 20-40 ° C. The share of cheap low-grade heat used in the heat generator to generate useful, higher-grade heat is about 70%. Such heat generators have exceptional consumer properties: high efficiency, environmental friendliness, low noise level during operation, ease of maintenance, long service life, full automation.

The principle of operation of the heat generator is based on the ability of the absorbent solution to absorb water vapor having a lower temperature than the solution. The working substance in the heat generator is water, the absorbent is an aqueous solution of lithium bromide salt. The refrigerant water boils under vacuum in the tube bundle of the evaporator, due to the heat removed from the cooled medium circulating in the tubes (source of low potential heat). Water vapor is absorbed by the absorbent solution on the tube bundle of the absorber with the release of heat, which is removed by the heated water circulating in the tubes. The diluted solution from the absorber is pumped out.

to the generator, where on the tube bundle regeneration (evaporation) of water vapor absorbed in the absorber is carried out, due to the heat of the heating coolant. The condensed water vapor in the condenser is returned to the evaporator, and the concentrated solution to the absorber.

A heat generator is known that contains a boiler plant, a cogeneration turbine unit, steam pipelines, raw, chemically cleaned, feed water with the necessary fittings, direct and return network water pipelines, a heat pump, using an absorption bromide-lithium double-case heat pump consisting of a generator and a condenser located in one casing, absorber and evaporator - in another casing, and the thermocompressor drive, which is located between the smoke exhaust and the chimney and includes the removal of the hog with gas a water heater for heating the circulating water heating the heat pump generator, in addition, the heat pump evaporator is connected to the outlet and inlet pipes of the cooling water of the turbine condenser through the valves, and the absorber and condenser of the heat pump are connected by a hot water pipe and return mains water from the consumer passing in series through the absorber and condenser of the heat pump (RU No. 2278333, F24H 1/00, publ. 2006.06.20)

The disadvantage of this heat generator is its volume due to the construction of nodes and assemblies according to the separation scheme and the resulting large heat losses that reduce the efficiency of the heat generator and increase the energy consumption for the actual process of producing hot water at the outlet. In addition, with such a construction scheme, it is difficult to maintain the operating conditions of individual units unchanged, since with any movement of the thermal or cooled carrier along the communication lines, the achieved parameters are lost, the summation of which ultimately either does not allow the heat generator to stabilize in the mode of dispensing the finished product with the required parameters either leads to

the need to work with increased initial parameters, taking into account losses.

The technical result achieved in this case is to increase thermal efficiency, increase the production of heat carrier at the outlet, reduce heat losses and increase operational safety.

The specified technical result is achieved in that the heat generator contains a chamber with a solution of lithium bromide salt, in communication with a heating source for heating a solution of lithium bromide and evaporation of water from it to 60% of the concentration of this solution, an absorber, which is a tubular heat exchanger placed in a separate volume, the input of which communicated with the source of the return water supply, and the outlet with the consumer of direct hot water, and the atomizer in the form of a tube with nozzles extended through the absorber, communicated through the pump with a chamber with a solution of lithium bromide below the level of the latter for spraying a 60% concentration of this solution on the surface of the heat exchanger, a cooler, which is a tubular heat exchanger placed in a separate volume with water in the bottom, the inlet of which is connected to the water supply source, and the outlet to the drain line of this water , the outlet temperature of which is lower than the temperature of the water at the inlet to this heat exchanger, and the atomizer in the form of a tube with nozzles extended through a cooler, communicated through a discharge pump with a settling zone water in the bottom of this separate volume, a vacuum pump for creating a vacuum in separate volumes and pumping out non-condensable gases, a heater in the form of a tubular heat exchanger, the inlet of which is connected to the discharge line with a discharge pump in communication with the bottom of the separate volume of the absorber, where the collection zone of the washed the surface of the tubular heat exchanger of a solution of lithium bromide salt with a concentration reduced to 50%, and the outlet is in communication with a chamber with a solution of lithium bromide salt above the level of the last o, while the specified heater is placed in a shell in communication with the exhaust channel

hot products from a heating source, in the upper part of the chamber with a solution of lithium bromide there is a water collector, connected by a highway with a heat exchanger channel in the second volume, and both volumes are formed in a common sealed enclosure, divided into two volumes by a partition with the windows of the message between the volumes.

These features are significant and 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 concrete example, which, however, is not the only possible one, but clearly demonstrates the possibility of achieving the required technical result by the given set of features.

Figure 1 - diagram of the heat generator.

The heat generator is a heat power unit that combines a gas heating boiler for heating mains water to a temperature of 95 ° C, designed for reliable heat supply of residential premises in the climatic zone with a minimum outdoor temperature of 50 ° C with a heat pump unit that allows heat energy to be removed from low potential source with a temperature of 20 ÷ 30 ° C to 10 ÷ 15 ° C and convert it into a higher potential coolant having a temperature of 55 ÷ 65 ° C.

The operation of the heat pump in this mode provides heat supply to the rooms at an outdoor temperature of + 8 ° С to -10 ° С (on average for heat losses in residential buildings), which makes up 70% of the heating season for the middle strip. When the outdoor temperature is below -10 ° C, heating of the mains water to the temperature schedule is in separate gas boilers equipped with automation.

The work of a thermochemical heat pump (heat generator) is based on the ability of a concentrated aqueous solution of lithium bromide salt (60%) to absorb (absorb) water vapor with the release of heat as a result of a chemical reaction. Maximum water vapor absorption up to

concentration of a 50% solution of lithium bromide salt. After this, the solution needs to be regenerated, i.e. evaporate part of the water vapor (10%), and return the condensate (by gravity) to the evaporator.

For this purpose, the absorber, where the heating of the network water circulating inside the cupronickel tubes is carried out, for example, in a film heat exchanger (or in a tubular heat exchanger) by combining lithium bromide solution sprayed by the nozzles on the outer surface of the tubes, is combined with an evaporator in one housing. Cold water is sprayed into the evaporator at the lowest possible temperature. Fine atomization provides better vaporization at a given temperature. Therefore, the upper part of the evaporator is in communication with the absorber, in which the absorption of water vapor will occur.

To ensure vaporization at low temperature, the entire heat exchanger will be under a deep vacuum (P = 0.05 ± 0.005 atm), which is provided by a vacuum pump pumping non-condensable gases (O ₂ and CO ₂ ) formed above the surface of the water in the evaporator.

The regeneration (evaporation) of a weakly concentrated solution of lithium bromide salt is carried out in the generator due to the heat from the products of gas combustion during gas heating or steam during steam heating. In the steam space of the generator, a tube bundle of a desuperheater is installed, which will be the second stage of heating the network water after the absorber.

Figure 1 shows an example of a solution to the structural solution of the heat generator.

The heat generator comprises a generator chamber 1 with a solution of lithium bromide 2, a sealed housing 3, divided into two volumes 4 and 5 by a partition 6 with windows for communicating the volumes between each other, an absorber 7 placed in one volume of the housing, a cooler 8 placed in another volume of the housing so that the water vapor formed in the volume of the cooler passes into the volume of the absorber through the windows in the partition, the vacuum pump 9 to create a vacuum in individual volumes and pump non-condensable

gases (O ₂ , CO ₂ ). In this case, a bath 10 for collecting water (condensate) is formed in this part of the volume of the cooler, and a bath 11 for collecting a solution of lithium bromide saturated with water is formed in this part of the volume of the absorber.

The structure of the generator chamber also includes a heating source 12 for heating a solution of lithium bromide and evaporation of water from it in the chamber to a 60% concentration of this solution. As a heating source, a heating combustion chamber can be considered. As a result of fuel combustion, waste hot products (gases) are formed. To organize the combustion process of the fuel, a fan 13 for supplying air to the combustion chamber is provided. The internal volume of the combustion chamber is connected to the gas-tube evaporation bundle 14. Figure 1 shows the combustion chamber, the combustion products from which are discharged through the fire-tube bundle (channels) 14 to the outside and give off heat in the heater 15.

The absorber 7 is a tubular heat exchanger located in a separate volume 16, the inlet 17 of which is connected to a source of return water supply, and the outlet 18 is with a consumer of direct hot water, and the atomizer is in the form of a tube 19 extended through the absorber with nozzles communicated through the pump 20 to the chamber 1 with a solution of lithium bromide salt below the level of the latter for spraying a 60% concentration of this solution on the surface of the heat exchanger 16.

Thus, a solution of lithium bromide salt with a 60% concentration (part of the water from this solution is evaporated) supplied under pressure from the pump 20 from the chamber enters through the tube 19 with nozzles into the body volume 5, in which the heat exchanger 16 is located. Irrigating the surfaces of the heat exchanger 16, this the solution interacts with water vapor and begins to produce heat, which is transferred through the walls of the heat exchanger to the water flowing through this heat exchanger.

At the input 17 of the heat exchanger 16 the return network water with a temperature of 40 ° C is supplied and directly sent to the consumer with a temperature of 60 ° C through the channel in its pipe from the exit 18.

From the exit 18 hot with a temperature of 55 ° C through the output pipe 21 can be passed through the chamber 1 with lithium bromide, in which this pipe and its water are heated to a temperature of 60 ° C, from where hot water enters the consumer 22.

By gravity from the surface of the heat exchanger 16, a water-saturated solution of lithium bromide to a concentration of 50% is discharged into the bathroom to collect this solution, from where the solution is returned to the chamber 1 by means of the injection pump 23 communicated with this bottom part of the absorber 7 and merges above the level of this solution in the chamber.

Since in the process of interaction with water vapor, lithium bromide solution lowers its temperature, it is heated before returning to the chamber. To do this, a heater 15 is used in the form of a tubular heat exchanger 24, the input of which is connected to the discharge line of the injection pump 23, connected to the bottom of a separate volume 5 of the absorber 7, and the output is communicated with the fire tube 14. The heat exchanger 24 of the heater is placed in the shell 25 in communication with the channel 14 of the removal of hot gases from the chamber with a solution of lithium bromide so that the spent hot gases from the chamber enter the cavity of the shell, transfer heat to the heat exchanger 24 and thereby heat the solution. The gases cooled from the shell are then removed to the atmosphere.

The cooler 8 is a tubular heat exchanger 26 located in a separate volume 4 and with water in the bottom, the inlet 27 of which is connected to a water supply source with a temperature of 20 ° C, and the outlet 28 is with a drain pipe for this water, the outlet temperature of which is lower than the water temperature the entrance to this heat exchanger (for example, 15 ° C), and the atomizer in the form of a nozzle tube 29 stretched through the cooler, connected through the pressure pump 30 to the water collection zone in the bottom of this separate volume. Thus, in a given volume for certain

pressure and temperature of the water vapor forms, which enters the adjacent volume, where the solution of lithium bromide is saturated with water with the release of heat.

In the upper part of the chamber 1 with a solution of lithium bromide, a water collector 31 is placed, connected by a line 32 with a volume of 4. When vapor is evaporated in the form of condensate, it is collected in the water collector 31, from where it is fed back to the cooler system.

The absorber in the heat exchanger uses a nickel silver tube with fins made of nickel silver, and the evaporator uses a brass tube with fins made of copper plane trees.

The heat generator operates as follows.

The combustion process is formed in the combustion chamber or hot gases are passed through the channel in the chamber and the lithium bromide solution is heated in chamber 1. The evaporated water condenses in the catchment 31. The vacuum is carried out in the housing due to the operation of the vacuum pump 9.

Water is supplied to the heat exchanger 26 of cooler 8 with a temperature of 20 ° C and washed on its surface with water from the bottom of the housing in the volume where this heat exchanger is installed. When the set pressure and temperature are reached, water vapor is formed in this volume, which enters through the windows in the partition into the neighboring volume, where the absorber is located.

At the same time, return water with its own temperature is supplied through the heat exchanger 16 of the absorber.

Under pressure, the pump 20 serves from the chamber 1 a solution of lithium bromide of 60% concentration and irrigate them with the surface of the heat exchanger 16 in the volume of the housing for the absorber. The solution is saturated with water and heat is transferred to the water flowing through the heat exchanger 16. At the outlet of this heat exchanger we get hot water with a temperature of 55 ° C, which is sent for additional heating to the desuperheater and from there this water enters the consumer. The lithium bromide solution collected in the bottom of the volume 7 of the housing is pumped back into the chamber 1 through

a heater 15, the heat of which is generated by hot gases - combustion products in the combustion chamber 12.

Water from the reservoir 31 by gravity returns volume 4.

This utility model is industrially applicable, can be manufactured using well-known technologies for constructing heat pumps and steam power plants.

Claims (1)

A heat generator containing a chamber with a solution of lithium bromide salt, in communication with a heating source for heating a solution of lithium bromide and evaporation of water from it to 60% of the concentration of this solution, an absorber, which is a tubular heat exchanger placed in a separate volume, the inlet of which is connected to a source of return water supply , and the outlet with the consumer is direct hot water, and the atomizer is in the form of a tube with suction pipes stretched through the absorber, connected through a pump with a chamber with a solution of lithium bromide salt below I am the last one for spraying a 60% concentration of this solution on the surface of the heat exchanger, a cooler, which is a tubular heat exchanger placed in a separate volume with water in the bottom, the inlet of which is connected to the water supply source, and the outlet - to the drain line of this water, the temperature of which is at the outlet below the temperature of the water at the inlet to this heat exchanger, and the atomizer in the form of a tube with nozzles extended through the cooler, communicated through a pressure pump with a water collection zone in the bottom of this separate volume, in a vacuum pump for creating a vacuum in separate volumes and pumping out non-condensable gases, a heater in the form of a tubular heat exchanger, the inlet of which is connected to the discharge line of the discharge pump, connected to the bottom of a separate absorber volume, where a collection zone of the washed surface of the tubular heat exchanger of lithium bromide salt solution with 50 % concentration, and the output is communicated with a chamber with a solution of lithium bromide salt above the level of the latter, while the specified heater is placed in a shell communicated with a channel for the removal of spent hot products from a heating source, in the upper part of the chamber with a solution of lithium bromide salt there is a water collector connected by a main with a cavity of the volume of the cooler, and both of these volumes are formed in a common sealed enclosure, divided into two volumes by a partition with message windows of volumes between by myself.