KR101606282B1 - The condensing heat recovery system for high temperature moist gas using heat-recovery-type absorbent fluidized bed and dry-air-dehumidifing-type absorbent fluidized bed - Google Patents

Abstract

The present invention relates to a condensing heat recovery system for a high temperature moist gas using a heat-recovery-type absorbent fluidized bed and a dry-air-dehumidifying-type absorbent fluidized bed comprising: a heat-recovery-type absorbent fluidized bed unit having an exhaust gas inlet into which an exhaust gas of high temperature produced in a combustion device at one side flows, a first body with an exhaust gas outlet through which the exhaust gas flows out in the form of dry gas at the other end, a first porous plate placed inside of the first body to pass the exhaust gas that flowed in, and a first absorbent fluidized bed which consists of an adsorbent in the upper side of the first porous plate and absorbs steam of the exhaust gas and latent heat and sensible heat of the exhaust gas; a feed water heater in which feed water is heated by a high-temperature absorbent of low concentration discharged through the exhaust gas outlet of the heat-recovery-type absorbent fluidized bed unit; and a dry-air-dehumidifying-type absorbent fluidized bed unit having a dry air inlet into which dry air flows at one side, a second body with a moist air outlet through which moist air absorbing moisture from the absorbent is discharged at the other end, a second porous plate placed inside the second body to pass the exhaust gas that flowed in, and a second absorbent fluidized bed which consists of an adsorbent passing the feed water heater in the upper side of the second porous plate, discharges part of the moisture to the dry air side and recovers the absorbent.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a high temperature wet gas condensate heat recovery system using a heat recovery type absorbent fluidized bed and a dry air dehumidifying absorption fluid bed,

The present invention relates to a high temperature wet gas condensate heat recovery system using a heat recovery type absorbent fluidized bed and a dry air dehumidifying absorbent fluidized bed.

For recovering the waste heat of conventional combustion exhaust gas, a water fluidized bed heat exchanger was used to recover the latent heat of condensation and sensible heat of the steam contained in the high temperature corrosive exhaust gas. In addition, the conventional heat medium fluidized bed heat exchanger can produce hot water of about 80 ^o C, but only the sensible heat is mainly recovered.

1 is a cross-sectional view of a conventional water fluidized bed heat exchanger. 1, the water fluidized bed heat exchanger is provided with a perforated plate 3 on the bottom surface of a heat exchange tube 2 provided in an inner bottom portion of a rectangular shell 1, (4) are provided.

A rectangular external body 1a having an exhaust inlet port 6 is provided at one side of the rectangular shell 1 so as to form an exhaust gas induction passage 5 so that the exhaust gas guided at the bottom surface of the perforated plate 3 The bottom plate 1b of the quadrangular outer member 1a is formed so as to be inclined so as to form the passages 5a and the connecting portions of the quadrangular outer member 1a and the bottom plate 1b are connected in an angular manner as shown in Fig.

When a proper amount of water is supplied through the water supply pipe 7a with the automatic control valve 7 connected to one side of the upper part of the rectangular shell 1 and the water supply pipe 7a is stopped, 5a and the square body 1 and flows into the interior of the rectangular shell 1 through the perforated plate 3 by the exhaust gas pressure supplied at the time of operation of the boiler So that a water fluidized bed is formed between the heat exchange tubes 2. An exhaust gas bypass pipe 9 is provided at an upper portion of the quadrangular outer member 1a so as to communicate with the exhaust gas outlet 8 so that a part of the hot exhaust gas passes through the bypass pipe 9 Is mixed with the cooled exhaust gas in the water saturated state that flows into the exhaust gas outlet (8) and passes through the water droplet removing filter (4), so that the exhaust gas saturated with moisture is reheated and exhausted from the exhaust gas outlet And the condensation phenomenon of water due to the cooling of the gas can be prevented.

However, in the conventional water fluidized bed heat exchanger, since the temperature of the exhaust gas in the fluidized bed is limited to the saturation temperature of the humidifier in the water fluidized bed, the temperature of the water in the heated tub set in the fluidized bed is also limited below this saturation temperature. Therefore, in the case of recovering waste heat from a common boiler flue-gas, the saturation temperature of the humidifier in this fluidized bed is about 55 ^° C or less. Thus, when only a water fluidized bed heat exchanger is used, the feed water temperature through the fluidized bed is limited to about 55 ^o C or less.

In addition, the exhaust of the saturated flue gas at the outlet of the water fluidized bed may cause the problem of white smoke.

The absorption column and the exhaust gas are in direct contact with each other by using a filling tower for collecting the heat of condensation of the flue gas, so that the latent heat of condensation can be recovered by absorbing the water vapor in the flue gas. In this case, water is evaporated by heating the absorption liquid using steam to regenerate the absorption liquid.

That is, when the high temperature flue gas passes through the heating medium fluidized bed as in the conventional method, high temperature water is produced which is higher than the saturation temperature of the flue gas, but the condensation heat can not be recovered because there is no absorption of water vapor in the heating medium fluidized bed.

In addition, in the existing water fluidized bed heat exchanger, the water production temperature in the water fluidized bed heat exchanger is limited to the saturation temperature of the exhaust gas. And the exhaust of the saturated flue gas at the outlet of the water fluidized bed may cause the problem of white smoke.

That is, in order to recover the heat of condensation heat of the hot wet gas discharged from the heat facility, the absorption liquid and the hot wet gas are mainly brought into direct contact with each other in the filling tower to absorb the water vapor in the wet gas, and the sensible heat of the hot wet gas and the latent heat of condensation can be simultaneously recovered . In this case, the temperature of the absorption liquid increases from about 70 ^o C to 80 ^o C, which can produce hot water at about 70 ^o C. However, a process of heating the absorption liquid for regeneration of the absorption liquid and evaporating the water is required, and usually, a separate expensive steam is used.

In the conventional case, an absorption liquid having a relatively large capacity to absorb water vapor in the flue gas was used in order to recover the waste heat of the wet gas containing the high-temperature water vapor discharged from the thermal equipment and produce hot water at a high temperature. In the condensation heat recovery system using such an absorption liquid, it is further required to regenerate the absorption liquid which absorbs water vapor in the humidifier.

That is, in the case of the conventional absorption type heat recovery system, the absorption liquid is heated by the high-temperature steam to regenerate the absorption liquid, and the steam is evaporated and regenerated. As a result, the economical efficiency of the condensation heat recovery system is deteriorated and the absorption liquid having a high evaporation temperature can not be used.

Korean Patent No. 1118509 Korea Patent No. 0242226 Korean Patent No. 0578109 Korea Patent No. 0213303 Korea Patent Publication No. 2013-0096317

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a method and apparatus for recovering condensation heat by absorbing water vapor in a high- , The dry gas is discharged and the absorption liquid is regenerated by using external dry air to regenerate the absorption liquid without boiling evaporation using conventional steam for regeneration of the absorption liquid so that the amount of high- And to provide a heat and moisture condensed heat recovery system using a heat recovery fluidized bed and a dry air dehumidifying absorption fluidized bed capable of improving the performance and economy of the recovery system.

According to an embodiment of the present invention, in order to regenerate the absorbing liquid absorbing water vapor in the absorbing fluidized bed of the heat recovery process, the absorbing liquid and the external dry air are brought into direct contact with the regenerating absorbing fluid bed to effectively remove water vapor of the absorbing liquid, The present invention has been made to solve the above problems, and it is an object of the present invention to provide a heat recovery type condensate heat recovery system using a heat recovery type fluidized bed fluidized bed and a dry air dehumidifying type absorption fluidized bed which can solve the problem of using a large amount of expensive steam for regeneration of absorbed fluid.

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are not intended to limit the invention to the precise form disclosed. It can be understood.

SUMMARY OF THE INVENTION A first object of the present invention is to provide a high temperature wet gas condensate heat recovery apparatus which is provided with a flue gas outlet A first porous plate provided in the first body to allow the introduced exhaust gas to pass therethrough and an absorbing liquid disposed on an upper side of the first porous plate for absorbing water vapor of the exhaust gas and absorbing latent heat and sensible heat of the exhaust gas; A heat recovery type absorbent fluidized bed unit having a first absorbent fluidized bed; A water supply heat being heated by an absorption liquid discharged through an exhaust gas outlet of the heat recovery type absorption liquid fluidized bed unit; A second body having a dry air inlet for introducing dry air into one side thereof and a humidifier vent for discharging a humidifier for absorbing moisture from the absorption liquid at the other end thereof; A dry air dehumidifying liquid absorbent liquid fluidized bed unit comprising a porous plate and a second absorbent fluidized bed composed of an absorbent fluid passing through the feed water heater at an upper side of the second porous plate and discharging steam by the dry air and regenerating the absorbent liquid; Temperature humic gas condensing heat recovering device using the heat-recoverable absorbent fluidized bed and the dry-air dehumidifying absorbent fluidized bed.

The method may further include a step of removing droplets of the exhaust gas, the droplets being disposed in the first body between the exhaust gas outlet and the first absorbent fluidized bed.

At least one of the first absorbent fluidized bed and the second absorbent fluidized bed is formed in a multi-stage type in which the perforated plates are spaced apart from each other by a predetermined distance, and is formed on the outer surface of the upper body to have an absorbent solution inlet, An overflow inflow pipe through which the absorbed liquid discharged through the overflow discharge pipe flows into the lower side perforated plate; and an overflow inflow pipe through which the absorbed liquid discharged through the overflow discharge pipe flows into the lower side perforated plate, And an absorption liquid outlet formed on an outer surface of the body on the upper side and through which the absorption liquid having a predetermined level or higher is discharged.

A second object of the present invention is to provide a method and a device for recovering high-temperature wet-gas condensation heat in which a high-temperature wet gas formed in a heat facility is introduced into a first perforated plate Flowing into the lower part; The wet gas passing through the first perforated plate and flowing into the first absorbent fluidized bed; Absorbing liquid in the first absorbent fluidized bed absorbs water vapor, latent heat, and sensible heat of the exhaust gas and is heated; The flue gas being removed by the demister and discharged through the flue gas outlet; Absorbing water vapor, producing a hot water by heating the absorbed liquid passing through the water heater and releasing heat; The absorption liquid having passed through the feed water heater flows into the second body of the dry air dehumidifying absorption liquid fluidized bed unit to form a second absorbent fluidized bed; The external dry air is introduced into the lower portion of the second porous plate in the second body through the dry air inlet provided in the second body of the dry air dehumidifying absorbent fluidized bed unit by the air blower; The dry air passing through the second porous plate and flowing into the second absorbent fluidized bed; Absorbing water vapor of the absorbing liquid; And a step in which an absorption liquid partially removing moisture is introduced into the heat recovery type absorbent fluidized bed unit, and a method of recovering hot moisture gas condensed heat using the dry air desiccant absorbent fluidized bed and the dry air desiccant absorbent fluidized bed.

The first perforated plate is spaced apart from the first perforated plate in a multi-stage fashion. The first perforated plate is provided with a first absorbent fluidized bed, and the first perforated plate of the first body and a predetermined interval Discharging the absorbing liquid through an overflow discharge pipe provided to the upper side; Flowing the absorption liquid discharged through the overflow discharge pipe to the upper side of the first lower perforated plate through the overflow inlet pipe; And discharging the water to the water supply side through the absorption liquid discharge port spaced apart from the lower side first perforated plate by a predetermined distance.

The second porous plate of the dry air dehumidifying absorbent fluidized bed unit is disposed in a multi-stage manner at a predetermined interval from each other, and a second absorbent fluidized bed is provided on each of the plurality of second porous plates. A step of discharging the absorbing liquid through an overflow discharge pipe spaced apart from an upper side second perforated plate by a predetermined distance; Flowing the absorption liquid discharged through the overflow discharge pipe to the upper side of the lower-side second perforated plate through the overflow inflow pipe; And a step of discharging the absorption liquid to the heat recovery type absorbent fluidized bed unit through the absorption liquid discharge port spaced apart from the lower side second perforated plate by a predetermined distance.

A third object of the present invention is to provide an apparatus for regenerating an absorption liquid discharged from a heat recovery type absorption liquid fluidized bed unit after absorbing water vapor, sensible heat and latent heat of condensation of a high temperature wet gas discharged from a heat facility, A second porous plate provided in the second body to allow the introduced dry air to pass therethrough, a second porous plate provided in the second body to receive the second porous plate, A dry air dehumidifying liquid absorbing fluid bed unit composed of an absorbing liquid discharged from the heat recovery type absorbent fluidized bed unit at the upper side of the porous plate and having a second absorbent fluidized bed in which water vapor is discharged by the dry air and the absorbing liquid is regenerated; An air blower for introducing external dry air into the gun air inlet side; A low-concentration high-temperature absorption liquid pump for introducing an absorbing liquid that absorbs water vapor of hot and wet gas into the dry-air dehumidifying liquid-phase fluid unit; And a high-concentration low-temperature absorber pump for introducing the absorbed liquid into the heat-recoverable absorbent fluidized-bed unit, the steam-removed absorbed liquid being sucked into the heat-recoverable absorbent fluidized bed unit by the dry air.

A first heat exchanger provided between the air blower and the dry air dehumidifying absorbing fluidized bed unit for preheating the external dry air by a second circulating medium; A second heat exchanger for cooling the humidifier discharged through the humidifier outlet of the dry air dehumidifying absorbent fluidized bed unit by the second circulation medium; And a second circulation medium pump for circulating a second circulation medium flowing through the first heat exchanger and the second heat exchanger.

The second porous plate of the dry air dehumidifying absorbent fluidized bed unit is disposed in a multi-stage manner at a predetermined interval from each other, and a second absorbent fluidized bed is provided on each of the plurality of second porous plates. An overflow inflow tube that is spaced apart from the upper side second perforated plate by a predetermined distance above and through which the absorbing liquid is discharged; an overflow inflow tube that allows the absorption liquid discharged through the overflow discharge tube to flow into the upper side of the lower second perforated plate; Further comprising an absorbent outlet that is spaced apart from the second perforated plate by a predetermined distance above and discharges the absorbent to the side of the heat recovery type absorbent fluidized bed unit.

A fourth object of the present invention is to provide a method for regenerating an absorbing liquid discharged from a heat recovery type absorbing fluidized bed unit after absorbing steam, sensible heat and latent heat of condensation of hot flue gas discharged from a thermal equipment, Absorbing liquid fluidized bed unit, and the second absorbing fluidized bed layer is formed by the low-concentration high-temperature absorbing liquid pump into the second body of the dry-air dehumidifying absorbing fluidized bed unit; The external dry air is introduced into the lower portion of the second porous plate in the second body through the dry air inlet provided in the second body of the dry air dehumidifying absorbent fluidized bed unit by the air blower; The dry air passing through the second porous plate and flowing into the second absorbent fluidized bed; Absorbing water vapor of the absorbing liquid; And a step in which the absorption liquid from which water is partially removed flows into the heat recovery type absorbent fluidized bed unit by the high concentration low temperature absorption liquid pump.

The method further includes preheating the external dry air by a second circulating medium passing through the first heat exchanger provided between the air blower and the dry air dehumidifying absorbent fluidized bed unit before the step of flowing into the lower part And the wet gas absorbing water vapor of the absorption liquid is discharged through the humidifier outlet of the dry air dehumidifying absorbent fluidized bed unit and cooled by the second circulation medium by the second heat exchanger.

A fifth object of the present invention is to provide a high temperature wet gas condensing heat recovery system which comprises a flue gas inlet having a flue gas inlet through which hot gas produced at a high temperature generated in a combustion device is introduced into one side and an flue gas outlet A first porous plate provided in the first body to allow the introduced exhaust gas to pass therethrough and an absorption liquid disposed on an upper side of the first porous plate to absorb water vapor of the exhaust gas and to absorb latent heat and sensible heat of the exhaust gas; A heat recovery type absorbent fluidized bed unit having a first absorbent fluidized bed; A water supply heat being heated by a low-concentration high-temperature absorbing liquid discharged through an exhaust outlet of the heat recovery type absorbent fluidized bed unit; An air blower for introducing external dry air into the gun air inlet side; A second body having an air inlet for introducing dry air into one side and a humidifier outlet for discharging a humidifier which absorbs moisture from the absorption liquid at the other end; and a second body provided in the second body, A dry air dehumidifying liquid absorbent fluidized bed unit composed of a stencil sheet and an absorbent fluid passing through the feed water heater on the upper side of the second porous plate, and having a second absorbent fluidized bed in which water vapor is discharged by the dry air and the absorbent liquid is regenerated; A low-concentration high-temperature absorbing liquid pump for causing an absorbing liquid, which has absorbed water vapor of a humidifier, to flow into the dry air dehumidifying-type absorbing-fluid bed unit side in the heat- And a high-concentration low-temperature absorbing pump for introducing an absorbing fluid partially removed from the dry air into the heat-recoverable absorbing fluid bed unit in the dry air dehumidifying absorbing fluid bed unit; An absorbent heater disposed between the heat recovery type absorbent fluidized bed unit and the dry air dehumidifying absorbent fluidized bed unit for heating the absorbed liquid discharged from the dry air dehumidifying absorption liquid fluidized bed unit; A first heat exchanger provided between the air blower and the dry air dehumidifying absorbing fluidized bed unit for preheating the external dry air by a second circulating medium; A second heat exchanger for cooling the humidifier discharged through the humidifier outlet of the dry air dehumidifying absorbent fluidized bed unit by the second circulation medium; And a second circulation medium pump for circulating the second circulation medium flowing through the first heat exchanger and the second heat exchanger. The method of claim 1, Can be achieved as a heat recovery system.

The exhaust gas heat exchanger further comprises a flue gas heat exchanger in which the waste heat of the flue gas discharged from the heat recovery type absorbent fluidized bed unit is absorbed by the first circulation medium and a second circulation medium which is provided between the absorption liquid heater and the flue gas heat exchanger, And heating means for heating the substrate.

A sixth object of the present invention is to provide a method for recovering heat in a high temperature wet gas condensing heat recovery system using the condensed heat recovery system according to the fifth aspect of the present invention, Flowing into a lower portion of the first perforated plate in the first body through an inlet; Flowing the hot wet gas through the first perforated plate into the first absorbent fluidized bed; Absorbing liquid in the first absorbent fluidized bed absorbs water vapor, latent heat, and sensible heat of the exhaust gas and is heated; Absorbing water vapor, producing a hot water by heating the absorbed liquid passing through the water heater and releasing heat; Heat absorbing liquid absorbent liquid fluidized bed unit to produce warm water through hot water heat transfer to the second body of the dry air dehumidifying liquid absorbing fluid bed unit by a low concentration high temperature absorbing liquid pump to form a second absorbent fluidized bed; The external dry air being preheated by a second circulating medium passing through the first heat exchanger; The external dry air is introduced into the lower portion of the second porous plate in the second body through the dry air inlet provided in the second body of the dry air dehumidifying absorbent fluidized bed unit by the air blower; The dry air passing through the second porous plate and flowing into the second absorbent fluidized bed; Absorbing water vapor of the absorbing liquid; Wherein the humidifier which absorbs the water vapor of the absorption liquid is discharged through the humidifier outlet of the dry air dehumidifying absorbent fluidized bed unit, cooled by the second circulation medium by the second heat exchanger, and discharged to the atmosphere; And a step in which the absorption liquid from which a part of water has been removed is passed through the absorption liquid heater by the high concentration low temperature absorption liquid pump and then heated and then flows into the heat recovery type absorption liquid fluidized bed unit and the dry air desiccant absorption liquid fluidized bed Can be achieved as a high-temperature wet gas-condensed heat recovery method.

In addition, in the flue gas heat exchanger, the first circulating medium absorbs waste heat of the exhaust gas discharged from the heat recovery type absorbent fluidized bed unit; And heating the first circulation medium flowing into the absorption fluid heater by the heating means provided between the absorption fluid heater and the exhaust gas heat exchanger.

According to one embodiment of the present invention, the absorption liquid is absorbed from the hot humid gas of the thermal equipment to absorb the water vapor in the hot humid gas to recover the condensation heat, to discharge the dry air, and to use the steam The boiler does not evaporate and boils, and the boiler is dehumidified using external dry air to regenerate the absorption liquid, thereby reducing the amount of expensive steam used, thereby improving the performance and economical efficiency of the condensing heat recovery system of the high temperature humidifier.

According to an embodiment of the present invention, in order to regenerate the absorbing liquid absorbing water vapor in the absorbing fluidized bed of the heat recovery process, the absorbing liquid and the external dry air are brought into direct contact with the regenerating absorbing fluid bed to effectively remove water vapor of the absorbing liquid, It is possible to improve the problem of using a large amount of expensive steam for the regeneration of the absorption liquid.

It should be understood, however, that the effects obtained by the present invention are not limited to the above-mentioned effects, and other effects not mentioned may be clearly understood by those skilled in the art to which the present invention belongs It will be possible.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate preferred embodiments of the invention and, together with the description, serve to further the understanding of the technical idea of the invention, It should not be construed as limited.
1 is a cross-sectional view of a conventional fluidized bed heat exchanger,
FIG. 2 is a configuration diagram of a hot wet-gas condensation heat recovery system using a heat recovery type absorbing fluidized bed and a dry air dehumidifying absorption fluid bed according to an embodiment of the present invention;
3 is a flow chart illustrating a flow path of an absorption liquid according to an embodiment of the present invention,
FIG. 4 is a partial structural view of a hot wet-gas condensation heat recovery system showing a portion of a heat recovery type fluid-bed unit of a heat recovery type according to an embodiment of the present invention;
FIG. 5 is a flow chart of a method of recovering heat by a heat recovery type fluid-bedded unit according to an embodiment of the present invention; FIG.
FIG. 6 is a partial structural view of a hot wet-gas condensation heat recovery system showing a dry air dehumidifying absorption liquid fluidized bed unit according to an embodiment of the present invention;
FIG. 7 is a flow chart of a method of regenerating an absorption liquid by a dry air dehumidifying absorbing fluidized bed according to an embodiment of the present invention;
8 is a partial structural diagram of a high temperature wet gas condensation heat recovery system showing an absorption liquid heater, a heating means, and an exhaust gas heat exchanger side according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the detailed description of known functions and configurations incorporated herein will be omitted when it may unnecessarily obscure the subject matter of the present invention.

The same reference numerals are used for portions having similar functions and functions throughout the drawings. Throughout the specification, when a part is connected to another part, it includes not only a case where it is directly connected but also a case where the other part is indirectly connected with another part in between. In addition, the inclusion of an element does not exclude other elements, but may include other elements, unless specifically stated otherwise.

Hereinafter, the structure and function of the hot wet-gas condensation heat recovery system 100 using the heat recovery type absorbent fluidized bed and the dry air dehumidifying absorption fluid bed according to an embodiment of the present invention will be described. FIG. 2 is a block diagram of a high temperature wet gas condensation heat recovery system 100 using a heat recovery type absorbent fluidized bed and a dry air dehumidifying absorption fluid bed according to an embodiment of the present invention. As shown in FIG. 2, the high temperature wet gas condensate heat recovery system 100 using the heat recovery type absorbent fluidized bed and the dry air dehumidifying absorption liquid fluidized bed according to an embodiment of the present invention includes a heat recovery type absorbent fluidized bed unit 20, A first heat exchanger 51, a second heat exchanger 52, an absorption liquid heater 70, a heating means 71, an exhaust gas heat exchanger 72, And the like.

First, a description will be given of the flow path of the absorption liquid in the hot wet-gas condensate heat recovery system 100 using the heat recovery type absorbent fluidized bed and the dry air dehumidifying absorption fluid bed according to an embodiment of the present invention. do. FIG. 3 is a flowchart illustrating a flow path of an absorption liquid according to an embodiment of the present invention.

3, the absorption liquid flows through the absorption liquid inlet 29 provided on the upper side outer surface of the first body 21 of the heat recovery type liquid-absorbent fluidized bed unit 20, So that the first absorbent fluidized bed 24 is formed.

As shown in FIG. 2, the first absorbent fluidized bed 24 is desirably formed in multiple stages spaced apart from each other by a predetermined distance. The first absorbent fluidized bed (24) is in direct contact with the hot humid gas introduced by the exhaust gas blower (11), absorbing the steam of the hot humid gas while the sensible heat of the hot humid gas and the latent heat of condensation are transferred to the absorption liquid, The liquefied temperature is increased (S1).

The high-temperature absorbing liquid of low concentration which absorbs water vapor of the high-temperature wet gas passes through the water heating oven 30 through the absorption liquid outlet by the absorption liquid pump 31. Accordingly, the water introduced through the other path is heated by absorbing the heat of the high-temperature absorbent at the water heater 30 (S2). Accordingly, the feed water is heated by the high-temperature absorbing liquid to efficiently recover the waste heat of the hot wet gas, thereby producing hot water at a high temperature.

The absorption liquid that has passed through the water heater 30 passes through the absorption liquid inlet 49 of the dry air dehumidifying liquid absorbing fluid bed unit 40 according to the embodiment of the present invention, And flows into the upper portion of the second perforated plate 43 to form a second absorbent fluidized bed 44 (S3). As shown in FIG. 2, the second absorbent fluidized bed 44 of the dry air dehumidification type absorbent fluidized bed unit 40 is also preferably formed in multiple stages spaced apart from each other by a predetermined distance.

In the dry air dehumidifying liquid absorbing fluidized bed unit 40 according to the embodiment of the present invention, since the absorbing liquid discharged from the heat recovery type absorbing fluidized bed unit 20 absorbs water vapor in the high temperature wetting gas and the concentration is low, To be used for the absorption liquid regeneration process.

The absorbing liquid in the dry air dehumidifying absorbent fluidized bed unit 40 is introduced by the air blower 50, preheated by the first heat exchanger 51, and introduced into the interior through the dry air inlets 42. Then, the low-concentration absorbing liquid and the low-humidity dry air come into direct contact with each other to remove a part of the moisture of the absorbing liquid (S4).

Further, in the process of regenerating the absorbent solution using dry air, the temperature of the absorbent is lowered while moisture in the low concentration absorbent is evaporated. Then, the absorption liquid from which a part of the water is discharged is discharged from the absorption liquid outlet port 46 of the dry air dehumidifying absorption liquid fluidized bed unit 40 by the high concentration low temperature absorption liquid pump 60 and is heated by the absorption liquid heater 70 (S5) .

The exhaust gas heat exchanger 72 according to an embodiment of the present invention absorbs the waste heat of the exhaust gas discharged from the heat recovery type absorbent fluidized bed and heats the first circulation medium. If necessary, the heat of the hot water heater The means (71) further heats the first circulating medium. And to heat the absorption liquid from the absorption liquid heater 70 to the first circulation medium. The absorbed liquid heated and regenerated by the absorbing liquid heater 70 is circulated while being introduced into the absorbing liquid inlet 29 of the heat recovery type absorbent liquid fluidized bed unit 20 (S6).

Through this process, the sensible heat and condensation latent heat of the hot flue gas containing water vapor can be recovered and high temperature water can be produced. In the present invention, unlike the conventional art, in order to regenerate a high-temperature absorbent, high-priced steam is used to regenerate the absorbed liquid by removing moisture from the absorbed liquid by using external dry air without evaporating moisture in the absorbed liquid, Can be reduced.

This makes it possible to apply an absorption liquid having a high boiling point and a high boiling point to the regeneration process using the existing steam, and further improve the economical efficiency of the heat recovery system.

Hereinafter, the structure of the heat recovery-type absorbent fluidized bed unit 20 and the heat recovery method will be described in more detail. FIG. 4 shows a partial schematic diagram of a hot wet-gas condensation heat recovery system 100 showing a portion of a heat recovery type fluid-bed unit 20 according to an embodiment of the present invention. 5 shows a flowchart of a heat recovery method by the heat recovery type fluid-bed unit 20 according to the embodiment of the present invention.

4, the heat recovery type absorbent liquid fluidized bed unit 20 according to the embodiment of the present invention includes an absorption liquid inlet port 29, an absorbent liquid outlet port 26, an exhaust gas inlet port 22, an exhaust gas outlet port 25, 1 body 21, a first perforated plate 23 formed in a multi-stage and a first absorbent fluidized bed 24 formed over each of the first perforated plate 23, an overflow outlet pipe 27, an overflow inlet pipe 28, and the like.

The hot humid gas discharged from the thermal equipment 10 is introduced into the first body 21 through the flue gas inlet 22 of the heat recovery type fluid bed unit 20 according to the embodiment of the present invention by the flue gas blower 11, (S11 and S12).

The high-temperature wet gas introduced into the lower side of the first body (21) directly contacts the lower first absorbent fluidized bed (24), so that the absorbent absorbs steam of the hot and wet gas, absorbing sensible heat and latent heat. Accordingly, the temperature of the absorption liquid is increased (S13, S14).

Subsequently, the flue gas is directly in contact with the upper first absorption liquid fluidized bed (24), so that the absorption liquid absorbs moisture vapor of the wet gas and absorbs sensible heat and latent heat.

After the absorption liquid is heated, the cooled exhaust gas is discharged through the exhaust gas outlet 25 in the upper part of the heat recovery type absorbent liquid fluidized bed unit 20 (S16). As will be described later, in the exhaust gas heat exchanger 72, The waste heat is once again discharged to the atmosphere.

The heat recovery type fluidized-bed reactor 20 according to an embodiment of the present invention includes a demister in the first body 21 between the exhaust gas outlet 25 and the upper first absorbent fluidized bed 24, The droplet may be removed and discharged (S15).

4, the heat recovery type fluid-bed unit 20 according to an embodiment of the present invention includes overflow tubes (not shown) for stably forming each of the first absorbent fluidized beds 24 at a constant level, Respectively.

Specifically, as shown in FIG. 4, an overflow discharge pipe 26 is provided on the outer surface of the first body 21 spaced apart from the upper first perforated plate 23 by a predetermined distance. Therefore, when the absorption liquid of the first upper perforated plate 23 exceeds the set level, the liquid is discharged through the overflow discharge pipe 26 and flows to the upper side of the first perforated plate 23 through the overflow inflow pipe 28 .

The absorption liquid outlet 26 is provided on the outer surface of the first body 21 at a predetermined interval from the lower first porous plate 23 so that the absorption liquid of the lower first porous plate 23 exceeds the predetermined level The high-concentration high-temperature absorbing liquid pump 31 discharges the water to the water heater 30 side.

The high-temperature absorbing liquid at a low concentration that absorbs water vapor of the high-temperature wet gas passes through the water heating oven 30 through the absorbing liquid outlet port 26 by the absorbing liquid pump 31. Accordingly, the water introduced through the other path is heated by absorbing the heat of the high-temperature absorbent from the water heater 30. Accordingly, the feed water is heated by the high-temperature absorbing liquid to efficiently recover the waste heat of the hot wet gas, thereby producing hot water at a high temperature.

Hereinafter, the construction of the dry-air dehumidifying-type absorption liquid fluidized-bed unit 40 and the method of regenerating the absorption liquid will be described in more detail. FIG. 6 shows a partial schematic view of a hot-wet-gas condensation heat recovery system 100 showing a dry-air dehumidifying-type absorption liquid fluidized bed unit 40 portion according to an embodiment of the present invention. FIG. 7 is a flowchart of a method of regenerating an absorbent by the dry air dehumidifying absorbent fluidized bed according to an embodiment of the present invention.

6, the dry air dehumidifying liquid absorbing fluidized bed unit 40 includes an absorbing liquid inlet 49, an absorbing liquid outlet 46, a dry air inlet 42, a humidifier outlet 45, a second body 41, A second absorbent fluidized bed 44 formed on each of upper portions of the second perforated plate 43 and the second perforated plate 43 formed in a multistage manner, an overflow discharge pipe 47, an overflow inflow pipe 48, and the like .

The absorbing liquid constituting the second absorbent fluidized bed 44 is introduced through the absorbent fluid inlet 49 provided on the outer surface of the upper end of the second body 41 through the water heater 30.

The external dry air is introduced by the air blower 50 (S21), and is first preheated by the first heat exchanger 51 (S22). In the first heat exchanger (51), the second circulating medium flowing through another path is exchanged with the external dry air, so that the dry air is preheated. The preheated external dry air is introduced into the lower layer of the second body 41 through the dry air inlet 42 of the dry air dehumidifying-type desorption liquid fluidized bed unit 40 (S23).

The dry air introduced into the lower side of the second body 41 continuously passes through the second absorbent fluidized bed 44 and the upper side second absorbent fluidized bed 44 on the lower end side of the second body 41 (S24) . As the dry air passes through the second absorbent fluidized bed 44, the dry air and the absorbing liquid directly contact each other, so that the dry air absorbs the moisture of the absorbing liquid (S25). As a result, the concentration of the absorption liquid again increases to the original concentration, and is discharged through the absorption liquid discharge port 46 of the dry air dehumidification type absorption liquid fluidized bed. However, in the process of regenerating the absorbent solution using the dry air, the moisture in the low concentration absorbent is evaporated, and the temperature of the absorbent is lowered.

6, the dry-air dehumidifying-type absorbent-fluid bed unit 40 according to an embodiment of the present invention includes an overflow (not shown) to stably form each of the multi-stage second absorbent fluidized beds 44 at a constant water level, Tubes.

Specifically, as shown in FIG. 6, an overflow discharge pipe 47 is provided on the outer surface of the second body 41 spaced apart from the upper second porous plate 43 by a predetermined distance. Accordingly, when the absorption liquid of the upper-side second perforated plate 43 exceeds the predetermined level, the liquid is discharged through the overflow discharge pipe 47 and flows through the overflow inflow pipe 48 to the upper portion of the lower- .

The absorption liquid outlet 46 is provided on the outer surface of the lower second porous plate 43 and the upper surface of the second body 41 at a predetermined interval so that the absorption liquid of the lower second porous plate 43 exceeds the set water level The absorbing liquid is discharged to the heat exchanger 70 side by the high concentration low temperature absorbing liquid pump 60.

The humidifier which absorbs the moisture of the absorption liquid is discharged through the humidifier outlet 45 of the dry air dehumidifying absorption liquid fluidized bed unit 40 and passes through the second heat exchanger 52 to discharge heat to the second circulation medium , And is discharged into the atmosphere (S26).

That is, as shown in FIG. 6, it can be seen that the second circulating medium circulates through the first heat exchanger 51 and the second heat exchanger 52 by the second circulating medium pump 53, . More specifically, the second circulating medium is circulated through the second heat exchanger (52) while being circulated by the second circulating medium pump (53), and discharged through the humidifier outlet (45) of the dry air dehumidifying absorbent fluidized bed unit (40) And the second circulation medium discharged from the second heat exchanger 52 passes through the first heat exchanger 51 and is heated by the air blower 50 to be preheated .

That is, the waste heat of the humidifier raised in the humidifier outlet 45 of the dry air dehumidifying absorbent fluidized bed unit 40 is recovered to preheat the external dry air supplied to the dry air dehumidifying absorbent fluidized bed to recover the entire heat recovery system 100 ) Can be increased.

Further, the absorbing liquid discharged from the dry air dehumidifying absorbing fluidized bed unit 40 is supplied to the heat recovery type absorbent fluidized bed by using the absorbing liquid pump 60. In this process, since the temperature of the absorption liquid is low, the waste heat of the dry gas discharged from the heat recovery type fluidized bed is recovered to preheat the absorption liquid. If the temperature of the absorption liquid supplied to the heat recovery fluidized bed is still low through the above process, the absorption fluid is further heated by using hot water or steam at a different temperature and maintained at a constant temperature.

8 shows a partial structural diagram of a high temperature wet gas condensation recovery system 100 showing an absorption liquid heater 70, a heating means 71 and an exhaust gas heat exchanger 73 side according to an embodiment of the present invention. As shown in Fig. 8, the first circulating medium circulated by the first circulating medium pump 73 collects the waste heat of the exhaust gas discharged from the heat recovery type absorbent fluidized bed through the exhaust gas heat exchanger 72, Is heated again by the hot water or steam while passing through the heating means 71 composed of the hot water heater or the steam heater and flows into the absorption liquid heater 70 to be circulated. The first circulation medium heated by the heating means and introduced into the absorption liquid heater 70 heats the absorption liquid. The absorption liquid heated by the absorption liquid heater 70 is again introduced into the first body 21 through the absorption liquid inlet 29 of the heat recovery type liquid-absorbent fluidized bed unit 20.

Through this process, the sensible heat and condensation latent heat of the hot flue gas containing water vapor can be recovered and high temperature water can be produced. In the present invention, unlike the conventional art, in order to regenerate a high-temperature absorbent, high-priced steam is used to regenerate the absorbed liquid by removing moisture from the absorbed liquid by using external dry air without evaporating moisture in the absorbed liquid, Can be reduced.

This makes it possible to apply an absorption liquid having a high boiling point and a high boiling point, which is superior to the conventional regeneration process using steam, and further improve the economical efficiency of the heat recovery system 100.

It should be noted that the above-described apparatus and method are not limited to the configurations and methods of the embodiments described above, but the embodiments may be modified so that all or some of the embodiments are selectively combined .

1: square body
1a:
1b: bottom plate
2: Heat exchange tube
3: Perforated plate
4: Water Drop Filter
5a, 5b: exhaust gas flow passage
6: Exhaust gas inlet
7: Automatic regulating valve
8: Exhaust gas outlet
9: Bypass tube
10: Thermal equipment
11: Flue gas blower
20: heat recovery type absorption liquid fluidized bed unit
21: First body
22: Flue gas inlet
23: First plate
24: first absorbent fluidized bed
25: exhaust gas outlet
26, 46: absorption liquid outlet
27, 47: overflow outlet
28, 48: overflow inlet
29, 49: absorption liquid inlet
30: Water heater
31: Low concentration high temperature absorption liquid pump
40: Dry air dehumidifying absorption liquid Fluid bed unit
41: second body
42: gun air inlet
43: Second plate
44: second absorbent fluidized bed
45: Humidifier outlet
50: air blower
51: first heat exchanger
52: second heat exchanger
53: second circulating medium pump
60: High concentration low temperature absorption liquid pump
70: Absorption liquid heater
71: Heating means
72: Flue gas heat exchanger
73: first circulating medium pump
100: Heat recovery type absorption liquid Fluidized bed and dry air dehumidification type Absorption liquid High temperature wet gas condensation heat recovery system using fluidized bed

Claims (15)

An apparatus for regenerating an absorption liquid discharged from a heat recovery type absorption liquid fluidized bed unit after absorbing water vapor, sensible heat and latent heat of condensation discharged from a heat facility,
A second body having an air inlet port through which dry air flows into the first side and a second air outlet port through which the humidifier which absorbs moisture from the absorption liquid is discharged at the other end; And a second absorbent fluidized bed layer composed of an absorbing fluid discharged from the heat recovery type absorbent fluidized bed unit at the upper side of the second porous plate and partially discharging moisture from the dry air and regenerating the absorbed fluid;
An air blower for introducing external dry air into the gun air inlet side;
A low-concentration high-temperature absorbing liquid pump for causing an absorbing liquid, which has absorbed water vapor in a high-temperature humidifier, to flow into the dry air dehumidifying-type absorbing-fluid bed unit side in the heat- And
And a high-concentration low-temperature absorber pump for introducing an absorbing fluid partially removed of water by the dry air into the heat-recoverable absorbent fluidized bed unit in the dry air dehumidifying absorbent fluidized bed unit.
The method according to claim 1,
A first heat exchanger provided between the air blower and the dry air dehumidifying absorbing fluidized bed unit for preheating the external dry air by a second circulating medium;
A second heat exchanger for cooling the humidifier discharged through the humidifier outlet of the dry air dehumidifying absorbent fluidized bed unit by the second circulation medium; And
Further comprising a second circulation medium pump for circulating a second circulation medium flowing through the first heat exchanger and the second heat exchanger.
3. The method of claim 2,
Wherein the second porous plate of the dry air dehumidifying absorbing fluid bed unit is disposed in a multi-stage manner at a predetermined interval from each other, and a second absorbent fluidized bed is provided on each of the plurality of second porous plates,
An overflow discharge pipe that is spaced apart from an upper side of the second porous plate of the second body by a predetermined distance and through which the absorption liquid is discharged, and an overflow inflow pipe that allows the absorption liquid discharged through the overflow discharge pipe to flow toward the upper side of the lower- And an absorption liquid outlet which is spaced apart from an upper side of the predetermined interval with the lower-side second perforated plate to discharge the absorption liquid toward the heat recovery type liquid-absorbing fluid bed unit.
A method for regenerating an absorption liquid discharged from a heat recovery type absorption liquid fluidized bed unit after absorbing water vapor, sensible heat and latent heat of condensation discharged from a heat facility,
Heat absorbing liquid absorbent liquid fluidized bed unit to produce warm water through hot water heat transfer to the second body of the dry air dehumidifying liquid absorbing fluid bed unit by a low concentration high temperature absorbing liquid pump to form a second absorbent fluidized bed;
The external dry air is introduced into the lower portion of the second porous plate in the second body through the dry air inlet provided in the second body of the dry air dehumidifying absorbent fluidized bed unit by the air blower;
The dry air passing through the second porous plate and flowing into the second absorbent fluidized bed;
Absorbing water vapor of the absorbing liquid; And
And the step of introducing the absorbing liquid from which water vapor has been removed into the heat recovery type absorbent fluidized bed unit by the high concentration low temperature absorbing solution pump.
5. The method of claim 4,
Before entering the lower portion,
Further comprising preheating the external dry air by a second circulating medium passing through the first heat exchanger provided between the air blower and the dry air dehumidifying absorbent fluidized bed unit,
And the wet gas absorbing the water vapor of the absorption liquid is discharged through the wet gas outlet of the dry air dehumidifying liquid absorbing fluid bed unit and cooled by the second circulation medium by the second heat exchanger .
In a hot and humid condensation heat recovery system,
A first body having a flue gas inlet through which a high temperature flue gas generated in the combustion device flows in one side and an exhaust gas outlet through which the flue gas is discharged in the form of dry air at the other end; A heat absorbing liquid fluidized bed unit comprising a perforated plate and a first absorbent fluidized bed composed of an absorbent on the upper side of the first perforated plate and absorbing water vapor of the exhausted gas and absorbing latent heat and sensible heat of the exhausted gas;
A water supply heat being heated by a low-concentration high-temperature absorbing liquid discharged through an exhaust outlet of the heat recovery type absorbent fluidized bed unit;
An air blower for introducing external dry air into the gun air inlet side;
A second body having an air inlet for introducing dry air into one side and a humidifier outlet for discharging a humidifier which absorbs moisture from the absorption liquid at the other end; and a second body provided in the second body, A dry air dehumidifying absorbent fluidized bed unit comprising a stencil plate and a second absorbent fluidized bed composed of an absorbent fluid passing through the feed water heater on the upper side of the second porous plate and partially discharging water to the dry air side and regenerating the absorbent fluid;
A low-concentration high-temperature absorbing liquid pump for causing an absorbing liquid, which has absorbed water vapor in a high-temperature humidifier, to flow into the dry air dehumidifying-type absorbing-fluid bed unit side in the heat- And
A high-concentration low-temperature absorber pump for introducing an absorbing fluid partially removed from the dry air into the heat-recoverable absorbing fluid bed unit in the dry air dehumidifying-type absorbing fluid bed unit;
An absorbent heater disposed between the heat recovery type absorbent fluidized bed unit and the dry air dehumidifying absorbent fluidized bed unit for heating the absorbed liquid discharged from the dry air dehumidifying absorption liquid fluidized bed unit;
A first heat exchanger provided between the air blower and the dry air dehumidifying absorbing fluidized bed unit for preheating the external dry air by a second circulating medium;
A second heat exchanger for cooling the humidifier discharged through the humidifier outlet of the dry air dehumidifying absorbent fluidized bed unit by the second circulation medium; And
And a second circulation medium pump for circulating the second circulation medium flowing through the first heat exchanger and the second heat exchanger. The method according to claim 1, wherein the heat recovery water system.
The method according to claim 6,
An exhaust gas heat exchanger for absorbing waste heat of the exhaust gas discharged from the heat recovery type absorption liquid fluidized bed unit by a first circulation medium and a first circulation medium which is provided between the absorption fluid heater and the exhaust gas heat exchanger, And a heating means, wherein the heat recovery water absorbing fluidized bed and the dry air dehumidifying absorbing fluidized bed are used.
In the hot and wet gas condensed heat recovery method,
The hot humid gas formed in the thermal facility flows into the lower portion of the first perforated plate in the first body through the flue gas inlet provided in the first body of the heat recovery type absorbent fluidized bed unit;
The wet gas passing through the first perforated plate and flowing into the first absorbent fluidized bed;
Absorbing liquid of the first absorbent fluidized bed absorbs water vapor, latent heat, and sensible heat of the hot wetted gas and is heated;
Absorbing water vapor, producing a hot water by heating the absorbed liquid passing through the water heater and releasing heat;
Heat absorbing liquid absorbent liquid fluidized bed unit to produce warm water through hot water heat transfer to the second body of the dry air dehumidifying liquid absorbing fluid bed unit by a low concentration high temperature absorbing liquid pump to form a second absorbent fluidized bed;
The external dry air being preheated by a second circulating medium passing through the first heat exchanger;
The external dry air is introduced into the lower portion of the second porous plate in the second body through the dry air inlet provided in the second body of the dry air dehumidifying absorbent fluidized bed unit by the air blower;
The dry air passing through the second porous plate and flowing into the second absorbent fluidized bed;
The dry air partially absorbing moisture of the absorption liquid;
The humidifier absorbing the moisture of the absorption liquid is discharged through the humidifier outlet of the dry air dehumidifying absorbent fluidized bed unit, cooled by the second heat exchanger by the second circulation medium, and discharged to the atmosphere; And
And a step of introducing into the heat recovery type absorbent fluidized bed unit a heat recovery type fluidized bed and a dry air desiccant type absorbed fluidized bed, characterized in that the absorbed fluid partially removed from the water is heated by passing through the absorption liquid heater by the high concentration low temperature absorption liquid pump, Heat recovery method using high temperature wet gas.
9. The method of claim 8,
In the flue gas heat exchanger, the first circulating medium absorbs waste heat of the exhaust gas discharged from the heat recovery type absorption fluidized bed unit; And
Further comprising the step of heating the first circulation medium flowing into the absorption fluid heater by a heating means provided between the absorption fluid heater and the exhaust gas heat exchanger, wherein the heat recovery fluidized bed and the dry air dehumidifying absorption fluid bed Heat recovery method using high temperature wet gas. delete delete delete delete delete delete

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