KR20110109796A - Exhaust gas outlet chimney structure of exhaust gas heat recovery unit - Google Patents

Abstract

[PROBLEMS] To provide an exhaust gas outlet stack structure of an exhaust gas heat recovery machine which prevents inflow of condensed water into a heat exchange chamber.
[Solution] A heat exchange chamber (40A) for accommodating a portion of the absorbent liquid tube (21D) from the absorber of the absorption chiller to the high temperature regenerator, and the absorbent liquid flowing through the absorbent liquid tube (21D) in the heat exchange chamber (40A) is a high temperature regenerator. In the exhaust gas outlet stack structure of the exhaust gas heat recovery unit 40 which is heated by exhaust gas from the combustion chamber of the exhaust gas and exhausts the exhaust gas to the outside through the stack 40B in which the exhaust gas stands up in the substantially vertical direction, the heat exchange chamber 40A. The stack 40B is disposed to overlap a part of the top plate 41E, and the openings 44 are formed in the top plate 41E where the stacks 40B do not overlap, and the openings 44 and the stack 40B are formed of a conductor ( 45), and condensation receiving part 49 is formed immediately under the stack 40B which does not overlap with the top plate 41E.

Description

EXHAUST GAS OUTLET CHIMNEY STRUCTURE OF EXHAUST GAS HEAT RECOVERY UNIT}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an exhaust gas outlet stack structure of an exhaust gas heat recovery machine that heats an absorption liquid flowing through an absorption liquid pipe with exhaust gas from a high temperature regenerator of an absorption chiller.

Background Art Conventionally, an absorption cold / hot water machine including a high temperature regenerator, a low temperature regenerator, a condenser, an evaporator, and an absorber and connecting them to each other to form a circulation path for an absorbent liquid and a refrigerant is known (see Patent Document 1, for example). In this absorption chiller, in order to use the exhaust heat of the exhaust gas discharged from the high temperature regenerator, an exhaust gas heat recovery unit is provided in the exhaust path of the exhaust gas to recover the exhaust heat of the exhaust gas. The exhaust gas heat recovery unit performs heat exchange between the exhaust gas flowing through the exhaust path and the rare absorbent liquid flowing through the absorption liquid pipe from the absorber to the high temperature regenerator.

[Patent Document 1] Japanese Patent Application Laid-Open No. 2005-282968

By the way, when the heat recovery in the exhaust gas heat recovery machine is performed by pre-cooling and heating load, the temperature of the exhaust gas becomes near the dew point or below the dew point at the outlet of the exhaust gas heat exchanger at low load. In this case, there exists a possibility that the dew condensation water which generate | occur | produced in the exit part of an exhaust gas heat recovery machine, or the condensation water generated in the flue part of the installation side connected to the outlet part of an exhaust gas heat recovery machine may flow into the heat exchange chamber which heat-exchanges.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide an exhaust gas outlet stack structure of an exhaust gas heat recovery device which prevents inflow of condensed water into a heat exchange chamber.

In order to achieve the above object, the present invention includes a heat exchange chamber for accommodating a portion of the absorbent liquid tube from the absorber of the absorption chiller to the high temperature regenerator, wherein the absorbent liquid flowing in the absorbent liquid tube from the combustion chamber of the high temperature regenerator is In an exhaust gas outlet stack structure of an exhaust gas heat recovery machine which is heated with exhaust gas and exhausts the exhaust gas to the outside through a stack in which the exhaust gas stands up in a substantially vertical direction, a part of the top plate of the heat exchange chamber is superposed. The stack is disposed, an opening is formed in the top plate where the stack does not overlap, and the opening and the stack are connected by a flue, and a condensation receiver is directly under the stack that does not overlap the top plate. Characterized in that formed by connecting the wealth.

In the above configuration, the inlet opening of the stack may be adjacent to the opening of the top plate.

In the above configuration, the top plate immediately below the inner wall of the stack may be provided with a blocking plate that prevents condensation water from entering the heat exchange chamber.

In the above configuration, the stopping plate may be disposed outside the stack.

In the above configuration, the condensation water receiver may be provided below the top plate, and the top plate and the condensation water receiver may communicate with each other.

In the above configuration, the flue body includes a flue top plate and a flue side plate, overlaps a part of the flue top plate and the flue side plate to arrange the stack, and the inlet opening of the stack is both of the flue plate and the flue side plate. You may form in.

According to the present invention, a stack is placed on a top plate of a heat exchange chamber, and a stack is formed, an opening is formed in a top plate where the stacks do not overlap, and the opening and the stack are connected by a conductor, and condensation water is directly below the stack that does not overlap the top plate. Since the receiving part was formed successively, condensation water generated in the stack and condensation water generated in the flue part on the installation side gather in the condensation water receiving part, thereby preventing condensation water from flowing into the heat exchange chamber from the opening of the top plate.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic block diagram of the absorption type cold and hot water heater which applied the exhaust gas outlet flue structure of the exhaust gas heat recovery system which concerns on this embodiment.
2 is a perspective view showing an exhaust gas heat recovery machine;
3 is a longitudinal sectional view showing an exhaust gas heat recovery machine;
4 is a perspective view showing an exhaust gas heat recovery device from above;
5 is a longitudinal sectional view schematically showing an exhaust gas heat recovery machine.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described with reference to drawings.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic block diagram of the absorption type cold and hot water heater which applied the exhaust gas outlet flue structure of the exhaust gas heat recovery system which concerns on this embodiment.

The absorption chiller 100 is a dual-use absorption chiller that uses water as a refrigerant and an aqueous lithium bromide (LiBr) solution as an absorption liquid. As shown in FIG. 1, the absorption chiller 100 includes an evaporator 1, an absorber 2 provided in the evaporator 1, and an evaporator absorber body in which the evaporator 1 and the absorber 2 are accommodated. (3), a high temperature regenerator 5 having a gas burner 4, a low temperature regenerator 6, a condenser 7 provided in the low temperature regenerator 6, these low temperature regenerators 6 and a condenser Low temperature regenerator condenser body (8), low temperature heat exchanger (12), high temperature heat exchanger (13), refrigerant drain heat exchanger (16), rare water pump (P1), concentrated absorbent liquid The pump P2 and the refrigerant pump P3 are provided, and each of these devices is connected to each other via the absorption liquid pipes 21 to 25, the refrigerant pipes 31 to 35, and the like.

Reference numeral 14 denotes a cold / hot water pipe for circulating and supplying the brine heat exchanged with the refrigerant in the evaporator 1 to a heat load (for example, an air conditioner), which is not shown, and part of the cold / hot water pipe 14. The heat exchanger tube 14A formed in the evaporator 1 is disposed. The temperature sensor 61 which measures the temperature of the brine which distribute | circulates the inside of the said cold / hot water pipe 14 is provided in the heat-transfer pipe 14A downstream of the cold / hot water pipe 14. Reference numeral 15 denotes a cooling water pipe for circulating the cooling water sequentially in the absorber 2 and the condenser 7, and each of the heat transfer pipes 15A and 15B formed in a part of the cooling water pipe 15 is respectively the absorber 2 and the condenser ( 7) is arranged in. Reference numeral 50 denotes a controller in charge of controlling the entire absorption type hot and cold water heater 100.

The absorber 2 has a function of absorbing the refrigerant vapor evaporated in the evaporator 1 into the absorbent liquid to maintain the pressure in the evaporator absorber body 3 in a high vacuum state. In the lower part of the absorber 2, a rare absorbing liquid pool 2A is formed in which the rare absorbing liquid diluted with the refrigerant vapor is accumulated, and the rare absorbing liquid pool 2A is controlled by the inverter 51 at a frequency variable. One end of the rare water absorption pipe 21 provided with the rare water absorption pump P1 is connected. This rare water absorbing liquid pipe 21 branches into the first rare water absorbing liquid pipe 21A and the second rare water absorbing liquid pipe 21B on the downstream side of the rare water absorbing liquid pump P1, and the first rare water absorbing liquid pipe 21A is a refrigerant drain. Via the heat exchanger 16, the second rare water absorption pipe 21B joins again after passing through the low temperature heat exchanger 12. The other end of the rare water absorbing tube 21 is branched into the third rare water absorbing tube 21C and the fourth rare water absorbing tube (absorbing liquid tube) 21D after passing through the high temperature heat exchanger 13, and the third rare absorbing liquid tube. 21C is opened to the base part 5B located above 5 A of heat exchange parts (combustion chamber) formed in the high temperature regenerator 5, and the 4th rare water absorption pipe 21D is exhaust gas heat recovery. After passing through the group 40, the opening is opened to the base layer portion 5B of the high temperature regenerator 5.

Under the high temperature regenerator 5, for example, a gas burner 4 including an igniter 4A for igniting fuel such as city gas and a fuel control valve 4B for controlling the amount of fuel to vary the amount of heat source. Is accommodated. In the high temperature regenerator 5, a heat exchanger 5A is formed above the gas burner 4 to heat-regenerate the absorbing liquid using the flame of the gas burner 4 as a heat source. An exhaust path 17 through which exhaust gas combusted by the gas burner 4 flows is connected to the heat exchange part 5A, and an exhaust gas heat recovery 40 is provided in the exhaust path 17. On the side of the heat exchanger 5A, an intermediate absorbent liquid pool 5C in which the intermediate absorbent liquid heated and regenerated in the heat exchanger 5A is formed is formed.

One end of the intermediate absorbent liquid tube 22 is connected to the lower end of the intermediate absorbent liquid holding part 5C, and the other end of the intermediate absorbent liquid tube 22 is formed on the upper part of the low temperature regenerator 6 through the high temperature heat exchanger 13. It is opened to base layer part 6A. The high temperature heat exchanger 13 heats the absorbent liquid flowing through the rare absorbent liquid tube 21 by the heat of the high temperature absorbent liquid flowing out from the intermediate absorbent liquid reservoir 5C, and the gas burner 4 of the high temperature regenerator 5 is heated. The reduction of fuel consumption is aimed at. Moreover, the high temperature heat exchanger 13 upstream of the intermediate | middle absorption liquid pipe 22 and the absorber 2 are connected by the absorption liquid pipe 23 which the opening-closing valve V1 interposes.

The low temperature regenerator 6 heat-regenerates the absorbent liquid accumulated in the absorbent liquid holding part 6B formed below the base layer portion 6A by using the refrigerant vapor separated from the high temperature regenerator 5 as a heat source, thereby absorbing the liquid holding part 6B. The heat transfer pipe 31A formed in a part of the refrigerant pipe 31 extending from the upper end of the high temperature regenerator 5 to the bottom of the condenser 7 is arranged. By passing the refrigerant vapor through the refrigerant pipe 31, the heat of the refrigerant vapor is transferred to the absorption liquid accumulated in the absorption liquid pool 6B through the heat transfer tube 31A, and the absorption liquid is further concentrated.

One end of the concentrated absorbent liquid tube 24 is connected to the lower end of the absorbent liquid holding part 6B of the low temperature regenerator 6, and the other end of the concentrated absorbent liquid tube 24 is the concentrated absorbent liquid pump P2 and the low temperature heat exchanger 12. It is connected to the concentrated liquid spreader 2C provided above the base part 2B of the absorber 2. The low temperature heat exchanger 12 heats the rare absorbent liquid flowing through the second rare absorbent liquid tube 21B by the heat of the concentrated absorbent liquid flowing out from the absorbent liquid holding part 6B of the low temperature regenerator 6. In addition, a bypass pipe 25 for bypassing the concentrated absorbent liquid pump P2 and the low temperature heat exchanger 12 is provided on the upstream side of the concentrated absorbent liquid pump P2, and the operation of the concentrated absorbent liquid pump P2 is stopped. If so, the absorbent liquid flowing out from the absorbent liquid holding part 6B of the low temperature regenerator 6 is supplied to the absorber 2 via the bypass pipe 25 without passing through the low temperature heat exchanger 12.

As described above, the base layer portion 5B of the high temperature regenerator 5 and the bottom of the condenser 7 are heat transfer tubes 31A and a refrigerant drain heat exchanger 16 piped to the absorbent liquid holding part 6B of the low temperature regenerator 6. Is connected by a refrigerant pipe 31 passing through), and the base layer portion 2B of the heat transfer pipe 31A upstream of the refrigerant pipe 31 and the absorber 2 are connected to a refrigerant pipe (V2) via an on / off valve V2. 32). Moreover, the bottom part of the condenser 7 and the base layer part 1A of the evaporator 1 are connected by the refrigerant pipe 33 through which 33 A of U seal parts are interposed. In addition, a coolant liquid holding part 1B is formed below the evaporator 1, where the liquefied refrigerant accumulates, and the spreader disposed above the coolant liquid holding part 1B and the base layer part 1A of the evaporator 1. 1C is connected by the refrigerant pipe 34 through which the refrigerant pump P3 is interposed. The refrigerant pump P3 downstream of the refrigerant pipe 34 and the absorbent liquid holding part 2A of the absorber 2 are connected by the refrigerant pipe 35. Moreover, the outlet side of the heat exchanger tube 14A of the cold / hot water pipe 14 with the outlet side of the heat exchanger tube 15B of the cooling water pipe 15 is connected by the communication pipe 36 through which the switching valve V3 is interposed.

The absorption type cold and hot water heater 100 operates by switching between a cooling operation for extracting cold water from the cold / hot water pipe 14 and a heating operation for extracting hot water from the cold / hot water pipe 14 under the control of the controller 50. do.

In the cooling operation, the absorption type of the evaporator 1 outlet side of the brine (for example, cold water) circulated and supplied to a heat load (not shown) through the cold / hot water pipe 14 is an absorbing type, for example, 7 ° C. The amount of heat input to the cold and hot water heater 100 is controlled by the controller 50. Specifically, the control device 50 starts all the pumps P1 to P3, and burns the gas in the gas burner 4 so that the temperature of the brine measured by the temperature sensor 61 is 7 ° C. The fire power of the gas burner 4 is controlled to be. In addition, the closing valves V1 to V3 are closed during the cooling operation.

The rare water absorbed by the rare water pump (P1) from the absorber (2) through the rare water liquid pipe (21) is connected to the refrigerant drain heat exchanger (16) or the low temperature heat exchanger (12), and the high temperature heat exchanger (13). In addition to the light oil, some are sent to the high temperature regenerator 5 via the exhaust gas heat recovery 40. Since the rare absorbent liquid returned to the high temperature regenerator 5 is heated by the flame by the gas burner 4 and the high temperature combustion gas in this high temperature regenerator 5, the refrigerant in this rare absorbent liquid is evaporated and separated. The intermediate absorbent liquid whose concentration is increased by evaporating and separating the refrigerant from the high temperature regenerator 5 is sent to the low temperature regenerator 6 via the high temperature heat exchanger 13. In this low temperature regenerator (6), the intermediate absorbent liquid is heated by the high temperature refrigerant steam supplied from the high temperature regenerator (5) through the coolant pipe (31) and flows into the heat transfer pipe (31A), and the coolant is further separated to further increase the concentration. This concentrated absorbent liquid is sent to the absorber 2 via the concentrated absorbent liquid pump P2 and the low temperature heat exchanger 12, and is scattered from above the concentrated dispersion machine 2C.

On the other hand, the refrigerant separated and generated in the low temperature regenerator 6 enters the condenser 7 to condense. Then, the coolant liquid generated in the condenser 7 enters the evaporator 1 via the coolant pipe 33 and is lifted by the operation of the coolant pump P3 to cool / hot water pipes from the spreader 1C. 14 is distributed over the array pipe 14A.

Since the refrigerant liquid scattered on the heat pipe 14A takes vaporization heat from the brine passing through the inside of the heat pipe 14A and evaporates, the brine passing through the inside of the heat pipe 14A is cooled, so that the brine that lowers the temperature is a cold / hot water pipe. It is supplied to heat load from 14, and cooling operation, such as cooling, is performed.

The refrigerant evaporated in the evaporator 1 enters the absorber 2 and is absorbed by the concentrated absorbent liquid supplied from the low temperature regenerator 6 and scattered from above, and stored in the rare absorbent liquid pool 2A of the absorber 2. The circulation returned to the high temperature regenerator 5 by the rare water absorbing pump P1 is repeated. In addition, the heat generated when the absorbent liquid absorbs the refrigerant is cooled by the heat transfer pipe 15A of the cooling water pipe 15 disposed in the absorber 2.

In the heating operation, the absorption cold / hot water heater 100 such that the temperature at the outlet side of the evaporator 1 of the brine (for example, hot water) circulated and supplied to the heat load through the cold / hot water pipe 14 becomes a predetermined set temperature, for example, 55 ° C. The amount of heat inputted into) is controlled by the controller 50. Specifically, the control device 50 starts all the pumps P1 to P3, and also burns the gas in the gas burner 4 so that the temperature of the brine measured by the temperature sensor 61 is 55 ° C. The fire power of the gas burner 4 is controlled to be. In addition, the circulation of the cooling water to the cooling water pipe 15 is stopped. In addition, the closing valves V1 to V3 are closed during the heating operation.

In this case, the refrigerant evaporated from the rare absorbent liquid in the high temperature regenerator 5 enters the absorber 2 and the evaporator 1 from the middle of the refrigerant pipe 31 mainly through the refrigerant pipe 32 having a small flow resistance. The water supplied from the hot water pipe 14 is condensed by heat exchange with the heat transfer pipe 14A, and the water flowing inside the heat transfer pipe 14A is heated by the heat of condensation at this time. The brine which raised the temperature in this way is supplied to the heat load from the cold / hot water pipe 14, and heating operation is performed.

The refrigerant condensed by heating in the evaporator 1 enters the absorber 2 through the refrigerant pipe 35 from the refrigerant liquid holding part 1B at the bottom of the evaporator 1 by the refrigerant pump P3, The absorber 2 is mixed with the absorbent liquid flowing from the high temperature regenerator 5 after passing through the absorbent liquid tube 23 and the opening / closing valve V1, and from the rare absorbent liquid tube 21 by operation of the rare absorbent liquid pump P1. In addition to the refrigerant drain heat exchanger (16) or the low temperature heat exchanger (12) and the high temperature heat exchanger (13), a part is sent to the high temperature regenerator (5) via the exhaust gas heat recovery (40).

FIG. 2 is a perspective view showing the exhaust gas heat recovery 40, FIG. 3 is a longitudinal cross-sectional view showing the exhaust gas heat recovery 40, and FIG. 4 is a perspective view showing the exhaust gas heat recovery 40 from above. 5 is a longitudinal cross-sectional view which schematically shows the exhaust gas heat recovery machine 40. In addition, the directions before and after, left, right, and up and down described below indicate the direction when viewed from the front side in the state where the exhaust gas heat recovery unit 40 is installed as shown in FIG. 2.

The exhaust gas heat recovery unit 40 accommodates a part of the fourth rare water absorbing tube 21D, and exhausts the rare water absorbing liquid flowing through the fourth rare water absorbing tube 21D from the heat exchange part 5A of the high temperature regenerator 5. 40 A of heat exchange chambers heated by gas, and the flue 40B which stood up in the substantially perpendicular direction which exhausts the exhaust gas after heat exchange to the flue part 70 of the installation side are provided.

The exhaust gas heat recovery unit 40 horizontally has an upper plate 41A, a rear plate 41B, a left plate 41C, a right plate 41D, and an upper portion of the left plate 41C on the right plate 41D side. The top plate 41E bent and formed, and the substantially box-shaped case 41 which has the bottom plate 41F are provided, and 40 A of heat exchange chambers are formed by these plates 41A-41F. A portion of the fourth rare water absorbing tube 21D is accommodated in the heat exchange chamber 40A through the rear plate 41B, and a portion of the fourth rare water absorbing tube 21D accommodated in the heat exchange chamber 40A is transferred to the heat transfer tube 21E. It consists of: The bottom plate 41F is provided with an exhaust gas introduction port (not shown) for connecting the exhaust path 17 (FIG. 1) of the exhaust gas.

The stack 40B is formed in a substantially angular cylinder shape, and is arranged offset to the right side plate 41D with respect to the heat exchange chamber 40A so as to partially overlap the top plate 41E of the heat exchange chamber 40A. In more detail, the stack 40B is arrange | positioned so that the centerline C may be located inside rather than the right side board 41D. In the stack 40B, a flange portion 43 is formed at the outlet opening 42 to connect with the flue portion 70 on the facility side. In addition, although the state in which the stack 40B is arrange | positioned close to the thick plate 41B is shown in FIGS. 2-4, the position of the stack 40B in the front-back direction is arbitrarily according to the position of the flue part 70 of the installation side, etc. you can change it.

An opening 44 for discharging the exhaust gas in the heat exchange chamber 40A to the stack 40B is formed in the top plate 41E where the stack 40B does not overlap. The opening part 44 is formed in substantially rectangular shape, is provided in the substantially center of the left-right direction of the top plate 41E, and is connected to the chimney 40B by the flue conductor 45. As shown in FIG.

The flue body 45 is a flue seat 45A extending upward from the top plate 41E on the left plate 41C side, and the flue plate formed by bending the flue seat 45A horizontally to the stack 40B side. 45B is provided. The flue seat 45A is inclined toward the stack 40B, thereby reducing the flow resistance of the exhaust gas. The flue top plate 45B extends to the right side plate 41D, and the flue top plate 45B is provided with the opening 46A in the part which overlaps with the chimney 40B. In addition, the flue conductor 45 is a flue plate 45C formed by extending the front plate 41A upward from the top plate 41E, and a year formed by extending the plate plate 41B upward from the top plate 41E. The back plate 45D and the right plate 41E formed by extending the right plate 41D upwards from the top plate 41E are provided. The light plate 45E has an opening 46B in a portion overlapping with the stack 40B. ) Is formed. These openings 46A and 46B constitute the inlet opening 46 of the stack 40B.

In the opening 44 of the top plate 41E, three sides 44A to 44C separated from the stack 40B are arranged at intervals from the flue 45, and one side 44D on the side of the stack 40B is a stack ( It is formed so that it may be arrange | positioned outside the inner wall 47 of 40B. Accordingly, the edge portions 41E1 to 41E3 are formed in the top plate 41E between the three sides 44A to 44C of the opening 44 and the flue 45, and one side 44D of the opening 44. And the condensation water receiving piece 41E4 which receives the condensation water falling from the stack 40B between the and the flue plate 45E.

In the top plate 41E located directly below the inner wall 47 of the stack 40B, a stop plate 48 is provided to prevent condensation water from flowing into the heat exchange chamber 40A. The stopping plate 48 is formed from the front plate 41A to the rear plate 41B at the edge of one side 44D of the opening 44, and is located outside the inner wall 47 of the stack 40B.

Immediately below the stack 40B that does not overlap with the top plate 41E, a condensation water receiver 49 is formed to block the lower portion of the stack 40B. The condensation water receiver 49 is provided at a position lower than the height of the top plate 41E, and the condensation water receiver 49 is provided with a discharge port 49A for discharging the condensation water collected in the condensation water receiver 49. It is.

Next, the operation of the exhaust gas outlet stack structure of the exhaust gas heat recovery unit 40 will be described.

In the exhaust gas heat recovery machine 40, the stack 40B is disposed so as to partially overlap the top plate 41E of the heat exchange chamber 40A, and the opening 44 is formed in the top plate 41E in which the stack 40B does not overlap. Therefore, it is possible to prevent the dew condensation generated in the inner wall 47 of the stack 40B and the dew condensation generated in the flue portion 70 on the installation side from falling into the opening 44. In addition, since the stopping plate 48 is provided outside the inner wall 47 of the stack 40B, the condensation water on the top plate 41E can be prevented from entering the heat exchange chamber 40A. In addition, the inflow of condensation water falling from the inner wall 47 into the heat exchange chamber 40A can be prevented reliably. Therefore, the number of dew condensation which generate | occur | produced in the inner wall 47 of the position which overlaps with the top plate 41E, and the number of dew condensation from the flue part 70 which fall to the position which overlaps with the top plate 41E are shown by the dotted line in FIG. It falls to the condensation water receiving piece 41E4 of the top plate 41E.

Since the dew condensation receiving part 49 is formed immediately under the stack 40B which does not overlap with the top plate 41E, as shown by the dotted line in FIG. 5, the inner wall 47 of the position which does not overlap with the top plate 41E is shown. The number of dew condensation generated in the c) and the condensation water from the flue part 70 falling to a position not overlapping with the top plate 41E falls directly into the condensation water receiving part 49. The condensation water receiver 49 is provided at a position lower than the height of the top plate 41E, and since the opening 46B is formed at a portion overlapping the stack 40B, the opening plate 46E is provided with this opening ( The top plate 41E and the condensation water receiving part 49 communicate with each other by 46B). As a result, the dew condensation water on the top plate 41E flows into the condensation water receiving unit 49, as indicated by the dotted line in FIG. 5, so that the condensation water on the top plate 41E flows into the heat exchange chamber 40A. It can certainly be prevented. In addition, since the number of dew condensation becomes difficult to accumulate on the top plate 41E, the height of the stop plate 48 can be made low, and the flow resistance of the exhaust gas can be made small.

Since the condensation water receiver 49 is provided with a discharge port 49A, the condensation water collected in the condensation water receiver 49 is discharged from the outlet 49A. Thus, since the inflow of the dew condensation water to 40 A of heat exchange chambers can be surely prevented, the heat exchanger tube 21E can be formed using relatively inexpensive iron etc., without making it expensive stainless steel excellent in corrosion resistance.

The stack 40B is arranged such that a part of the stack 40B overlaps with the top plate 41E of the heat exchange chamber 40A, and the center line C of the stack 40B is located inside the right plate 41D. In comparison with the case where the top plate 41E of the 40A does not overlap, the inlet opening 46 of the stack 40B can be adjacent to the opening 44 of the top plate 41E, so that the bending angle of the exhaust gas flow Can be made small, and as a result, the flow resistance of exhaust gas can be made small. In addition, since the exhaust gas heat recovery unit 40 can be prevented from being enlarged in the offset direction, the nozzle 52 for the exhaust gas analysis and the nozzle for the exhaust gas thermometer side (for example, on the side wall of the stack 40B) 53) can be installed.

Moreover, since the stack 40B is arrange | positioned so that a part may overlap with the flue top board 45B and the flue board 45E of the flue conductor 45, the inlet opening part 46 of the flue 40B may be made into the flue 45 Can be formed on both the flue top plate 45B and the flue plate 45E, and the opening area of the inlet opening 46 can be made large, so that the flow resistance of the exhaust gas can be made small. Therefore, in order to make the opening area of the inlet opening 46 large, it is not necessary to enlarge the stack 40B in the front and rear or in the vertical direction, so that the stack 40B can be downsized.

As described above, according to the present embodiment, a part of the stack 40B is overlapped with the top plate 41E of the heat exchange chamber 40A, and the opening 44 is provided in the top plate 41E in which the stack 40B does not overlap. Forming and connecting the opening 44 and the chimney 40B with the flue conductor 45, and the condensation receiving part 49 is formed directly below the chimney 40B that does not overlap with the top plate 41E. I did. With this configuration, since the condensation water generated in the stack 40B and the condensation water generated in the flue part 70 on the installation side are collected in the condensation water receiving part 49, the condensation water is transferred from the opening 44 of the top plate 41E to the heat exchange chamber. Inflow to 40A can be prevented.

In addition, according to the present embodiment, since the inlet opening 46 of the stack 40B is adjacent to the opening 44 of the top plate 41E, the bending angle of the exhaust gas flow can be reduced, so that the flow resistance of the exhaust gas is reduced. Can be made small.

Moreover, according to this embodiment, since the top plate 41E just under the inner wall 47 of the chimney 40B was provided with the stopping plate 48 which prevents inflow of condensed water into the heat exchange chamber 40A, the top plate 41E is provided. The dew condensation water in the c) can be prevented from flowing into the heat exchange chamber 40A.

In addition, according to the present embodiment, since the stopping plate 48 is disposed outside the inner wall 47 of the stack 40B, condensation water falling from the inner wall 47 can be prevented from flowing into the heat exchange chamber 40A. have.

Moreover, according to this embodiment, since the dew condensation receiving part 49 was provided below the top plate 41E, and the top plate 41E and the condensation water receiving part 49 were communicated, the number of condensation on the top plate 41E Since the condensation water receiver 49 flows down, the condensation water on the top plate 41E can be reliably prevented from flowing into the heat exchange chamber 40A. In addition, since the number of dew condensation becomes difficult to accumulate on the top plate 41E, the height of the stop plate 48 can be made low, and the flow resistance of the exhaust gas can be made small.

Moreover, according to this embodiment, the flue body 45 is equipped with the flue top board 45B and the flue board 45E, and arrange | positions a part 40 to the flue top board 45B and the flue board 45E, and arranges the stack 40B. The inlet opening 46 of the stack 40B was formed on both of the flue top plate 45B and the flue plate 45E. By this structure, since the opening area of the inlet opening 46 can be made large, the flow resistance of exhaust gas can be made small. Therefore, in order to make the opening area of the inlet opening 46 large, it is not necessary to enlarge the stack 40B in the front and rear or in the vertical direction, so that the stack 40B can be downsized.

However, the said embodiment is a kind of this invention, and can change suitably in the range which does not deviate from the meaning of this invention.

For example, in the said embodiment, although the structure provided with the gas burner 4 which burns fuel gas and heats as heating means for heating an absorption liquid in the high temperature regenerator 5 was demonstrated, it is not limited to this, It is good also as a structure provided with the burner which burns kerosene and A heavy oil, and the structure heated using heat, such as steam and exhaust gas.

Moreover, in the said embodiment, although the absorption type cold water heater 100 was formed in what is called series flow cycle which supplies the absorption liquid which flowed out from the high temperature regenerator 5 to the low temperature regenerator 6, it is not limited to this, For example, an absorber The present invention may be applied to an absorption cold / hot water formed by a so-called parallel flow cycle which is split into two into a high temperature regenerator and a low temperature regenerator extending from the above, or a so-called reverse flow cycle in which an absorbent liquid flowing out of the low temperature regenerator is supplied to the high temperature regenerator.

In addition, although the absorption type refrigerant | coolant water heater is a double-use type in the said embodiment, it cannot be overemphasized that this invention is applicable to the absorption chiller and water heater and absorption type heat pump apparatus of the single-use type | mold, triple-use type, and triple-use type.

2 Absorber 5 High Temperature Regenerator
5A Heat Exchanger (Combustion Chamber) 17 Exhaust Path
21D 4th Absorption Liquid Tube (Absorbent Tube) 21E Heat Transfer Tube
40 Exhaust Gas Heat Recovery Machine 40A Heat Exchanger Chamber
40B stack 41E top plate
44 opening 45 flue
46 Entrance opening 47 Inner wall
48 Jersey plate 49
70 flue 100 absorption chiller

Claims (6)

A heat exchange chamber accommodating a portion of the absorption liquid pipe from the absorber of the absorption chiller to the high temperature regenerator; In the exhaust gas outlet stack structure of the exhaust gas heat recovery machine which exhausts gas to the outside through a stack of standing in the substantially vertical direction,
A part of the stack is overlapped with the top plate of the heat exchange chamber, an opening is formed in the top plate where the stack does not overlap, and the opening and the stack are connected by a conductor, and the stack is not overlapped with the top plate. The exhaust gas outlet stack structure of the exhaust gas heat recoverer, characterized in that the condensation water receiving unit is formed immediately below the stack. The method according to claim 1,
An exhaust gas outlet stack structure of an exhaust gas heat recoverer, wherein the inlet opening of the stack is adjacent to the opening of the top plate. The method according to claim 1 or 2,
An exhaust gas outlet stack structure of an exhaust gas heat recovery device, characterized in that a stop plate for preventing condensation water from entering the heat exchange chamber is provided on the top plate directly below the inner wall of the stack. The method according to claim 3,
An exhaust gas outlet stack structure of an exhaust gas heat recoverer, wherein the blocking plate is disposed outside the inner wall of the stack. The method according to any one of claims 1 to 4,
The condensation water receiver is provided under the top plate, and the top plate and the condensation water receiver are in communication with each other. The method according to any one of claims 1 to 5,
The flue body has a flue top plate and a flue side plate,
The stack is disposed to overlap a part of the flue top plate and the flue side plate,
An exhaust gas outlet stack structure of an exhaust gas heat recovery machine, wherein the inlet opening of the stack is formed on both of the flue top plate and the flue side plate.

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