CZ305869B6 - Modular condensation recuperator - Google Patents

Abstract

In the present invention, there is disclosed a modular condensation recuperator consisting of an inlet module (A) for supply of surrounding air and an outlet module (B) for exit of the surrounding air into the object. Each module is formed by a casing (1) separated by partitions (2) that are situated alternatively one above the other, parallel to each other and which are inclined in the condensate discharge direction. One end of these partitions (2) is secured to the casing (1) internal jacket, while the other end thereof is free. Thus, mutually permeable chambers (12) are created between the partitions (2), wherein a system of parallel diathermic pipes (3) is arranged in meander-like manner in the chambers (2). One end of said pipes (3) is connected through the mediation of an inlet distributor-merger (4.1) to an inlet chamber (5.1), while the other end thereof is connected through the mediation of an outlet distributor-merger (4.2) to an outlet chamber (5.2). Adjacent chambers (12) of the connecting modules (A) and (B) are interconnected by an oppositely situated first interconnecting opening (13.1) in the inlet module (A) casing (1) and by a second interconnecting opening (13.2) performed in the outlet module (B) casing (1). The outlet chamber (5.2) of the inlet module (A) and the inlet chamber (5.1) of the interconnected outlet module (B) are interconnected, as well. A collecting trough (16) for condensate collection is fixedly inserted on the inlet module (A) casing (1) base. The inlet module (A) is provided with an intake opening (6) and a discharge opening (14) for exhaust of exhausted air. The outlet module (B) is provided with both in inlet piping (10) opening from the casing (1) into the object room and entering via a first fan (11) to the upper chamber (12) thereof, and a surrounding air outlet (7) that is connected to the outlet chamber (5.2) thereof and opening outside the casing (1) into the object room via a second fan (8) and a discharge piping (9).

Description

Modular condensing recuperator

Field of technology

The present solution relates to an improved heat recovery system, especially for apartments and smaller houses, and to improving the availability of a condensing heat exchanger for users.

Prior art

At present, plate heat exchangers made of plastic or metal casting are mainly used for heat recovery. The current solution is disadvantageous in that these exchangers have very small gaps between the individual plates, so that at lower temperatures of the supplied outdoor air, the condensate formed between the plates can freeze. In addition, small cracks are clogged with dust. Manufacturers eliminate these shortcomings by preheating the supply air outside or by mixing dampers to mix the supply air outside with the supply air. These solutions are technically and costly, and in addition do not allow sufficient use of the heat gain from the condensation of internal moisture.

The essence of the invention

These shortcomings are substantially eliminated by a modular condensing recuperator for the recovery of heat removed from the building by means of an inlet pipe, a first fan and an outlet pipe, according to the present solution, where the outdoor air is heated through a suction opening. The essence of the new solution in its one main embodiment is that the recuperator consists of two interconnected modules, namely an inlet module for the supply of outdoor air and an outlet module for the outlet of outdoor air to the building. Each of the modules consists of a cabinet divided by parallel partitions placed alternately on top of each other. One end of the partitions is attached to the inner shell of the cabinet and the other end is free. In this way, mutually permeable chambers are formed between the partitions, in which a set of parallel heat-permeable pipes is placed in a meandering manner. Their one end is connected to the inlet chamber via an inlet manifold-combiner and their other end is connected to the outlet chamber via an outlet manifold-combiner.

Adjacent chambers of the connected input and output module are connected by an opposite first connecting hole in the input module housing and a second connecting hole in the output module housing. Also, the output chamber of the input module and the input chamber of the connected output module are interconnected. A condensate tray is firmly slid onto the base of the input module cabinet, which is open. The inlet module is provided with a suction opening with a suction pipe for the entry of outside air opening into its inlet chamber and an outlet opening for the exhaust of exhaust air, to which an exhaust pipe opening outside the building is connected. The outlet module intended for the outlet of outdoor air to the building is provided with an inlet duct leading from the cabinet to the building room and opening via the first fan to its upper chamber, and with an outdoor air outlet connected to the outlet chamber of this outlet module and opening outside the cabinet to the building room via second fan and through the outlet pipe. The partitions are inclined in the direction of the condensate drain.

In one possible embodiment, the output module is located above the input module. A suction opening for the supply of outdoor air opening into the inlet chamber is formed in the side of the lowest chamber of the inlet module. Also, the outlet opening is formed in the side of the lowest chamber of the input module, in front of the inlet manifold-combiner. In this case, the collecting tank is located below the suction opening and the outlet opening, where it is slightly suspended, and is provided with an outlet opening for condensate drainage.

- 1 CZ 305869 B6

In another embodiment, where again the outlet module is located above the inlet module, an outdoor air intake opening which opens into the inlet module inlet chamber and an exhaust air outlet opening into the lower chamber are formed in the side of the sump. The sump is tightly slid onto the base of the inlet module cabinet.

Another possibility is that the output module is located next to the input module. In this case, the supply of outside air through the intake port and the intake manifold, and the exhaust air outlet through the outlet port and the exhaust pipe are formed in the upper base of the inlet module. The exhaust air inlet duct and the outside air outlet are then formed in the upper base of the secondary, connected, outlet module. Both modules are equipped with a bath with drain holes in their lower part. In this embodiment, it is possible to place a third fan for the short-term intensive extraction at the outlet of the exhaust air duct.

In all these embodiments, it is advantageous if the individual tubes of the heat-permeable pipe system are wound in a spiral, thus increasing the efficiency of the condensing recuperator.

If required, at least one additional module can be connected between the input and output module. This module is again formed by a housing divided one above the other by parallel parallel, and inclined in the direction of the condensate drain, partitions. One end of them is attached to the inner shell of the cabinet and the other end is free. In this way, mutually permeable chambers are formed between the partitions, in which a system of parallel heat-permeable pipes is placed in a meandering manner. One end of the pipe is connected via an inlet manifold to the inlet chamber for connection to the outlet chamber of one of its located modules, and the other end is connected via an outlet manifold to the outlet chamber for connection to the inlet chamber of the other located module. . A first connection hole is formed in the lower base of the housing of this insert module for connecting its lower chamber to the upper chamber from one side of the module located through its second connection hole. Similarly, a second connection hole is formed in the upper base of the insert module housing for connecting its upper chamber to the lower chamber from the other side of the module located through its first connection hole.

In the second main embodiment, the modular condensing recuperator consists of an inlet module for the entry of outdoor air and a plate heat exchanger. The inlet module consists of a cabinet divided one above the other by alternating parallel bars, inclined in the direction of the condensate drain. One end of them is attached to the inner shell of the cabinet and the other end is free. Thus, mutually permeable chambers are formed between the partitions, in which a system of parallel heat-permeable pipes is mounted in a meandering manner. One end of the pipe is connected to the inlet chamber via an inlet manifold-combiner and their other end is connected to the outlet chamber via an outlet manifold-combiner. This outlet chamber is connected to the outdoor air inlet space of the plate heat exchanger. A first connecting hole is formed in the upper base of the housing, which connects the upper chamber of the inlet module with the inner space for air outlet from the plate heat exchanger object through a second connecting hole formed in the base of the plate heat exchanger. The condensate collection tray is tightly pushed onto the base of the inlet box. The inlet module is provided with a suction opening with a suction pipe for the entry of outside air opening into the inlet chamber and an outlet opening for the exhaust of the exhaust air, to which an exhaust pipe opening outside the building is connected. The plate heat exchanger is provided on the one hand with an inlet pipe opening into the building room and opening via the first fan into the plate heat exchanger space, and on the other hand with an outside air outlet opening outside the plate heat exchanger into the building room via a second fan and via an outlet pipe.

Also in this second main embodiment, there are two possible variants of the location of the suction and discharge opening. In one variant, the suction opening for the supply of outdoor air opening into the inlet chamber is formed in the side of the lowest chamber of the inlet module and the outlet opening is also formed in the side of the lowest chamber of the inlet module, in front of the inlet manifold.

-2GB 305869 B6 cam. The collecting bath is located below the suction and discharge opening, where it is slightly suspended, and is provided with an outlet opening for condensate drainage. In the second variant, the suction and discharge openings are formed in the side of the collecting tank, which is tightly slid onto the base of the input module housing.

Also in this case, it is advantageous if the individual tubes of the heat-permeable pipe system are wound in a spiral.

Said modular condensing recuperator is designed mainly for individual assembly directly by the investor. The modular design of the condensing recuperator allows easy distribution of individual modules, its necessary accessories and easy assembly.

The internal air extraction chambers are permeable to each other and their partitions are inclined in the direction of the exhaust air so that the condensate flows into the condensate bath at the base of the condensing recuperator module, from where it is discharged to the waste or outside the building. In this embodiment, the condensing recuperator washes itself out. The recuperator does not freeze even in Arctic frosts. The efficiency of the recuperator, which depends on the length and number of heat-permeable pipes used in relation to the exchanged air, increases the heat obtained from the condensation of internal moisture. The recuperator according to the technical solution is practically maintenance-free. It can be advantageously fitted at the outside air inlet with a filter box and a small fan designed to cover the pressure losses caused by filtration.

Explanation of drawings

The modular condensing recuperator according to the proposed solution will be further elucidated according to the attached drawings, where several possible embodiments are schematically.

Fig. 1A shows an embodiment of the condensing recuperator modules built on top of each other, where it is possible to carry out condensate drainage together in a duct with polluted air, or to add condensate drainage and air drainage separately by adding a one-sided branch pipe. Giant. 1B is a section A-A.

Fig. 2B schematically shows a variant in which the condensing recuperator modules are placed side by side. Giant. 2A is a section B-B.

Fig. 3 A shows the assembly of a special condensing recuperator module with a plate heat exchanger and a module with a tube heat exchanger. Giant. 3B is a section A-A.

Examples of embodiments of the invention

The modular condensing recuperator for heat recovery from the building consists of two interconnected modules, namely input module A and output module B. In the example in Fig. 1A and 1B, a variant is shown where the condensing recuperator consists of an input module A and built on it. output module B. Input module A is intended for the supply of outdoor air and output module B is intended for the output of heated air into the room of the building and at the same time for the discharge of indoor humid air outside the building. Each of the modules A and B is formed by a housing 1 divided by parallel partitions 2 alternately arranged one above the other, which are inclined in the direction of the condensate drain. These partitions 2 are fixed at one end to the inner shell of the housing 1 and have the other end free. Thus, interconnected and permeable chambers 12 are formed in the space of the housing 1 between these partitions 2. A set of parallel heat-permeable pipes 3 is meanderingly accommodated in the chambers 12. One end of these heat-permeable pipes 3 is via an inlet manifold 4,1 located inside the housing 1 at its lower bases are connected to the inlet chamber 5.1 and their other end is via an outlet splitter-combiner

-3 CZ 305869 B6

4.2 located again inside the housing 1 at its upper base connected to the outlet chamber 5.2. Adjacent chambers 12 of connected modules, i.e. upper chamber 12 of input module A and lower chamber 12 of output module B, are connected by opposite first connecting hole 13.1 in housing 1 of input module A and second connecting hole 13.2 formed in housing 1 of output module B. thus, the outlet chamber 5.2 of the inlet module A and the inlet chamber 5.1 of the connected outlet module B are interconnected. The inlet module A is provided with an outdoor air intake opening 6 adapted to connect a suction pipe and opening into the inlet chamber 5.1 and an outlet opening 14. which is connected to the exhaust pipe 15 for the exhaust of the exhaust air. This exhaust pipe 15 opens out of the building and below it, a condensate collecting tank 16 is tightly pushed to the base of the housing 1 of the inlet module A, which is open. The outlet module B, intended for the outlet of outdoor air to the building, is provided on the one hand with an inlet duct 10 opening from the housing 1 to the building room and opening via a first fan 11 to the upper chamber 12 of the outlet module B, and on the other hand with an outdoor air outlet 7 connected to the outlet chamber 5.2. of this outlet module B and opening outside the cabinet 1 into the room of the building via the second fan 8 and via the outlet duct 9.

The bundle of heat-permeable duct 3 for the supply of outdoor air is guided through chambers 12 of approximately twice the cross-section than the sum of the cross-sections of the tubes of heat-permeable duct 3 used.

An outdoor air intake opening 6 opening into the inlet chamber 5.1 may be formed in the side of the lowermost chamber 12 of the inlet module A and an exhaust air outlet 14 may also be formed in the side of the lowermost chamber 12 of the inlet module A in front of the inlet manifold 4.1. The collecting bath 16 is then located below the suction opening 6 and the outlet opening 14, where it is slightly suspended, and is provided with an outlet opening 18 for draining condensate. Alternatively, the outdoor air intake opening 6 opening into the inlet chamber 5.1 of the inlet module A and the exhaust air outlet opening 14 opening into the lower chamber 12 may be formed in the side of the collecting tank 16 which is tightly slid onto the base of the housing 1. input module A.

The inlet module A supplies outside air sucked through the suction opening 6 into the inlet chamber 5.1 of the housing 1 of this inlet module A of the condensing recuperator. Furthermore, the outside air enters via the inlet manifold-combiner 4.1 into the bundle of heat-permeable duct 3, which is meanderingly guided through the chambers 12 of the housing 1 of the inlet module A of the condensing recuperator. From there, it is led via the outlet manifold 4.2 of the input module A via its outlet chamber 52 to the inlet chamber 5.1 of the outlet module B, from where it passes again through the inlet chamber 5.1 and the inlet manifold 4.1 of the outlet module B by a bundle of heat-permeable duct 3. a second fan 8 into the living rooms through the outlet pipe 9.

Opposite to the supply air, internal humid and degraded air is discharged, usually from the toilet, bathroom and kitchen through the inlet pipe 10, is sucked out by the first fan 11 and passes through chambers 12 of outlet module B and condenser recuperator inlet module A. through second connection opening 13.2 and a first connection opening 13.1 of the inlet module A. From the condensing recuperator, the exhaust air is blown out through the outlet opening 14 via an outlet blow pipe 15 outside the building. The condensate formed flows down the inclined partitions 2 through the second connecting opening 13.2 and the first connecting opening 13.1 into the collecting tank 16 and flows out of the object through the outlet opening 14.

In Figs. 2B and 2A, the inlet module A is located next to the outlet module B. The intake opening 6 for the supply of outdoor air is in the upper part of the inlet module A, as well as the outlet opening 14 for the exhaust of indoor air. It is possible here to advantageously install a third fan 17 at the outlet of the exhaust pipe 15 for short-term intensive extraction, for example from a toilet or a kitchen. The interconnection of the input module A and the output module B is again via the output chamber 5.2 of the input module A and the input chamber 5.1 of the output module B and by connecting the chambers 12 through the first connection opening 13.1 of the input module A and the second connection opening 13.2.

-4EN 305869 B6 of the output module B. The condensate formed flows into the collecting tanks 16, from where it is preferably discharged through the outlet openings 18 into the toilet cistern or outside the building. The function of this design is similar to the variant where modules A and B are placed on top of each other.

In both of the variants described above, it is possible to connect at least one further module between the input module A and the output module B. This module is not shown in the drawings, but again consists of a housing 1 divided above each other by parallel parallel, inclined in the direction of condensate drainage, partitions 2, between which mutually permeable chambers 12 are formed, in which a system of parallel heat-permeable pipes 3 is meanderingly placed. one end is connected to the inlet chamber 5.1 for connection to the outlet chamber 5.2 from one side of the module located by means of the inlet manifold-combiner 4.1 and their other end is connected to the outlet chamber 5.2 for connection to the inlet chamber 5.1 via an outlet manifold-combiner 4.1. from the other side of its located module. In the lower base of the housing 1 of this insert, a first connecting opening 13.1 is formed for connecting its lower chamber 12 to the upper chamber 12 from one side of its module via its second connecting opening 13.2. Analogously, a second connecting opening 13.2 is formed in the upper base of the housing 1 of the inserted module for connecting its upper chamber 12 to the lower chamber 12 from the other side of the module located via its first connecting opening 13.1. This solution is used if the user requests to increase the efficiency of recuperation through a larger heat transfer area by inserting a bundle of pipes in another module.

In Figs. 3A and 3B, the condensing recuperator modules are placed on top of each other similarly to Fig. 1, but the output module B is replaced by a plate heat exchanger 19. The inlet module A is formed as described above. Its outlet chamber 5.2 is connected to the outdoor air inlet space of the plate heat exchanger 19, and the first connecting hole 13.1 connects the upper chamber 12 of the inlet module A to the inner air outlet space of the plate heat exchanger object 19 through a second connecting hole 13.2 formed in the plate heat exchanger base 19. .

The plate heat exchanger 19 is provided on the one hand with an inlet pipe 10 opening into the building room and opening via the first fan 11 into the plate heat exchanger space 19, and on the other hand with an outdoor air outlet outside the plate heat exchanger 19 into the building room via a second fan 8 and via an outlet pipe 9.

Also in this second main embodiment, there are two possible variants of the location of the suction opening 6 and the outlet opening 14, either in the side of the lowest chamber 12 of the inlet module A or in the collecting tank 16, as described above. It is also advantageous if the tubes of the heat-permeable pipe 3 in the inlet module A are wound in a spiral.

In this embodiment, with the plate heat exchanger 19 used on the suction side of the indoor air and the air blown into the manifolds, the advantages of a tube recuperator in that it does not freeze are advantageously combined, and the advantages of a larger heat transfer area and plate heat exchanger efficiency. The outside air preheated in the tube recuperator can no longer cause the condensate to freeze in the plate recuperator.

Industrial applicability

The modular condensing recuperator according to the presented solution expands the offer of air recuperation in buildings. It makes the implementation of air recuperation more affordable. The recuperator can be easily placed in separate apartments or offices and workplaces. It can also be used in a reasonable size for ventilation of individual school classes.

Claims (5)

PATENT CLAIMS A modular condensing recuperator for the recovery of heat removed from a building by means of an inlet pipe (10), a first fan (11) and an outlet pipe (15), where outdoor air is heated through a heat exchanger through a suction opening (6), characterized in that it consists of from two interconnected modules (A, B), namely from the inlet module (A) for the supply of outdoor air and from the outlet module (B) for the outlet of outdoor air to the building, each of which consists of a cabinet (1) divided one above the other alternately placed parallel partitions (2), one end of which is fixed to the inner shell of the housing (1) and the other end is free, whereby mutually permeable chambers (12) are formed between these partitions (2), in which a set of parallel heat-permeable pipes (3) is placed in a meandering manner. ), one end of which is connected to the inlet chamber (5.1) via an inlet manifold (4.1) and the other end of which is connected to the inlet via a manifold (4.2) an outlet chamber (5.2), wherein the adjacent chambers (12) of the connected input module (A) and the output module (B) are connected by opposite first connecting openings (13.1) in the housing (1) of the input module (A) and the second connecting opening ( 13.2) formed in the housing (1) of the output module (B) and also the output chamber (5.2) of the input module (A) and the input chamber (5.1) of the connected output module (B) are interconnected, with the input chamber (1) of the input module (B) connected to each other. module (A), which is open, the condensate collecting sump (16) is firmly inserted and this inlet module (A) is provided with a suction opening (6) with a suction pipe for the entry of outside air opening into the inlet chamber (5.1) and an outlet an exhaust air opening (14) to which an exhaust pipe (15) opening outside the building is connected and an outlet module (B) intended for the outlet of outdoor air to the building is provided with an inlet pipe (10) opening from the cabinet (1) into the room object and opening through the first in the nitrator (11) into its upper chamber (12), and on the one hand by an outdoor air outlet (7) connected to the outlet chamber (5.2) of this outlet module (B) and opening outside the cabinet (1) into the building room via a second fan (8) and via the outlet pipe (9), the partitions (2) being inclined in the direction of the condensate drain. Modular condensing recuperator according to claim 1, characterized in that the outlet module (B) is located above the inlet module (A), the suction opening (6) for the supply of outdoor air opening into the inlet chamber (5.1) being formed at the lowest side. chamber (12) of the inlet module (A) and the outlet opening (14) is also formed in the side of the lowest chamber (12) of the inlet module (A) in front of the inlet manifold-combiner (4.1) and the collecting bath (16) is located below the suction opening ( 6) and an outlet opening (14), where it is slightly projected, and is provided with an outlet opening (18) for condensate drainage. Modular condensing recuperator according to claim 1, characterized in that the outlet module (B) is located above the inlet module (A), the suction opening (6) for the supply of outdoor air opening into the inlet chamber (5.1) of the inlet module (A). and an exhaust outlet (14) for the exhaust air opening into the lower chamber (12) is formed in the side of the sump (16), which is tightly slid onto the base of the housing (1) of the inlet module (A). Modular condensing recuperator according to claim 1, characterized in that the outlet module (B) is located next to the inlet module (A), where the supply of outside air through the suction opening (6) and the suction line and the exhaust of indoor air through the outlet opening (14). ) and the exhaust pipe (15) are formed in the upper base of the inlet module (A) and the exhaust air inlet pipe (10) and the outside air outlet (7) are formed in the upper base of the secondary outlet module (B), both modules (A, B) are provided in their lower part with a tub (16) with outlet openings (18). Modular condensing recuperator according to Claim 4, characterized in that the exhaust air duct (15) has a third fan (17) arranged at its outlet. -6GB 305869 B6 A modular condensing recuperator according to claim 1 and any one of claims 2 to 5, characterized in that the individual tubes of the heat-permeable pipe system (3) are wound in a spiral. A modular condensing recuperator according to claim 1 and any one of claims 2 to 6, characterized in that at least one further module is connected between the outdoor air inlet module (A) and the outdoor air outlet module (B) to the building. housing (1) divided above each other by parallel parallel, inclined in the direction of condensate drainage, partitions (2), one end of which is fixed to the inner shell of the housing (1) and the other end is free, thus forming between these partitions (2) permeable chambers (12), in which a set of parallel heat-permeable pipes (3) is mounted in a meandering manner, one end of which is connected via an inlet manifold-combiner (4.1) to an inlet chamber (5.1) for connection to the outlet chamber (5.2) on one side thereof. located module and the other end of which is connected via an output splitter-combiner (4.2) to the output chamber (5.2) for connection to the input chamber (5.1) located on the other side of it module, and wherein in the lower base of the housing (1) of this inserted module a first connecting hole (13.1) is formed for connecting its lower chamber (12) to the upper chamber (12) of one of its located modules via its second connecting hole (13.2). and analogously, a second connecting hole (13.2) is formed in the upper base of the insert module housing (1) for connecting its upper chamber (12) to the lower chamber (12) of the module located on the other side thereof via its first connecting hole (13.1). A modular condensing recuperator for the recovery of heat removed from the building by means of an inlet pipe (10), a first fan (11) and an outlet pipe (15), wherein outdoor air is supplied through the exchanger through a suction opening (6), characterized in that consists of an inlet module (A) for the entry of outdoor air, which consists of a housing (1) divided by parallel parallel, inclined in the direction of condensate drainage, partitions (2), one end of which is fixed to the inner casing (1) and the other the end is free, whereby mutually permeable chambers (12) are formed between these partitions (2), in which a set of parallel heat-permeable pipes (3) is mounted in a meandering manner, one end of which is connected to the inlet chamber (4.1) by means of an inlet manifold-combiner (4.1). 5.1) and the other end of which is connected via an outlet manifold (4.2) to an outlet chamber (5.2), where this outlet chamber (5.2) is connected to the space m for the outdoor air inlet of the plate heat exchanger (19), and wherein a first connecting hole (13.1) is formed in the upper base of the housing (1), which connects the upper chamber (12) of the inlet module (A) to the inner space for air outlet from the plate object. exchanger (19) through a second connecting hole (13.2) formed in the base of the plate heat exchanger (19), the condensate collecting sump (16) and this inlet module (A) being tightly slid onto the base of the inlet module housing (1) is provided with a suction opening (6) with a suction pipe for the entry of outside air opening into the inlet chamber (5.1) and an outlet opening (14) for the exhaust air to which the exhaust pipe (15) leading outside the building is connected and where the plate heat exchanger ( 19) is provided on the one hand with an inlet pipe (10) opening into the building room and opening through the first fan (11) into the plate heat exchanger space (19), and on the other hand with an outdoor air outlet opening outside the plate heat exchanger (19) into the building room via the second venti (8) and via the outlet pipe (9). A modular condensing recuperator according to claim 1, characterized in that the outdoor air intake opening (6) opening into the inlet chamber (5.1) is formed in the side of the lowermost chamber (12) of the inlet module (A) and the outlet opening (14). it is also formed in the side of the lowest chamber (12) of the inlet module (A) in front of the inlet manifold-combiner (4.1) and the collecting bath (16) is located below the suction opening (6) and the outlet opening (14), where it is slightly suspended, and is provided with an outlet opening (18) for condensate drainage. A modular condensing recuperator according to claim 8, characterized in that the suction opening (6) for the supply of outdoor air opens into the inlet chamber (5.1) of the inlet -7EN 305869 B6 of the module (A) and the outlet opening (14) for the exhaust air opening into the lower chamber (12) are formed in the side of the collecting tank (16), which is tightly pushed onto the base of the housing (1) of the inlet module (A). . A modular condensing recuperator according to claim 8 and any one of claims 9 or 10, characterized in that the individual tubes of the heat-permeable pipe system (3) are wound in a spiral.