RU2678811C1 - Supply and exhaust unit - Google Patents

Abstract

FIELD: ventilation.SUBSTANCE: invention relates to ventilation and air conditioning with regenerative heat exchangers and can be used to create a microclimate in residential, public, administrative and industrial premises. Technical result is achieved due to the supply and exhaust unit for ventilation of the room, comprising: a chamber with a regenerative heat exchanger, made in the form of a porous fiber filter; external inlet nozzle, adapted to intake atmospheric external air through a regenerative heat exchanger into the internal nozzle of a pressure air duct and containing a valve device in its cavity; internal branch pipe of the pressure air duct, made with the possibility of intake of external atmospheric air into the room and containing a valve device in its cavity; internal exhaust duct nozzle, made with the possibility of exhausting air from a room through a regenerative heat exchanger into an external exhaust nozzle and containing a valve device in its cavity; external exhaust pipe, made with the possibility of emission of air from one room to the outside into the atmosphere and containing in its cavity valve device; electric fan that provides air flow for ventilation of a single room and adjacent to the regenerative heat utilizer and/or adjacent to one of the mentioned valve devices; wherein the external outlet pipe is connected to the internal pipe of the pressure air duct, the external inlet pipe is connected to the internal pipe of the exhaust air duct, and the said chamber with a regenerative heat exchanger forms an intermediate air duct that connects the internal branch pipe of the pressure air duct and the external outlet branch pipe with the internal branch pipe of the exhaust air duct and the external inlet branch pipe; outer outlet and the outer inlet are adapted to be connected via external ducts to the ambient air atmosphere, the internal pipe of the pressure air duct and the internal pipe of the exhaust air duct are made with the possibility of connection by internal air ducts with the room, where the said internal air ducts are located in the room and contain inlet and outlet openings, or the said internal air ducts are connected to the room by means of the said inlet and outlet openings providing ventilation of the room; design parameters that establish the balance of performance mentioned inlet and outlet openings are limited by the balance of air in the room, wherein the supply air volume is equal to or exceeds the volume of air removed from the room through the regenerative heat exchanger; supply and exhaust unit further comprises a relay and/or a controller providing or ensuring the operation of the supply and exhaust unit.EFFECT: technical result consists in increasing the efficiency of the room ventilation.17 cl, 17 dwg

Description

Field of Technology:

[0001] The invention relates to ventilation and air conditioning with regenerative heat exchangers and can be used to create a microclimate in residential, public, administrative and industrial premises. The prior art:

[0002] A forced-air and exhaust installation for ventilating an apartment with built-in exhaust openings for intake shafts in non-residential premises, containing pressure and exhaust ducts with intake and exhaust openings connected to channels for supply and exhaust air in the housing cavity by means of internal nozzles having valve devices and connected with the atmosphere of external air through external pipes, an electric fan and a chamber with regenerative heat exchanger, while the internal the surface of the case is covered with heat-insulating material, and in non-residential premises standard apartment exhaust openings of air intake shafts are placed (patent RU 127875 U1, class F24F 5/00, published May 10, 2013).

[0003] The disadvantage of this technical solution is: increased energy consumption, unacceptable microclimate due to excessive drainage of room air and the complexity of manufacturing.

Disclosure of the invention:

[0004] The claimed invention provides a technical result, which consists in increasing the ventilation efficiency of at least one room.

[0005] Below are disclosed all general and particular essential features of the invention, characterizing their causal relationship with the specified technical result, sufficient for implementation by a person skilled in the art.

[0006] To solve the technical result, a supply and exhaust installation for ventilation of at least one room is provided, comprising: a chamber with a regenerative heat exchanger made in the form of a porous fiber filter; an external inlet pipe configured to let in ambient air through a regenerative heat exchanger into the internal pipe of the pressure duct and containing a valve device in its cavity; an internal branch pipe of a pressure air duct configured to inlet external atmospheric air into at least one room and comprising a valve device in its cavity; an internal pipe of the exhaust duct configured to discharge air from at least one room through a regenerative heat exchanger into an external exhaust pipe and containing a valve device in its cavity; an external exhaust pipe configured to discharge air from at least one room out into the atmosphere and containing a valve device in its cavity; at least one electric fan, providing a run of air for ventilation of at least one room, and adjacent to a regenerative heat exchanger and / or adjacent to at least one of said valve devices; wherein: the external exhaust pipe is connected to the internal pipe of the discharge duct, the external pipe inlet is connected to the internal pipe of the exhaust pipe, and said chamber with regenerative heat exchanger forms an intermediate pipe that connects the internal pipe of the pressure pipe and the external pipe to the internal pipe of the exhaust pipe and inlet pipe; the external outlet pipe and the external inlet pipe are adapted to be connected by means of external air ducts to the atmosphere of external air, the internal pipe of the pressure air duct and the internal pipe of the exhaust duct are made to be connected by means of internal air ducts to at least one room where said internal air ducts are located, at least in one room and contain inlet and outlet openings, or the aforementioned internal ducts are connected, m nshey least one location by means of said inlet and outlet openings provide ventilation, at least one space; while the design parameters that establish the balance of performance of the said inlet and outlet openings are limited by the balance of air exchange in at least one room, in which the volume of supply air is equal to or greater than the volume of air removed through the regenerative heat exchanger from at least one room; at the same time, the supply and exhaust installation additionally contains at least one relay and / or controller that provides or ensures the operation of the supply and exhaust installation in three phases: phase 1 - “inflow”, at which the valve devices of the external inlet pipe and internal the discharge duct pipe, and the valve devices of the external exhaust pipe and the internal pipe of the exhaust duct are closed, and said at least one electric fan is connected to run outside atmospheric air cut regenerative heat exchanger into the room; phase 2 - “outlet”, in which the valve devices of the external exhaust pipe and the internal pipe of the exhaust duct are open, and the valve devices of the external air pipe and the internal pipe of the discharge duct are closed, and said at least one electric fan is connected to run the internal air, at least one room through a regenerative heat exchanger into the atmosphere; and phase 3 - "recirculation", in which the valve devices of the internal pipe of the discharge duct and the internal pipe of the exhaust duct are open, and the valve devices of the external exhaust pipe and the external inlet pipe are closed, and said at least one electric fan is connected to run the internal air through regenerative heat exchanger in at least one room.

[0007] It is obvious that both the previous general description and the following detailed description are given by way of example and explanation only and are not limitations of the present invention.

Brief Description of the Drawings:

[0008] FIG. 1 shows the installation location in a one-room apartment.

[0009] FIG. 2 shows a longitudinal section through the housing.

[0010] FIG. 3 presents phase 1 “influx” in a two-room apartment.

[0011] FIG. 4 shows a diagram of the air circulation in the installation in the phase of "inflow".

[0012] FIG. 5 presents phase 2 “release” in a two-room apartment.

[0013] FIG. 6 shows a diagram of the air circulation in the installation in the "release" phase.

[0014] FIG. 7 presents phase 3 “recycling” in a two-room apartment.

[0015] FIG. 8 is a diagram of the air circulation in the installation in the "recirculation" phase.

[0016] FIG. 9 shows an embodiment with one fan and four valves.

[0017] FIG. 10, 11 show channel arrangement options.

[0018] FIG. 12 is a view A of FIG. eleven.

[0019] FIG. 13 shows a General view of the supply and exhaust system without placement in any building.

[0020] FIG. 14 shows a general view of the supply and exhaust system with placement in three buildings.

[0021] FIG. 15, 16, 17 are general views of the supply and exhaust installation with placement in two buildings in various versions.

The implementation of the invention:

[0022] Next, with reference to figures 1-12 will be described inlet and exhaust installation in a variant arrangement in a single housing. The supply and exhaust installation for ventilation of at least one room 1 contains pressure 2 and exhaust 3 air ducts made with intake 4 and exhaust 5 openings in communication with channels 7 made in the cavity of the housing 6.

[0023] In this case, the cavity of the housing 6 is connected with the premises of the apartment and with the atmosphere of the outside air through channels 7 for supply and exhaust air made in it in the form of internal nozzles 8 and 9 connected to the rooms and external nozzles 10 and 11 connected to the atmosphere external air, while all the nozzles are equipped with valve devices 12.

[0024] The installation includes electric fans 13 and a chamber 14 with a regenerative heat exchanger 15. Moreover, in one embodiment, the installation contains only one electric fan 13 (see Fig. 9), this option will be described below.

[0025] The surface of the housing 6 is covered or made of heat-insulating material (not shown in Fig.), And in non-residential premises 16 and 17 (Fig. 1) there are standard apartment exhaust openings 18 of the air intake shafts.

[0026] Said intake openings 4 of the exhaust duct 3 are located in at least one of the living rooms 19 (FIG. 1) or in the hallway, and the inlets 5 of the pressure duct 2 are located in each living room 19 (FIG. 1) and 20, 21 (Fig. 3, Fig. 5, Fig. 7).

[0027] The housing 6 of the supply and exhaust system can be installed in one of the non-residential premises, for example, in the kitchen 17 (Fig. 1) or on the loggia 22 (Fig. 3, Fig. 5, Fig. 7) or outdoors on the street (not shown in FIG.) or, for example, suspended on a wall of a building (not shown in FIG.).

[0028] Moreover, the design parameters that establish the balance of the performance of the inlet 4 and outlet 5 openings of the rooms of apartment 1 are limited by the balance of air exchange in apartment 1, in which the volume of supply air is equal to or greater than the sum of the volume of air removed from the living quarters 15 from the living quarters 19 and the volume air removed through the specified standard apartment exhaust openings 18 of the intake shafts from non-residential premises 16 and 17 of apartment 1.

[0029] These channels 7 are interconnected by an intermediate duct 23 containing the specified chamber 14 with a regenerative heat exchanger 15, made in the form of a porous fiber filter. Moreover, said chamber 14 forms an intermediate duct.

[0030] In each of the said inner 8 and 9 and outer 10 and 11 nozzles, said electric fan 13 is installed with an adjacent valve device 12 with the possibility of alternating flow through the regenerative heat exchanger 15 of the intermediate air duct 14 of the outside air and air removed from the apartment 1 in the modes three phases selected by the relay: phase 1 - "inflow" (Fig. 3, Fig. 4), in which the valve devices 12 of the external inlet pipe 11 and the internal pipe 9 of the pressure pipe 2 are open, and valve devices 12 of the outer exhaust pipe 10 and the inner pipe 8 of the exhaust duct 3 are closed, and the electric fans 13 adjacent to the open valve devices 12 are connected to run outside air through the regenerative heat exchanger 15 into the living quarters 19 (Fig. 1) and 20, 21 (Fig. 3 , Fig. 5, Fig. 7); phase 2 - “outlet” (Fig. 5 and Fig. 6), in which the valve devices 12 of the external exhaust pipe 10 and the internal pipe 8 of the exhaust duct 3 are open, and the valve devices 12 of the external inlet pipe 11 and the internal pipe 9 of the pressure duct 2 are closed moreover, the electric fans 13 adjacent to the open valve devices 12 are connected to run the room temperature indoor air through the regenerative heat exchanger 15 into the atmosphere and phase 3 is “recirculation” (Fig. 7 and Fig. 8), in which the valve devices are open Properties 12 of the internal pipe 9 of the pressure duct 2 and the internal pipe 8 of the exhaust duct 3, and the valve devices 12 of the external exhaust pipe 10 and the external inlet pipe 11 are closed, and adjacent to the open valve devices 12, the electric fans 13 are connected to run the internal air through a regenerative heat exchanger 15 in living quarters 19 (Fig. 1) and 20, 21 (Fig. 3, Fig. 5, Fig. 7).

[0031] The external nozzles 10 and 11 may be provided with external ducts 24. Valve devices 12 may be located in front of or behind the electric fans 13.

[0032] The installation may be equipped with an air heater — a heater (not shown in FIG.). It is also possible device, for example, with one electric fan 13 (Fig. 9) in the intermediate duct 23 adjacent to the regenerative heat exchanger 15, while valve devices 12 in each of the four pipes 8, 9, 10, 11 can be made (or have ) with electromagnetic (s) drive (s) (not shown in FIG.). These channels 7 can be L-shaped (Fig. 11). The intermediate duct 23 may have a C-shape in communication with the channels 7 through the holes. The specified time relay for the phases of "inflow", "release" can be performed in the form of a pressure sensor, and for the phase of "recirculation" in the form of a time interval adjuster.

[0033] The specified time relay for the "inflow" phase can be made in the form of a pressure sensor, for the "release" phase in the form of a temperature sensor located in the external outlet pipe 10, and for the "recirculation" phase can be performed as an interval adjuster time. The specified time interval relay can be made in the form of sensors of temperature, pressure, humidity, time interval setter.

[0034] The specified porous fiber filter 15 may be made of: copper metal fibers; aluminum metal fibers; stainless steel fibers; synthetic fibers; from a ceramic washable material with filtering properties for air or from a plastic washable material with filtering properties for air.

[0035] Next, with reference to the accompanying figures, an example of the operation of the supply and exhaust system in one housing will be given. The installation provides for alternating passage through the regenerative heat exchanger 15 of the intermediate duct 23 of atmospheric external air and air removed from the apartment 1 in the three-phase modes selected by the relay: phase 1 - “inflow” (Fig. 3, Fig. 4), at which the valve devices 12 the external inlet pipe 11 and the internal pipe 9 of the pressure pipe 2, and the valve devices 12 of the external exhaust pipe 10 and the internal pipe 8 of the exhaust duct 3 are closed, adjacent to the open valve devices 12, electric fans 13 are connected to run outside atmospheric air through a regenerative heat exchanger 15 into living quarters 19 (FIG. 1) and 20, 21 (FIG. 3, FIG. 5, FIG. 7); phase 2 - “outlet” (Fig. 5 and Fig. 6), in which the valve devices 12 of the external exhaust pipe 10 and the internal pipe 8 of the exhaust duct 3 are open, and the valve devices 12 of the external inlet pipe 11 and the internal pipe 9 of the pressure duct 2 are closed moreover, the electric fans 13 adjacent to the open valve devices 12 are connected to run the room temperature indoor air through the regenerative heat exchanger 15 into the atmosphere and phase 3 is “recirculation” (Fig. 7 and Fig. 8), in which the valve devices are open Properties 12 of the internal pipe 9 of the pressure duct 2 and the internal pipe 8 of the exhaust duct 3, and the valve devices 12 of the external exhaust pipe 10 and the external inlet pipe 11 are closed, and adjacent to the open valve devices 12, the electric fans 13 are connected to run the internal air through a regenerative heat exchanger 15 in living quarters 19 (Fig. 1) and 20, 21 (Fig. 3, Fig. 5, Fig. 7).

[0036] Next, with reference to figure 13 will be described a supply and exhaust installation for ventilation of at least one room without being placed in any building. In this embodiment, the supply and exhaust installation includes a chamber 101 with a regenerative heat exchanger 108, made in the form of a porous fiber filter, an external inlet pipe 102, an internal pipe of the discharge duct 103, an internal pipe of the exhaust pipe 104, an external exhaust pipe 105, valve devices 106, at least one electric fan 107, at least one relay and / or controller (not shown in FIG.). It should be noted that the positions 101-105 indicated in the figures are only conditional zones, and the mentioned pipes and chamber are a continuous structure, in the cavity of which there is a regenerative heat exchanger 108, valve devices 106, at least one electric fan 107. By a continuous structure is meant a design of one, as well as two or more parts, interconnected by prefabricated operations located in a functional-structural unity (assembly units), while prefabricated operations include in itself, including screwing, jointing, riveting, welding, soldering, crimping, flaring, gluing, stitching, etc. Additionally, at least one filter (not shown in FIG.) Can be arranged in said cavities, which provides additional filtration of the air passing through the installation, while said filter can be located as in front of at least one electric fan 107 and / or valve device 106 and / or regenerative heat recovery unit 108, and after. Also, at least one relay and / or controller (not shown in FIG.) Is located outside the said cavity.

[0037] The external inlet pipe 102 is adapted to let in ambient air through a regenerative heat exchanger 108 into the internal pipe of the pressure duct 103 and comprises a valve device 106 in its cavity. The internal pipe of the pressure pipe 103 is configured to let in at least external air. , in one room and also contains in its cavity a valve device 106.

[0038] The inner pipe of the exhaust duct 104 is configured to discharge air from at least one room through the regenerative heat exchanger 108 into the external exhaust pipe 105 and also includes a valve device 106 in its cavity. The external exhaust pipe 105 is configured to discharge air, at least from one room out to the atmosphere and also contains in its cavity a valve device 106.

[0039] The external outlet pipe 105 is connected to the internal pipe of the discharge duct 103, the external intake pipe 102 is connected to the internal pipe of the exhaust duct 104, and said chamber 101 with regenerative heat exchanger 108 forms an intermediate duct that connects the internal pipe of the pressure pipe 103 and the external discharge pipe 105 with an internal pipe of the exhaust duct 104 and an external inlet pipe 102.

[0040] Mentioned at least one electric fan 107, provides the passage of air for ventilation of at least one room, and is adjacent to the regenerative heat exchanger 108 and / or adjacent to at least one of the aforementioned valve devices 106. B in the case of the supply and exhaust installation, for example, with four electric fans 107 adjacent to the valve devices, these fans provide the opening or closing of a valve device 106 due to the passage of internal air and / or eshnego atmospheric air via said valve device 106. Thus, the valve device 106 may be located in front of blower motor 107 and after them. In the case of the supply and exhaust installation, for example, with one electric fan 107 adjacent to the regenerative heat exchanger 108, said fan only provides for the passage of internal air and / or external atmospheric air through the said valve devices 106, which, in turn, are made with electromagnetic drives ( not shown in Fig.), providing switching valve devices 106.

[0041] Additionally, the supply and exhaust system may include an air heater - air heater. Also, a chamber with regenerative heat exchanger can be additionally connected to the cooling and / or air heating system.

[0042] Mentioned regenerative heat exchanger 108, made in the form of a porous fiber filter, consisting of: copper fibers or aluminum fibers or stainless steel fibers or synthetic fibers or a ceramic washable material with filtering properties for air or a plastic washable material with filtering properties for air . Moreover, the mentioned materials are only an example, and are not a limitation of the execution of the said regenerative heat recovery unit 108 from any other materials.

[0043] The external outlet pipe 105 and the external inlet pipe 102 are configured to be connected by external ducts to the atmosphere of the outdoor air. The inner pipe of the discharge duct 103 and the inner pipe of the exhaust duct 104 are made with the possibility of connection by means of the internal ducts to at least one room. Mentioned internal ducts are located in at least one room and contain inlet and outlet openings for ventilation of at least one room. Also, said internal ducts may be connected to at least one room via inlet and outlet openings. The design parameters establishing a balance of the performance of said inlet and outlet openings are limited by the balance of air exchange in at least one room, in which the volume of supply air is equal to or greater than the volume of air removed through the regenerative heat exchanger 108 from at least one room.

[0044] Additionally, any of the above ducts, as well as an external inlet pipe and / or an external outlet pipe and / or an internal pipe for the discharge duct and / or an internal pipe for the exhaust duct and / or a chamber with a regenerative heat exchanger, may be coated with a heat insulating material or made of heat insulating material.

[0045] The switching of the valve devices 106 is controlled by at least one relay and / or controller (not shown in FIG.), Which provides or facilitates the operation of the supply and exhaust system in three phases: phase 1

- “inflow”, in which the valve devices 106 of the external inlet pipe 102 and the internal pipe of the discharge duct 103 are opened, and the valve devices of the external pipe 105 and the internal pipe of the exhaust duct 104 are closed, wherein said at least one electric fan 107 is connected to the run atmospheric outside air through a regenerative heat exchanger 108 into the room; phase 2 - “outlet”, in which the valve devices 106 of the external outlet pipe 105 and the internal pipe of the exhaust duct 104 are opened, and the valve devices 106 of the external inlet pipe 102 and the internal pipe of the discharge duct 103 are closed, wherein said at least one electric fan 107 included in the run of internal air of at least one room through a regenerative heat exchanger 108 into the atmosphere; and phase 3

- “recirculation”, in which the valve devices 106 of the inner pipe of the discharge duct 103 and the inner pipe of the exhaust duct 104 are opened, and the valve devices of the external exhaust pipe 105 and the external inlet pipe 102 are closed, wherein said at least one electric fan 107 is connected to the run internal air through a regenerative heat exchanger 108 in at least one room.

[0046] Additionally, the at least one relay (not shown in FIG.) Provides switching between the “discharge”, “inflow”, and “recirculation” phases by means of signals or commands from at least one time interval master (not shown in FIG.) and / or at least one pressure sensor (not shown in FIG.) and / or at least one temperature sensor (not shown in FIG.) and / or at least , one humidity sensor (not shown in Fig.) and / or at least one sensor evaluating the level of pollution ulcers and composition of ambient air (not shown in FIG.) and / or at least one air velocity sensor (not shown in FIG.).

[0047] Additionally, the at least one controller receives signals or commands from at least one time interval adjuster and / or at least one pressure sensor and / or at least one temperature sensor and / or at least one humidity sensor and / or at least one sensor evaluating the level of pollution and the composition of the ambient air and / or at least one air speed sensor, processes them, and provides switching between phases “Issue”, “inflow” and recycling. "

[0048] As additional embodiments of the present invention, hereinafter, with reference to figures 14-17 will be described various options for placement in several cases of the mentioned conditional zones 101-105. As a first additional embodiment (see FIG. 14), said outer outlet pipe 105 interconnected and said pressure duct inner pipe 103 are arranged in a first housing 109, said outer intake pipe 102 interconnected and said exhaust pipe inner pipe 104 located in the third housing 111, and the aforementioned chamber 101 with regenerative heat exchanger 108 are located in the second housing 110, and form an intermediate duct connecting the first housing 109 and the third building 111.

[0049] As a second further option (see FIG. 15), said chamber 101 with regenerative heat exchanger 108 are located in the first housing 109 and form an intermediate duct connecting the external outlet pipe 105 and the inner pipe of the discharge duct 103 with the external inlet pipe 102 and the inner pipe of the exhaust duct 104, where the external exhaust pipe, the internal pipe of the discharge duct, the external inlet pipe and the internal pipe of the exhaust pipe are located in the second housing 110.

[0050] As a third additional embodiment (see FIG. 16), said external outlet pipe 105 interconnected, said internal pressure port duct 103, and a chamber 101 with regenerative heat exchanger 108 are located in the first housing 109, and said external interconnected the inlet pipe 102 and said inner pipe of the exhaust duct 104 are located in the second housing 110.

[0051] As a fourth further embodiment (see FIG. 17), said outer outlet pipe 105 interconnected, said pressure duct inner pipe 103 are located in a first housing 109, and a chamber 101 with regenerative heat exchanger 108 and said outer connected the inlet pipe 102 and said inner pipe of the exhaust duct 104 are located in the second housing 110.

[0052] In this case, all of the above shells of said conditional zones 101-105 may be coated with a heat-insulating material or made of heat-insulating material. The presence of several cases allows to decentralize the location of the system (installation) elements, which gives a layout advantage in conditions of limited space, and also creates the convenience of access to individual elements of the system (installation), for example, a regenerative heat exchanger placed in a separate case improves its availability for washing at the location , for example, indoors, separately from other elements of the system. The distance between the indicated separate system enclosures connected by air ducts can reach several meters, which makes it possible to arrange the installation in parts in the most convenient arrangement of separate enclosures, reducing the occupied space in comparison with a single enclosure, which gives a layout advantage especially in limited space conditions. The presence of several buildings, including a separate housing for a regenerative heat exchanger, simplifies the process of connecting a regenerative heat exchanger to a cooling system in the summer or an additional heating system in the winter.

[0053] An example of the operation of the supply and exhaust system will be given below. The installation provides for alternating passage through the chamber 101 with a regenerative heat recovery unit 108 of atmospheric external air and air removed from at least one room in the three-phase modes described above. The forced-air and exhaust installation can be used to create a favorable microclimate in the premises of an apartment, especially in cities with a polluted atmosphere and temperature fluctuations.

[0054] The advantages of the invention from the point of view of practicality in real use - the simplicity of the design allows easy cleaning of all parts of the structure, especially the ease of removal and the ability to repeatedly wash the regenerative heat exchanger, which is very important for applications in cities with severe air pollution. The device according to the invention is most balanced for the return of moisture, which occurs without freezing the heat exchanger in almost any frost, unlike other systems, even if they allow the moisture to return back to the room. Moreover, the device is most balanced not only in the return of moisture, but also in the return of heat, especially when working in conjunction with additional hoods or standard apartment exhaust shafts. Heat saving occurs due to the balance in the conditions of air emission through additional exhaust hoods or standard apartment exhaust shafts, when more air is supplied through the air unit than is discharged through it due to the presence of additional hoods or standard air intake openings of exhaust shafts, for example, in the kitchen and in bathrooms.

[0055] The operation of the device in the winter is characterized by the fact that during the first phase of the "influx" due to the street cold air, the regenerative heat exchanger is cooled, as well as the inner walls of the inner pipe of the pressure duct. During the second “release” phase, the warm air of at least one room comes in contact with the cold fibers of the regenerative heat exchanger, begins to cool, while giving away moisture and leaving it on the fibers of the regenerative heat exchanger, this completes the second phase (so that the moisture is not thrown out) and the third phase begins - “recycling".

[0056] During the third phase, the regenerative heat exchanger is finally heated by the air passing through it from at least one room to room temperature, at the same time, droplets of moisture condensed on it during the previous “discharge” phase are mixed with the air stream, at least from one room, thereby moistening the flow of the mentioned air, at the same time, the regenerative heat exchanger and the internal pipe of the pressure duct are heated by air from at least one th room. At the beginning of the heating of the internal pipe of the discharge duct (when the pipe is still cold), condensation forms on its internal walls, but as the air moves from at least one room, the internal walls of the pipe, as well as in the case of a regenerative heat exchanger, warm up , all condensed moisture is mixed with air from at least one room, and the entire system is drained from the inside by a stream of said air. Thus, moisture is returned to at least one room and the entire system warms up to almost room temperature.

[0057] Next comes the first phase of the "influx" and the cycle repeats. During the “inflow” phase, cold street air comes into contact with a regenerative heat exchanger heated to room temperature and with the heated inner walls of the internal pipe of the pressure duct. Due to the heat of the regenerative heat exchanger, cold street air warms up and enters at least one room, thereby cooling the regenerative heat exchanger and, as the regenerative heat exchanger cools, gradually cools the inner walls of the internal pipe of the pressure head duct. Since moisture is not released during heating of the air, the “influx” phase occurs without the release of moisture. Next comes phase 2 “release”, and the cycle repeats.

[0058] Thus, the device minimizes the release of moisture in the winter to the street, thereby simplifying the task of humidifying dry air in the rooms (s) in the winter. The return of humidity affects the creation of a microclimate that is comfortable for a person, since humidity comfortable for a person in winter should be at the level of 30% -40%. In winter, the air in the room is dry, the situation is aggravated by the influx of street air, the relative humidity of which drops significantly when heated to room temperature, which in winter leads to a drop in relative humidity in the room. Dry air in a room (or apartment) has an adverse effect on human health. Therefore, the task of preventing the release of moisture from the room in the winter and humidifying the air entering the room is relevant for such devices.

[0059] Furthermore, during recirculation, indoor air is cleaned of dust, since the installation provides an additional effect in the form of an air purifier function.

[0060] Using the device additionally makes it possible to reduce energy consumption due to the balance of the supply and exhaust air, to reduce the degree of dehumidification of the air of at least one room, and to simplify the manufacturing technology.

[0061] The examples disclosed in this application should be considered as given for illustrative purposes only, with the essence and scope of the invention disclosed in the attached claims.

Claims (30)

1. The supply and exhaust installation for ventilation of at least one room, containing: - a chamber with a regenerative heat exchanger made in the form of a porous fiber filter; - an external inlet pipe made with the possibility of inlet of atmospheric external air through a regenerative heat exchanger into the internal pipe of the pressure duct and containing a valve device in its cavity; - the inner pipe of the pressure duct, made with the possibility of intake of external atmospheric air in at least one room and containing a valve device in its cavity; - an internal pipe of the exhaust duct configured to discharge air from at least one room through a regenerative heat exchanger into an external exhaust pipe and containing a valve device in its cavity; - an external exhaust pipe, configured to discharge air from at least one room out into the atmosphere and containing a valve device in its cavity; - at least one electric fan, providing a run of air for ventilation of at least one room and adjacent to a regenerative heat exchanger and / or adjacent to at least one of said valve devices; wherein - the external exhaust pipe is connected to the internal pipe of the discharge duct, the external pipe inlet is connected to the internal pipe of the exhaust pipe, and said chamber with a regenerative heat exchanger forms an intermediate pipe that connects the internal pipe of the pressure pipe and the external pipe to the internal pipe of the exhaust pipe and the external inlet ; - the external outlet pipe and the external inlet pipe are arranged to be connected by means of external air ducts to the atmosphere of external air, the internal pipe of the pressure air duct and the internal pipe of the exhaust duct are made to be connected by means of the internal air ducts to at least one room where said internal air ducts are located at least at least in one room and contain inlet and outlet openings, or the mentioned internal air ducts are interchanged with at least one room through said inlet and outlet openings providing ventilation of at least one room; wherein - design parameters establishing a balance of performance of said inlet and outlet openings are limited by the balance of air exchange in at least one room, in which the volume of supply air is equal to or greater than the volume of air removed through the regenerative heat exchanger from at least one room; wherein - the supply and exhaust installation further comprises at least one relay and / or controller, which provides or ensures the operation of the supply and exhaust installation in three phases: - phase 1 - “inflow”, in which the valve devices of the external inlet pipe and the internal pipe of the discharge duct are open, and the valve devices of the external pipe and the internal pipe of the exhaust duct are closed, and the at least one electric fan is connected to run the outside air through the regenerative heat exchanger in the room; - phase 2 - "outlet", in which the valve devices of the external outlet pipe and the internal pipe of the exhaust duct are open, and the valve devices of the external inlet pipe and the internal pipe of the pressure duct are closed, and said at least one electric fan is connected to run at least the internal air one room through a regenerative heat exchanger into the atmosphere; and - phase 3 - “recirculation”, in which the valve devices of the internal pipe of the pressure head duct and the internal pipe of the exhaust duct are opened, and the valve devices of the external outlet pipe and the external inlet pipe are closed, and the at least one electric fan is connected to run the internal air through the regenerative heat exchanger in at least one room. 2. Installation according to claim 1, characterized in that the said at least one relay provides switching between the phases “outlet”, “inflow” and “recirculation” by means of signals or commands from at least one time interval adjuster, and / or at least one pressure sensor, and / or at least one temperature sensor, and / or at least one humidity sensor, and / or at least one sensor, evaluating the level of pollution and the composition of the ambient air, and / or at least at least one speed sensor air. 3. Installation according to claim 1, characterized in that said at least one controller receives signals or commands from at least one time interval adjuster and / or at least one pressure sensor and / or at least one a temperature sensor, and / or at least one humidity sensor, and / or at least one sensor evaluating the level of contamination and the composition of the surrounding air, and / or at least one air speed sensor, processes them and switches between phases ck "," inflow "and" recycling ". 4. Installation according to claim 1, characterized in that said porous fiber filter is made of copper fibers, or aluminum fibers, or stainless steel fibers, or synthetic fibers, or a ceramic washable material with filtering properties for air, or a plastic washable material with filtering properties for air. 5. Installation according to claim 1, characterized in that the external inlet pipe and / or the internal pipe of the exhaust duct and / or the internal pipe of the pressure duct and / or the chamber with regenerative heat exchanger contain or contain inside their cavities or inside their cavity at least one filter that filters the air passing through or through it, said filter can be arranged in front of at least one electric fan and / or valve device and / or regenerative heat tilizatorom, and after. 6. Installation according to claim 1, characterized in that the said interconnected external outlet pipe and the internal pipe of the discharge duct, interconnected external inlet pipe and the internal pipe of the exhaust duct, and a chamber with regenerative heat exchanger are located in a single housing. 7. Installation according to claim 1, characterized in that the interconnected said external exhaust pipe and said internal pipe of the pressure duct are located in the first body, the interconnected said external inlet pipe and said internal pipe of the exhaust duct are located in the third body, and said a chamber with a regenerative heat exchanger is located in the second housing and forms an intermediate duct connecting the first housing and the third housing. 8. Installation according to claim 1, characterized in that said chamber with a regenerative heat exchanger is located in the first casing and forms an intermediate duct connecting the external outlet pipe and the internal pipe of the discharge duct with the external inlet pipe and the internal pipe of the exhaust duct, where the external exhaust pipe , the internal pipe of the discharge duct, the external inlet pipe and the internal pipe of the exhaust duct are located in the second housing. 9. Installation according to claim 1, characterized in that the interconnected said external exhaust pipe, said internal pipe of the discharge duct and the chamber with the regenerative heat exchanger are located in the first housing, and the interconnected said external inlet pipe and the said internal pipe of the exhaust duct in the second building. 10. Installation according to claim 1, characterized in that the interconnected said external exhaust pipe, said internal pipe of the discharge duct are located in the first housing, and the chamber with regenerative heat exchanger and the interconnected said external inlet pipe and said internal pipe of the exhaust duct in the second building. 11. Installation according to claim 1, characterized in that the external inlet pipe, the external exhaust pipe, the internal pipe of the discharge duct and the internal pipe of the exhaust duct contain one electric fan adjacent to each valve device located in each of the pipes. 12. Installation according to claim 11, characterized in that the valve devices can be located both in front of and after the electric fans. 13. Installation according to claim 1, characterized in that the valve devices have an electromagnetic drive. 14. Installation according to claim 1, further comprising an air heater - air heater. 15. Installation according to claim 1, characterized in that the external inlet pipe and / or external outlet pipe and / or internal pipe of the pressure duct and / or the internal pipe of the exhaust duct and / or the chamber with the regenerative heat exchanger are coated with heat-insulating material or made of heat insulating material. 16. Installation according to any one of paragraphs. 6-10, characterized in that the single housing, or the first housing, and / or the second housing, and / or the third housing are coated with heat-insulating material or made of heat-insulating material. 17. Installation according to claim 1, characterized in that the chamber with a regenerative heat exchanger is additionally connected to a cooling and / or air heating system.

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