CZ2015912A3 - A system for recuperation ram-jet ventilation for living spaces - Google Patents

Abstract

The recovery air ventilation system is formed by an exchanger with a system of thin-walled tubes (1) housed in a venting duct (2), wherein the supply air is supplied to the pressurized ventilated space (7) by these thin-walled tubes (1). Vented air is evacuated from the vacuum space (8) through the remaining space of the vent (2) outside the thin-walled tubes (1). It is advantageous to use the space between the chimney body (9) and the chimney insert (11) as ventilation vent (2) and thus to use the regenerative ventilation system as an additional hot-air exchanger reducing heat losses through the chimney flue.

Description

Recuperative Ventilation System for Residential Areas of Technology

BACKGROUND OF THE INVENTION The present invention relates to regenerative surge ventilation for energy-efficient ventilation of living spaces with a minimum of structural modifications to the existing structure, the function of which is completely independent of the need to connect a ventilated building to electrical or other power distribution.

BACKGROUND OF THE INVENTION In view of the cost-of-use of the prior art ventilation ventilation systems, this household equipment is considered an exclusive issue where only application excellence is observed and acquisition costs are seen as a secondary issue. Under these conditions, the regenerative ventilation systems developed so far are oriented to ventilator-ventilated equipment and to the use of a unified heat recovery exchanger. Since, in principle, every ventilation is to some extent recuperative, the most recently proposed solutions are surge ventilation systems that try to mimic the ventilation systems known from nature, such as ATTA solutions or other simple ventilation systems for passive temperature control in residential buildings. However, the purpose of these ventilation systems is to reduce temperature fluctuations in ventilated objects in an attempt to utilize as much as possible the natural regulating mechanisms of closing the ventilation ducts depending on the temperature and thermal inertia of the solid environment through which vents are conducted or the use of this environment as a natural solar article and the like. Since the purpose of these systems is to maintain the required temperature in the ventilated space, their more versatile application requires connection to an energy source, and the effort to recover heat between the supply air and the exhaust air through the exchanger is economically unjustified according to known solutions. Therefore, these systems cannot be considered as recuperative, but rather as systems capable of supplementing regenerative ventilation with additional air conditioning functions without the need for additional active energy elements. * From the main application point of the solution of the present invention, to develop a "ventilation system with minimal purchase costs, designed mainly for irregularly and only occasionally used residential buildings that are not permanently connected to the electricity distribution system, or a ventilated object from These systems are unsuitable for the time of absence, since they require unreasonably high acquisition costs or have too little advantageous utilization.These systems operate with unnecessarily short temperature control constants and do not use sufficient passive natural ventilation mechanisms to maintain air humidity in the ventilated area below the dew point corresponding to the real lowest temperature of the coldest, the inside of the ventilated object while minimizing the external demand Isun tejefíé energy, respectively. A maximum regenerative system efficiency.

SUMMARY OF THE INVENTION

The drawbacks and drawbacks of the prior art solutions of ventilation systems are significantly reduced by a system for regenerative surge ventilation with a vertically mounted upstream recuperative exchanger according to the present invention. Its essence is that the system is located in the ventilation duct of the existing chimney body, which is formed either by the entire interior of the chimney body or, in the case of a built-in chimney flue liner, by the space between the outer shell of this chimney insert and the inner chimney shell. The chimney body is equipped with a chimney extension on its upper part. A system of parallel thin-walled tubes is introduced into the ventilation duct of the chimney body. Their inner space is formed by a system of ventilation ducts with outside air, and the outer space between the ducts forms exhaust vents. The tubes are in the axial position airtightly fixed by a thixapsulating guide in the openings of the upper and lower baffles. The upper partition is fixed to a fixed part of the chimney extension, where it is also fixed at the same height level (broken separating partition) dividing the rotatably mounted chamber into the ram and suction spaces. This partition is attached to the bottom of the chimney at its lower edge. Its upper edge is attached to the opposite ceiling part of the chimney extension in order to divide the space in the chimney extension into the windward thrust chamber into which the tubes exit, and to the leeward suction chamber into which the exhaust vents open. The lower ends of the tube are fixed in the lower partition, which divides the ventilation duct into the lower space with the inlet formed in the chimney body and into the pressurized ventilated space, and into the space between the lower partition and the upper partition, into the lower part of which the exhaust air exhaust outlet opens. from a vacuum ventilated space to the exhaust vents formed in the chimney vent vent.

It is advantageous if the entrance to the windward ram chamber and the outlet of the leeward suction chamber of the chimney extension are overhanging and are provided with a system of overhanging vertically oriented and parallel screens. In one possible embodiment, the chimney fitting may be rotatably mounted at the chimney body where the ventilation duct fills the entire chimney body. Then, the wind chute chamber and the winding suction chamber are contained within the chimney extension rotary system, i.e., in other words, are formed in the rotary system and are thus part of it. This swivel chimney swivel system consists of a ceiling, a bottom, a windbreak chamber and a leeward suction chamber and side vertical walls. These vertical walls on the outlet side of the leeward suction chamber pass into the ailerons to maintain entry into the ram chamber in the upwind direction. The rotatable mounting of the chimney extension swivel system is formed by supporting its ceiling with the tip of a mandrel fixed in the axis of the upper partition and the lower partition.

An alternative to the aforementioned chimney body with a chimney insert, when the chimney extension is rotatably mounted, is another way of rotatably mounting the chimney extension rotary system. Here, the swivel bearing is secured by an axially mounted chimney liner extending above the swivel chimney extension. Here, the chimney liner is terminated by a support tip support that supports a chimney liner over the fitting seat at the top of the roof above the flue gas outlet. The swivel extension system is suspended on the roof by a suspension structure. To limit the horizontal fluctuations of the chimney extension rotary system, this system is provided with a bearing bearing on the annular opening of the upper partition for coaxial passage of the chimney insert. Even in both alternatives with a rotatably mounted chimney extension, it is advantageous if the entry into the windward ram chamber is overhanging and is provided with a system of overhanging vertically oriented and parallel screens.

To increase efficiency, an auxiliary fan may be provided at the outlet of the vent to a ventilated ventilated space that is connected to the photovoltaic cell directed towards the sun's afternoon position.

The main advantage of the solution according to the invention is that it allows easy installation into existing chimney and ventilation vents of older buildings, which most often suffer from their lack of regular ventilation. The system makes it very easy and convenient to collaborate with other interior treatment systems to significantly improve their efficiency. These include, for example, the use of a heat exchanger exchanger as an additional heat exchanger to reduce the loss of heat dissipation through the flue gas chimney from the heaters or to use a recuperative ventilation system as a source of pressure difference for underfloor heating and the like.

BRIEF DESCRIPTION OF THE DRAWINGS The exemplary basic embodiment of the inventive regenerative surge ventilation system is shown in dbrT # 1. 2 is a view of an open rigid chimney flue attachment intended to utilize the space between the chimney body and the chimney liner to install a recuperative exchanger exchanger exchanger. At 0br. 3 is a schematic illustration of a swivel head chimney fitting for automatically directing the entry into the surge ventilation ram chamber against the instantaneous wind direction. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The exemplary embodiments illustrated in OERT1, 2 and 3 are variations of solutions utilizing the existing ventilation duct 2 and chimney bodies 9 of older buildings for the installation of a ram recovery ventilation system according to the invention. Basic variant shown on C) br. 1 consists of introducing a thin-walled tube assembly 1 into an existing ventilation duct 2 in a chimney body 9. The venting duct 2 is formed either by the entire interior of the chimney body 9,. or, in the case of a flue liner 11, installed between the outer shell of the chimney liner U and the chimney shell 9. The chimney 9 is provided with a chimney flange 14 at its upper part. the partition 12 and the lower partition 13. The upper partition 12 closes the chimney extension 14 formed by the upper portion of the tubular chimney liner 11 and separates the windward chambers 3 from the ventilation duct 2. The thin-walled tubes 1 divide the ventilation duct 2 into supply ducts within the thin-walled tubes 1 and to the outer space used as suction vents 10. This ventilation vent section 2 closes from below the lower baffle 13. From the ventilation vent 2 below the lower baffle 13, the ventilation air is fed through the inlet 5 into the positive pressure vent 7. Entry him the space 5 can advantageously be preceded by an auxiliary fan 23 is preferably connected directly to a photovoltaic cell 24 directed to the southwest or so at a time when the outside air was hottest auxiliary ventilation fan 23 most strengthened.

It is advantageous if the ventilated air 7 is transferred from the pressurized ventilated space 7 into the vacuum space 8 through the cavities between the ventilated floor 21 and the base joint 22 and then through the suction outlet 6 into the lower part of the vent 2 defined by the upper partition 12 and the lower partition 13. In the upper part part of this section, the air from the exhaust ducts 10 is discharged through the leeward suction chamber 4 to the leeward side of the chimney head 14 ventilation system. The wind chill chamber 3 and the air intake chamber 4 are the contents of the chimney head 14 rotary system formed by the ceiling 17, bottom 26, separating the partition 25 of the windward thrust chamber 3 and the leeward duct 14 by vertical walls 18, which on the side of the lumen of the lumen suction chamber 4 pass into the ailerons providing the chimney extension system pivot system 14 with the function of a tap maintaining entry into the windward thrust chamber 3 in the wind direction. The rotatable mounting of the rotary system of the chimney extension 14 is ensured by supporting its ceiling 17 with the tip 16 of the mandrel 20 fixed in the axis of the upper partition 12 and the lower partition 13. The seat of the spike attachment is part of the ceiling 17 of the chimney extension rotary system 14. for the passage of the chimney insert H through the separating partition 25 and the chimney extension 14.

It is advisable to provide an entrance to the windward ram chamber 3 or leeward suction chamber 4 with a system of overhanging, vertically oriented racks 19 to prevent clogging of the windward ram chamber 3 and leeward suction chamber 4 sheets and the like, even in the event of a chimney hinge failure. extensions 14, where the air circulation polarity can be changed by the system and must be protected from clogging by leeward suction chamber 4 and exhaust vents 10.

The air supplied through the inlet 5 to the pressurized ventilated space 7 is suitable to be transferred to the vacuum chamber 8 to the suction inlet 6 by a system of vent openings in the partitions between the rooms of the ventilated object. A desired air-conditioning effect can be achieved if the airflow can also be run in series or in parallel. a cavity between the ventilated floor 21 and the floor in the base joint 22 under the waterproofing layer.

FIG. 2 is a view of the chimney fitting 14 for fixed attachment to the chimney head 9 by means of grips 27, which is intended for use as a vent 2 only between the flue liner and the walls of the chimney 9, the chimney 14 being shown in the state without closing the ceiling 17 with the lid. In this way, the view of the upper partition 12 with the axial hole for the chimney insert H is exposed, which in this case is intended for the exhaust of the local heater, so that the recovery exchanger exchanger also serves as an exchanger for increasing the efficiency of the local heater by the heat of the flue gas to be heated ventilation air. The top shape of the chimney extension 14 is rhomboidal, with its vertical walls 18 being parallel to each other and corresponding to the outer dimension of the chimney body 9. The edges of the ceiling 17 and the bottom 26 of the fixed chimney extension 14 define the inlet opening of the windward thrust chamber 3 and the outlet opening of the leeward suction chamber 4. and are perpendicular to the most likely wind direction. Thus, this variant is suitable for use in valley locations or generally where wind is directed to a particular direction by surrounding obstacles. The wind blast chamber 3 and the air intake chamber 4 are separated by a separating partition 25 on which the upper partition 12 of the heat exchanger is mounted.

FIG. 3 is a schematic representation of a chimney superstructure required for a variant of a forced recuperative ventilation built into a lined chimney for exhausting flue gas from a local heater and is provided with a rotary chimney extension 14. In this variant, the chimney liner 11 is provided with an axially mounted chimney insert. upwards above the rotary chimney extension 14 and is terminated here by a support 28 of the support tip 16, which supports the chimney insert U over the bearing seat at the top of the roof 15 above the flue gas outlet pivot system of the chimney extension 14. The rotary system of the chimney extension 14 is suspended on the roof 15 by means of a suspension structure 29. Even in this variant, the space between the chimney insert H and the chimney body 9 is used as a vent 2 for receiving the heat exchanger.

Industrial usability

The system for regenerative surge ventilation, as already indicated by the variants of the exemplary embodiment of the invention, can be used as an additional exchanger for local heaters. However, its main importance is its applicability for its advantageous applicability in reconstructions of older residential building structures, especially for buildings permanently uninhabited, such as an unmanned ventilation system maintaining the temperature of internal walls higher than the dew point of air supplied to the interior of the building by ventilation.

Claims (5)

PATENT CLAIMS 1. A system for regenerative surge ventilation for living spaces with a vertically mounted upstream recuperative heat exchanger / characterized in that it is located in a ventilation duct (2) of an existing chimney body (9) which is formed either by the entire interior of the chimney body (9) or in the case of a built-in chimney flue liner (11), the space between the outer casing of the chimney liner (11) and the inner casing of the chimney body (9), where the chimney body (9) is provided with a chimney fitting (14) on its upper part and into the ventilation flue ( 2) a stack of parallel thin-walled tubes (1) is introduced into the chimney body (9), the inner space of which forms a system of ventilation ducts for the outside air and the outer space between the tubes (1) forms the exhaust ducts (10), where the tubes (1) are in the axial position airtight fixed by sliding guide in openings of upper switch the lower partition (13), wherein the upper partition (12) is fixed to a fixed portion of the chimney extension (14), wherein at the same height level also the angled partition (25) is fixed, dividing the rotatably mounted chamber (14) on the thrust space (3) and the suction space (4), the separating partition (25) is connected at its lower edge to the bottom (26) of the chimney extension (14) and its upper edge is attached to the opposite ceiling section of the chimney extension (14) in order to divide the space in the chimney extension (14) into the windward ram chamber (3) into which the tubes (1) and the winding suction chamber (4) into which the exhaust vents (10) open, and the lower ends of the tubes ( 1) are fixed at their lower ends in a lower partition (13), which divides the ventilation duct (2) into a lower space with an inlet (5) formed in the chimney body (9) and into the overpressure in the venting space (7) and the space between the lower partition (13) and the upper partition (12), into the lower part of which the exhaust air outlet (6) from the ventilated vacuum space (8) is vented to the exhaust vents (10) formed in the ventilation duct (2) of the chimney body (9). System according to claim 1, characterized in that the inlet into the windward ram chamber (3) and the outlet of the leeward suction chamber (4) of the chimney extension (14) are overhanging and have a set of overhanging vertically oriented and parallel trays (19) . A system according to claim 1, characterized in that the chimney extension (3) is rotatably mounted in the chimney body (9), where the ventilation duct (2) fills the entire space of the chimney body (9), and the wind chute chamber (3) and the air intake chamber. (4) comprise a rotary system of a chimney extension (14) formed by a ceiling (17), a bottom (26), a separating partition (25) of a windward ram chamber (3) and a winding suction chamber (4) and vertical walls (18) which on the side of the mouth of the winding suction chamber (4) pass into the wings (30) to maintain entry into the ram chamber (3) in an upward wind direction, wherein the rotatable mounting of the chimney extension rotary system (14) is formed by supporting its ceiling (17) with a point (16) dark (20) fixed in the axis of the upper partition (12) and the lower partition (13) The system according to claim 1, characterized in that the chimney fitting (9) is rotatably mounted in the chimney body (9) with the chimney liner (11), and the wind chute chamber (3) and the air intake chamber (4) are contained in the chimney fitting rotary system. (14) consisting of a ceiling (17), a bottom (26), a separating partition (25) of a windward thrust chamber (3) and a winding suction chamber (4) and vertical walls (18) which pass on the outlet side of the winding suction chamber (4) into the ailerons to maintain entry into the ram chamber (3) in the upwind direction, wherein the rotatable mounting of the rotary chimney extension system (14) is provided by an axially positioned chimney liner (11) extending above the rotatable chimney extension (14) where it is terminated by a carrier ( 28) a support tip (16) that supports a chimney liner (11) over the fitting seat at the top of the roof (15) and a chimney fitting system (11) over the flue gas outlet. the yoke (14) is suspended on the roof (15) by means of a suspension structure (29), the system being provided with a bearing bearing on the annular opening of the upper partition (12) for coaxial passage of the flue liner ( 11). System according to any one of claims 1 to 4, characterized in that an auxiliary fan (23), which is connected to the photovoltaic cell (24), is provided in the outlet (5) from the vent (2) to the ventilated ventilated space (7). ) facing towards the afternoon afternoon sun.