RU2509847C2 - Ventilation system of pitched roof - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: ventilation system of a pitched roof comprises an inclined ventilation channel arranged under the roof. Inlet and outlet holes of the channel are ventilation windows and slot untightnesses between the roof and the walls of the building, and the lower wall of the channel is a hydraulic heat insulating screen, placed in parallel to slopes of the roof and made of two layers of the hydraulic insulating material, for instance, from reinforced polyethylene film, between which an air layer is formed. In both layers of the film there are holes for passage of heat insulating ventilation channels of the building, taken through an attic room and the roof into environment. In places where exits are located from the attic to the roof in the hydraulic insulating screen there are hatches made in the form of frames, where removable covers are installed. Edges of films that adjoin the floor of the attic room are lowered into the trays installed on the floor.

EFFECT: prevention of ice formation on a roof and roof eaves.

6 dwg

Description

The invention relates to the field of construction, in particular, to the construction of a pitched roof ventilation system in which the roofing material is located above the rafters or trusses on which the lathing and the roof are supported. The proposed system can be used in the construction of buildings with pitched roofs, as well as in the repair of previously built similar buildings, in which the furnace heating was replaced by central heating with the upper wiring of the heating system.

Known ventilation system of a pitched roof (Japanese application No. 63-578, publ. 88.01.07 No. 475), containing attic vertical exhaust channels, the inlet openings of which are located under the roof ridge and connected to the atmosphere, and the inlet openings are connected to the attic volume, and inclined pitched channels formed by roofing and subroofing material and a counter-lattice, the inlet openings of which are located in the eaves overhangs, and the inlet openings of the attic volume are located under the overhangs.

The disadvantage of such a pitched roof ventilation system is the low ventilation efficiency when the weather changes, which leads to a large temperature difference between the atmospheric air and the air in the attic and, as a result, to condensation on the inner surface of the roof and the formation of the outer surface of the icing and icicles on eaves overhangs. For buildings of an old construction, where there is no counter-lattice, such a design ventilation system is unsuitable.

A known ventilation system for a pitched roof (RF patent No. 2250970, publ. 04/27/2005) is the closest analogue containing attic vertical exhaust channels, the outlet openings of which are connected to the atmosphere and located under the roof ridge, and the inlet openings are connected to the attic, and inclined pitched channels formed by roofing and subroofing material and counter-lattice, the inlet openings of which are located in the eaves overhangs, and the inlet openings of the attic are located under the overhangs, while the ventilation system is equipped with it is provided with additional vertical channels attached externally to the attic exhaust ducts, the inlet openings of which are connected to the exits of the inclined ramp channels, the width of the additional vertical exhaust duct is equal to the width of the inclined ramp channel and equal to the height of the counter-grill, the outlet openings of the additional exhaust ducts are located below the level of the outlet openings of the attic exhaust ducts equal to the width of the inclined ramp channel, and the supply holes of the inclined ramp channels are located in the horns of eaves overhangs, the supply air openings of the attic are located in the lower plane of the eaves overhang.

The disadvantages of such a system are:

- such a pitched roof ventilation system is applicable only in the presence of attic exhaust channels, the outlet openings of which are located under the roof ridge, and the inlet openings are connected to the attic volume;

- to ensure the required cross-sectional dimensions of the inclined ramp channel, a counter-lattice is needed, which determines the height of this channel and the width of the vertical additional exhaust channel, the need to use a counter-lattice leads to additional costs of materials and money;

- the under-roof material fixed above the rafters and forming the lower wall of the inclined ramp channel does not heat-insulate this channel from the attic air, the temperature of which is determined not only by the temperature of the outside air, but also by heat from the building’s exhaust air ducts passing through the attic and from the building’s heat supply (heating) elements located in the attic. This can lead to an increase in temperature passing through the sloping air duct and an increase in the temperature of the roof.

Thus, this pitched roof ventilation system does not always solve the problem of combating the formation of ice and icicles. In addition, a large temperature difference between the attic volume and the outside air can cause condensation to form on the inner surface of the under-roof material. In case of accidental damage to the roof, moisture leaks occur, which will drain along the inclined channel to the filing of the eaves overhang, which can significantly reduce its service life. Such a design of the ventilation system is not suitable for old buildings that do not have a counter-lattice, and its creation in these buildings requires a preliminary analysis of the roof.

The drawbacks of this pitched roof ventilation system do not allow it to be used to combat the formation of icing and icicles in old buildings, especially in cities located in the middle and northern latitudes of Russia.

The aim of the invention is the creation of a ventilation system of a pitched roof, which can provide:

- effective ventilation of the pitched roof of urban buildings of the old construction, which in the cold season will provide cooling of the roof to a temperature not exceeding the temperature of atmospheric air by more than 1 ÷ 2 ° C, which avoids melting snow on the roof and the formation of ice and icicles on the roof overhangs;

- in this case, it is necessary to provide thermal insulation of the inclined ventilation channel located under the pitched roof from heat in the attic space under this channel, as well as to provide protection against possible condensation falling out of the air of the attic space on the surface of the ventilation inclined channel in contact with the volume of the attic space and provide protection attic space from moisture penetrating through accidental damage to the roof.

At the same time, the ventilation system of a pitched roof should be technically simple for installation and not requiring significant money for its creation, and should also be maintainable - easily repairable and not requiring energy consumption during its operation.

This goal is achieved due to the fact that the ventilation system of the pitched roof, containing an inclined ventilation channel located under the roof serving as the upper wall of the channel, the ventilation windows and slotted openings between the roof and the walls of the building are used as inlet and outlet openings, and the lower wall of this channel is a heat-insulating screen placed parallel to the roof slopes and made of two layers of waterproofing material, for example, of reinforced poly ethylene film, between which a heat-insulating air layer is formed with a thickness of approximately 50 ÷ 100 mm, the upper layer of the polyethylene film is attached to the rafters from below or to the side surfaces of the upper belts of adjacent trusses with wooden slats, and the lower layer of the film is attached parallel to the upper layer to the rafters also from below through fragments of wooden blocks with sizes from about 50 × 50 × 50 to 100 × 100 × 100 mm attached to the rafter legs through the upper layer of the film or to the side surfaces of the upper belts of adjacent erm with wooden slats so that the distance between the layers of the film is 50-100 mm, holes are cut in both layers of films for the passage of the building's insulated ventilation ducts, brought out through the attic and roof to the outside atmosphere, the edges of the holes being attached to the outer surfaces of these channels with “Collars” also made of reinforced plastic film; at the locations of the exits from the attic to the roof in the heat-insulating screen, passages (hatches) are formed, made in the form of frames made in the form of door frames, in which removable covers are installed, held in the frames by means of rotary latches mounted on the frames, while the frames fixed between two parallel beams attached perpendicular to the rafter legs, or to the upper belts of adjacent trusses but both sides of the roof exit; the edges of the polyethylene films, in which the openings for the aisles are cut out, are attached to the frames with wooden battens, the removable manhole covers are made of wooden frames on which reinforced polyethylene films are fixed on both sides of the contours with the help of rails, the distance between which corresponds to the thickness of the heat-insulating screen (50 ÷ 100 mm), and the dimensions of the openings in the frames to which the manhole covers are installed correspond to the sizes of the covers, the ends of the covers are equipped with sealing gaskets. The edges of the films adjacent to the floor of the attic are lowered into trays installed on the floor made of galvanized sheet steel, laid on wooden supports, providing a slight slope of the trays towards the nearest sewer risers, the outlets of the trays are equipped with holes that are connected to the holes drilled in the risers by hoses, and places for connecting hoses to trays and risers are sealed.

Such a system for ventilation of a pitched roof using an inclined ventilation duct in communication with the outside atmosphere through ventilation windows in the roof and slotted leakages between the roof and walls provides cooling of the roof in the cold season to a temperature not exceeding the temperature of atmospheric air by more than 1 ÷ 2 ° C, which avoids the formation of icing and icicles on the roof overhangs, and also provides thermal insulation of the inclined ventilation duct located under the roof of the pitched roof from heat generation in the attic thanks to the hydrothermal insulation screen mounted under the rafter legs (or between the side surfaces of the upper belts of adjacent trusses), which also protects the attic from cold air flowing through the inclined ventilation duct and from accidental leaks of the roof caused by damage to it, which damage to the roof on the top layer of the film, the moisture flows down but into the trays connected with the sewer risers. Such a ventilation system is technically not difficult to install and does not require expensive materials to create it. Such a ventilation system has a high degree of maintainability, as in case of damage to the plastic film, it is easy to replace its damaged part. The listed advantages of the proposed pitched roof ventilation system ensure its applicability to old buildings built until about the middle of the last century, especially to those buildings in which there was stove heating, which was subsequently replaced by central heating with the top layout of the heating system.

Analysis of analogues showed that the claimed technical solution is new. The novelty of the proposed solution lies in the use of a hydrothermal insulating screen for the formation of an inclined ventilation drop for a pitched roof, containing two layers of reinforced polyethylene film (waterproofing materials) in parallel, between which an air gap of 50-100 mm thick is formed, which is a good heat insulator. The hydrothermal insulating screen is mounted under the rafter legs or between the lateral surfaces of the upper truss belts, on which the crate and the roof rest. The screen serves as the bottom wall of the ventilation channel in communication with the atmosphere, outside air circulates through the channel, which in the cold season cools the roof, which serves as the upper wall of the channel. The hydrothermal insulating screen protects the ventilation channel from the heat of the attic, and also protects this room from the cold ventilation inclined channel. A polyethylene film protects the attic from moisture, which can penetrate through the accidental damage to the roof inside the attic, while leaking moisture flows down the upper layer of the film into the trays connected to the sewer risers.

Thus, the claimed technical solution is characterized by a new set of essential features that give a positive effect and has signs of compliance with the criterion of "inventive step".

Figure 1 and 2 shows the proposed ventilation system of the pitched roof for the most common version of fixing the battens and the roof on the rafters, figure 3 - a tray for collecting and removing water leaked through accidental damage to the roof, figure 4 - cutting holes in the film for the passage of ventilation ducts, in Fig.5 - fastening a reinforced plastic film to the side surfaces of the upper trusses, and in Fig.6 - the design of the passage in the heat-insulating screen for access to the roof.

The ventilation system is mounted on the rafter legs 1 located in the attic, on which the crate 2 is fixed with a roof attached to it 3. To the rafter legs 2, a layer of plastic film 4 is attached from the bottom using wooden rails 5, fragments are attached to the rafter legs 2 through this layer of film wooden bars 6 with dimensions of 50 × 50 × 50 or 100 × 100 × 100 mm, and the second (lower) layer of plastic film 7 rolls toward the latter. The plastic film is a waterproofing material. Between the layers of films 4 and 7 an air gap 8 is formed with a thickness of about 50 ÷ 100 mm (depending on the size of the bars 6), which is a good heat insulator. Thus, both layers of the film - the upper 4 and lower 7 together with the air gap 8 form a hydrothermal insulating screen 9, the screen 9 and the roof 3 form an inclined ventilation duct 10, in which the screen 9 serves as the lower wall of the channel, and the roof 3 - the upper wall. The ventilation duct 10 is in communication with the atmosphere through the ventilation windows 11 and slotted holes 12 between the roof 3 and the wall 13 of the building, which are available on the roof of the building. At the junctions of both layers of films 4 and 7 to the floor 17 of the attic, the ends 14 of the films are lowered into trays 15 (Figs. 1 and 3) made of galvanized sheet steel, laid on wooden supports 16 installed on the floor 17 of the attic. The ends of the trays 15 are closed by the walls 18. The supports 16 are installed on the floor 17 so as to create a slight slope for the trays 15 (approximately 1: 100) towards the nearest sewer riser 19 passing through the attic. Individual fragments of the trays 15 are interconnected “into the lock” 20, the connection points are sealed. In the end of the tray 15 closest to the riser 19 and in the riser 19, holes 21 and 22 are respectively drilled and connected by a hose 23. The hose connection points are sealed. Figures 1 and 2 also indicate the ventilation ducts 24 on the roof of the building, passing through the attic and led to the roof, as well as the exit 25 to the roof of the building. Figure 4 illustrates the technology of cutting holes in the film for the passage of ventilation ducts with the formation of "collars". In Fig. 5 are indicated: upper truss belts 26, wooden battens 27 for attaching polyethylene films to the side surfaces of the belts 26. In Fig. 6 (bottom view), a hatch structure is shown (for access to the roof exit): upper truss belts 26 attached to the upper truss belts (or to the rafters) of the beam 28, on which the frame 29 is made in the form of a door frame, rotary latches 30 are mounted on the rams 29 to hold in the frame 29 a cover 31 made in the form of a frame, the ends of which are equipped with sealing gaskets 32; wooden slats 33 are designed for fastening films along the contour of the frame on both sides of the lid 31 and the film of the insulating screen to the rams 29, the handles 34 mounted on the lid 31 are used for ease of installation and removal of the lid (the handles 34 are not included in the subject matter and are not presented in the claims )

The ventilation system of the pitched roof works as follows. Since the inclined ventilation duct 10 communicates with the atmosphere through the ventilation windows 11 available on the roof of the building, as well as through slotted leaks 12 between the roof 3 and the walls 13 of the building, air movement “drafts” occurs in channel 10, which cools during the cold season roof 3 to a temperature close to the temperature of atmospheric air (temperature difference does not exceed 1 ÷ 2 ° C). Therefore, thawing of snow on the roof 3 does not occur and ice does not form, but because if there is no thawing, then there is no moisture that can drain on the roof 3 and, when freezing, form icicles on the roof and on the overhangs of the roof of the building. The hydrothermal insulating screen 9, which is the bottom wall of the inclined ventilation duct 10, protects the air moving in this duct from the heat generated from the elements of the building’s technical systems - heating systems and ventilation systems, located in the attic, even if these elements have poor thermal insulation. At the same time, the heat-insulating screen protects the part of the attic space below it from the penetration of cold from the inclined ventilation duct, as a result, the temperature of the lower layer 7 of the polyethylene film cannot acquire the dew point temperature and condensation does not occur on it. Thus, the hydrothermal insulation screen protects the ventilation channel from heat from the attic, and the attic from cold from the inclined ventilation channel. In case of damage to the roof 3 but for some reason, a leakage of moisture forms (in appropriate weather), which falls on the top 4 layer of a polyethylene film having a slope along which moisture flows to the edges 14 of the film lowered into trays 15. Since the trays 15 have a slight slope (approximately 1: 100), set by coasters 16 installed on the floor 17 of the attic, then the moisture drains but the trays towards the sewer riser 19 and then through the hose 23 enters the riser 19 and is removed but into the sewer. Access to the roof exit is, if necessary, through an open hatch using a ladder (not included in the subject of the invention either in the formula, in the description and in FIGS. 1–6).

Thus, the proposed pitched roof ventilation system solves not only the task of combating the formation of ice on the roof of the building and icicles on the roof overhangs, but also in the event of emergencies (roof leaks) it prevents the penetration of moisture from the attic into the underlying floors of the building. So, the proposed pitched roof ventilation system solves all the goals:

- provides cooling of the roof in the cold season to a temperature not exceeding the temperature of atmospheric air by more than 1 ÷ 2 ° C;

- the heat-insulating screen protects the inclined ventilation duct from the heat generated by the elements of the building's technical systems located in the attic and prevents condensation from falling out both in the ventilation duct and on the underside of the screen facing the attic space;

- protects the attic (and the floors of the building located underneath) from moisture leaks through accidental damage to the roof;

- the proposed ventilation system is maintainable, it does not require expensive materials to create and repair it;

- the proposed ventilation system does not consume electricity during operation.

The proposed ventilation system is industrially applicable, because uses materials manufactured by industry for installation.

Claims (1)

A pitched roof ventilation system containing an inclined ventilation channel located under the roof serving as the upper wall of the channel, characterized in that the ventilation windows and slotted openings between the roof and the walls of the building are used as input and output openings of the channel, and the lower wall of the channel serves a hydrothermal insulating screen placed parallel to the roof slopes and made of two layers of waterproofing material, for example, of a reinforced plastic film, between which A heat-insulating air layer about 50–100 mm thick was called, the upper layer of the polyethylene film is attached to the rafters from below or to the lateral surfaces of the upper belts of adjacent trusses with wooden battens, and the lower layer of the film is attached parallel to the upper layer to the rafters also from below through fragments of wooden blocks with dimensions from about 50 × 50 × 50 to 100 × 100 × 100 mm through the upper layer of the film or to the side surfaces of the upper zones of adjacent trusses with wooden battens so that the distance between the layers of the film is varied from 50 to 100 mm, holes were cut in both layers of the film for the passage of the building's insulated ventilation ducts, brought out through the attic and the roof to the outside atmosphere, the edges of these holes being attached to the outer surfaces of the ducts using “collars” also made of reinforced plastic film ; at the locations of the exits from the attic to the roof in the heat-insulating screen, passages (hatches) are formed, made in the form of frames made in the form of door frames, in which removable covers are installed, held in the frames by means of rotary latches mounted on the frames, while the frames fixed between two parallel beams attached perpendicular to the rafter legs, or to the upper belts of adjacent trusses on both sides of the exit to the roof; the edges of the polyethylene films, in which the openings for the aisles are cut out, are attached to the frames with wooden battens, the removable manhole covers are made of wooden frames on which reinforced polyethylene films are fixed on both sides along the contours with the help of rails, the distance between which corresponds to the thickness of the heat-insulating screen (50 ÷ 100 mm), and the dimensions of the openings in the frames in which the manhole covers are installed correspond to the size of the covers, the ends of the covers are equipped with sealing gaskets, and the attic rooms adjacent to the floor the edges of the films are lowered into trays installed on the floor, made of galvanized sheet steel and laid on wooden supports, providing a slight bias of the trays towards the nearest sewer risers, the outlets of the trays are equipped with holes that are connected to the holes drilled in the risers using hoses, and the connection points hoses to trays and risers are sealed.

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