RU2848503C1 - Method of construction of ventilation duct for multi-storey building - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to methods for constructing ventilation systems for multi-storey residential and civil buildings from ventilation blocks. A ventilation duct is constructed from passage blocks stacked in a vertical row with a through collective duct for air passage and one or more satellite ducts for air intake from outside, separating blocks connecting the satellite ducts to the collective duct, and a headpiece in the form of a terminal block connecting the collective and satellite ducts. The ventilation duct is constructed floor by floor, where the upper passage block of each floor is located inside the inter-floor slab, and the ventilation duct block of the next floor is placed on the reinforcing belt.

EFFECT: increased reliability and stability of the ventilation duct of a multi-storey building, reduced construction time for the ventilation duct.

11 cl, 7 dwg

Description

The invention relates to the field of construction, namely to methods for constructing ventilation systems for multi-story residential and civil buildings from ventilation blocks [E04B 1/04, E04B 1/16, E04B 1/70, E04F 17/04].

The prior art discloses CELLULAR SUPPORTING BUILDING BLOCKS FOR VENTILATION AND AIR INTAKE SHAFTS [FR2521698 (A1), published: 19.08.1983] characterized in that the shaft consists of supporting elements with cells, the joining of which forms a box in which air ducts are located and two independent circuits are created, the pumped air of which softens the newly entering outside air through the walls, which is aimed at reducing losses from the ventilated room, wherein the supporting element consists of at least four air ducts, so that ventilation of stagnant air can be carried out from top to bottom along one of the channels located at one of the ends, returning upward into the other of the channels, cooling or heating the walls of the internal channels.

Also known is a VENTILATION CHANNEL [ES1066583 (U), published: 16.02.2008], formed by stacking in a vertical row prefabricated blocks intended for equipping various parts of a ventilation duct, including conductive blocks equipped with a main channel and one or more secondary channels, and deflecting blocks for establishing communication between the channels at the connection points of the main and additional air ducts, characterized in that the blocks, having an asymmetrical internal configuration, are provided with a mark on the outside signaling the position of these blocks.

The main technical issue with the analogue and prototype is the low reliability and stability of the ventilation duct structure due to the loads exerted on it by its own weight, which increases with the number of storeys of the building being constructed and, consequently, the weight of the ventilation duct. These loads also include dynamic loads, such as vibrations from equipment (fans, elevators, etc.), and thermal deformations due to temperature fluctuations. Low strength can lead to cracks, deformations, and even shaft collapse, as well as uneven settlement and distortions, leading to gaps, joint depressurization, and ventilation failure, which in turn leads to reduced airtightness and fire resistance (especially important for smoke ventilation).

The objective of the invention is to eliminate the shortcomings of the analogue and prototype.

The technical result of the invention consists in increasing the reliability and stability of the ventilation duct of a multi-story building and reducing the time required for construction of the ventilation duct.

The said technical result is achieved due to the fact that the method of constructing a ventilation duct of a multi-story building from blocks stacked in a vertical row and fastened with mortar, characterized in that the ventilation duct is erected floor by floor from through blocks provided with through insulated openings that form a collective duct for the passage of air through the ventilation duct and one or more satellite ducts for the intake of air into the ventilation duct from the outside, dividing blocks provided with a through opening for communicating the satellite ducts with the collective duct and a finishing block for forming the head of the ventilation duct above the roof of the building, provided with a through opening for communicating the collective and satellite ducts, where the upper through block of each floor is located in the opening of the interfloor ceiling intended for running the ventilation duct, and the block of the ventilation duct of the next floor is placed on a reinforcing belt located on top along the edges of the opening of the interfloor ceiling and fastened to the upper through block of the previous floor, wherein the ventilation duct The channel is installed in the opening of the interfloor ceiling with a gap on all sides; after installation, the gap is filled with non-combustible insulation based on mineral fiber, and a layer of cement mortar that binds the blocks is made with a mobility of 50-70 mm from cement of grade no lower than M100.

In particular, the reinforcing belt is made of a metal or composite strip, or profile, or rod.

In particular, the reinforcing belt is made in the form of two strips, or corners, or rods, located along opposite edges of the opening in the ceiling.

In particular, the edges of the reinforcing belt elements are made to protrude beyond the blocks.

In particular, a sealant in the form of a mineral cord is placed between the blocks near the reinforcing belt.

In particular, vertically oriented through holes are made in the corners of the blocks for additional connection of the blocks with rods.

In particular, the outside of the ventilation duct is fitted with a metal frame.

In particular, floor lathing is installed on top of the ceiling to hide the reinforcing belt or a screed is poured.

The said technical result is achieved due to the fact that the method of constructing a ventilation duct for a multi-story building formed from blocks stacked in a vertical row and fastened with mortar, characterized in that during monolithic construction the ventilation duct from through blocks equipped with through insulated openings that form a collective duct for the passage of air through the ventilation duct and one or more satellite ducts for the intake of air into the ventilation duct from the outside, dividing blocks equipped with a through opening for communicating the satellite ducts with the collective duct, is erected floor by floor from the bottom up to the calculated position of the interfloor ceiling with the upper surface of the upper through block of each floor level with or above the upper surface of the planned location of the ceiling, then the formwork of the ceiling around the ventilation duct is installed, concrete is poured, the surface is leveled and after the concrete has hardened, the construction of the ventilation duct of the next floor is continued, wherein the upper through block after pouring concrete for the ceiling is made mounted in the ceiling together with it with the ability to withstand the load mounted above parts of the ventilation duct and its redistribution to the ceiling, while completing the ventilation duct above the roof of the building with a finishing block equipped with a through hole for communication between the collective and satellite ducts and forming the head of the ventilation duct.

In particular, vertically oriented through holes are made in the corners of the blocks for additional connection of the blocks with rods.

In particular, the outside of the ventilation duct is fitted with a metal frame.

Brief description of the drawings.

Fig. 1 shows passage blocks 1 for construction in a ventilation duct with one collective duct (see Fig. 1a), two collective ducts (see Fig. 1b), three collective ducts (see Fig. 1c) and four collective ducts (see Fig. 1d).

Fig. 2 shows passage blocks 1 for constructing one collective and one satellite channel (see Fig. 2a), one collective and two satellite channels (see Fig. 2b) in the ventilation duct.

Fig. 3 shows separating blocks 2 for narrowing the collective channel or combining the collective and satellite channels into one (see Fig. 2a, 2b), narrowing the collective channel or combining the collective and satellite channels from one peripheral side of the collective channel and continuing the satellite channel from the other peripheral side of the collective channel.

Fig. 4-5 shows variants of sets of standard blocks for equipping a ventilation duct.

Fig. 6 shows a sectional view of a ventilation duct equipment option.

Fig. 7 shows a simplified ceiling with a reinforcing belt, view from above.

The figures indicate: 1 - passage block, 2 - separation block, 3 - finishing block, 4 - foundation, 5 - ceiling, 6 - ventilation hole, 7 - reinforcing belt.

Implementation of the invention.

The essence of the invention is a method for constructing ventilation ducts and chimneys for buildings and structures of various purposes that are resistant to various loads from ventilation blocks, for example, expanded clay concrete.

To construct individual ventilation ducts and chimneys, pass-through blocks 1, dividing blocks 2 for connecting the satellite duct to the collective duct and a finishing block 3 for constructing the head are used.

Each of the blocks 1-3 is made in the form of a rectangular parallelepiped of a standard size for their connection into a single structure.

Pass-through block 1 is designed for the installation of a collective and satellite duct, or just a collective duct. The collective duct is designed to ensure airflow from the bottom up along the entire height of the ventilation duct. In one embodiment, the satellite duct is designed to supply fresh air to the collective duct from outside and serves as a link between the external environment and the building's internal utilities, ensuring efficient air transport within the collective duct and protection from dust, dirt, and insects. In another embodiment, the satellite duct is designed to connect additional rooms in the building to the collective duct in parallel. The total length of one satellite duct is typically one floor, meaning air entering the satellite duct rises along it to the next floor and then enters the collective duct.

To construct a collective duct, pass-through block 1 is a rectangular parallelepiped block with at least one through-hole along its length, forming an air duct. To construct multiple collective ducts, pass-through block 1 is provided with a corresponding number of isolated through-holes of equal area.

Figure 1 shows passage blocks 1 for constructing one collective channel (see Fig. 1a), two collective channels (see Fig. 1b), three collective channels (see Fig. 1c) and four collective channels (see Fig. 1d) in the ventilation duct.

In order to construct a collective and satellite channels using the pass-through block 1, several through isolated openings are made in the pass-through block 1, forming air channels, the number of which corresponds to the total number of collective and satellite channels required for the equipment, wherein the collective channel is predominant in terms of the area of the opening, and is made in the center or with an offset to one of the side ends of the pass-through block, and the satellite channel, one or more, is made along the periphery of the collective channel with an offset to the opposite side end of the pass-through block 1.

Figure 2 shows passage blocks 1 for the construction of one collective and one satellite channel (see Fig. 2a), one collective and two satellite channels (see Fig. 2b) in the ventilation duct.

Divider block 2 is designed to narrow (expand) the collective channel or to connect a satellite channel to the collective channel. Divider block 2 is a rectangular parallelepiped block with at least one through-hole along its height, formed in the lower base corresponding to the feed-through channel or the feed-through and satellite channels combined, tapering upward from the collective and satellite channels of lower feed-through block 1 to the collective channel of upper feed-through block 1 at an angle of 30 to 60 degrees.

Figure 3 shows dividing blocks 2 for narrowing the collective channel or combining the collective and satellite channels into one (see Fig. 2a, 2b), narrowing the collective channel or combining the collective and satellite channels from one peripheral side of the collective channel and continuing the satellite channel from the other peripheral side of the collective channel.

The final block 3 (see Fig. 4-5) is designed to equip the head of the ventilation duct and is a block made in the form of a rectangular parallelepiped, inside which, along the height, one through hole is made across the entire area of the block 3, taking into account the thickness of its side walls and which is designed with the possibility of communicating with the collective and satellite channels.

The outer side edges of blocks 1-3 can be straight or rounded.

At the corners of the outer shell of blocks 1-3, vertical through holes (not shown in the figures) of equal diameter, for example 30 mm, can be made to further enhance static stability by reinforcing with steel rods through the mentioned holes of the ventilation duct, for which purpose the mentioned holes must be aligned when installing reinforced blocks 1-3 in a vertical row.

Installation of a ventilation duct using the specified blocks begins with selecting its location relative to the building's structural elements (walls, partitions, floor beams, rafters). The location and installation method of the ventilation duct are determined in accordance with the design. Foundation 4 (base) can be constructed to install the ventilation duct in the foundation. In one implementation option, the floor can be used as the foundation for the ventilation duct. For example, the ventilation duct can be installed from the floor of the second or another floor above the first. In this case, air is supplied to the ventilation duct through the satellite duct of the lower pass-through block 1 through an opening in the floor, on which the ventilation duct rests. This option can be implemented primarily from the second floor to save space on the ground floor, and the ventilation distribution and connection to the ventilation duct are achieved using metal ducts.

Installation of the ventilation duct begins from the bottom and is carried out floor by floor.

When installing a ventilation duct on a foundation, first a foundation 4 is cast, on which a waterproofing material is laid, and when using a combustible material, it is covered with a fire-retardant composition, then the first pass-through block 1 is installed, containing one collective and one satellite duct, while the pass-through block 1 with a satellite duct is mounted in the direction of the first floor room in which ventilation must be equipped.

Pass-through blocks 1 are installed sequentially upward in a single vertical row up to the opening made in the first floor 5 for the ventilation duct to pass through. The first floor ventilation duct is terminated with a pass-through block 1, with the upper surface of the upper pass-through block 1 being flush with or higher than the upper surface of the first floor 5.

Next, a reinforcing belt 7 (see Fig. 7) made of a strip, profile, or rods, such as metal or composite, is installed along the upper edges of the opening through which the ventilation duct extends to floor 5. Said reinforcing belt 7 may be made in the form of two strips, angles, or rods positioned along opposite edges of the opening in floor 5 for extending the ventilation duct. If angles are used for reinforcing belt 7, they are positioned along the edges of the opening with their lower flanges facing each other. The edges of the elements of reinforcing belt 7 should extend beyond the blocks by a distance depending on the weight of the floor ventilation duct and the thickness of the elements of reinforcing belt 7 in order to effectively redistribute the load from the ventilation duct to floor 5.

Next, on the said reinforcing belt 7, over the top block of the first floor, the installation of the ventilation duct of the second floor continues to the roof (roofing) of the building or to the next ceiling 5, where the upper passage block 1 is similarly led out into the opening in the ceiling 5.

Reinforcement of the ventilation duct is performed on each floor. Elements of the reinforcing belt 7 can be secured to the floor to prevent them from shifting during ventilation duct construction.

In one embodiment, a mineral cord is laid on the surface of the upper passage block 1, which is led out into the opening in the ceiling 5, to seal the joint with the next block.

Above the roof (roofing) of the building, a finishing block 3 is mounted on the passage 1 or dividing 2 block located on top.

The final block 3, located above the roof level, can be protected from atmospheric influences in various ways, for example, by plastering, metal finishing, brick cladding, etc.

Thus, the entire ventilation duct is assembled from standard blocks 1-3, which are typically 300-350 mm high, passing through openings in the slabs 5 and through the upper slab 5 of the structure, reinforced with reinforcing belts 7. Ventilation blocks 1-3 are installed on a 10 mm thick layer of cement mortar of at least grade 100. The mortar flow should be 50-70 mm at the depth of the standard cone. When applying the mortar, an installation template (not shown in the figures) is used to ensure the required mortar thickness and protect the internal collective and/or satellite ducts from mortar loss during installation. After installing each block 1-3, the internal joints must be carefully grouted.

On top of the ceilings 5, the floor lathing is installed or a screed is poured, ensuring the concealment of the reinforcing belt 7.

To install ventilation grilles, openings are cut in the side walls of the pass-through block 1, which form the walls of the satellite duct, into which the ventilation grilles are mounted. To create an inspection opening, it is preferably cut in the first pass-through block 1 from the base 4, into which the inspection hatch is installed. The height of the ventilation duct above the roof of the structure in which the ventilation duct is installed depends on the location of the ventilation duct relative to the roof (roof ridge) and adjacent building structures, taking into account the need to prevent the terminal block 3 of the ventilation duct from falling into the wind pressure zone.

For additional rigidity, if the height between floors (5) exceeds 3.5 meters, or if the free-standing portion of the ventilation duct rises above the roof (roofing) by more than 1.33 meters, the ventilation duct structure is additionally reinforced with steel rods (reinforcement), which can be threaded. These rods are installed through openings in the outer shells of blocks 1-3 and filled with liquid cement mortar. Blocks 1-3, which do not have openings for reinforcement, can be reinforced by external metal strapping.

After installation, the ventilation duct is plastered on all sides with a high-adhesion cement plaster. A special plaster mix or tile adhesive can be used as the plaster.

In one embodiment of monolithic construction, in the absence of floors during the construction of the ventilation duct, the ventilation duct is brought out to the calculated position of the floor taking into account the location of the upper surface of the upper block, as described above, level with or above the upper surface of the planned floor, and then the formwork of the upper floor is installed around the ventilation duct, concrete is poured, the surface is leveled and after the concrete has hardened, construction of the ventilation duct is continued, wherein the upper passage block 1, after pouring concrete into the floor 5, is made built into the floor 5 and forms a single whole with the floor 5 and performs the function of reinforcing the ventilation duct, taking the load of the part of the ventilation duct mounted above and redistributing it to the floors 5.

When installing blocks 1-3, ventilation ducts must not be interrupted in floors 5 to ensure fire resistance requirements. When passing through floors 5, the opening in floor 5 must be at least 20 mm larger than the dimensions of blocks 1-3 on all sides. The gap is filled with non-combustible mineral fiber insulation with a density of 100 to 200 kg/ ^m³ . The insulation in the gap is plastered with a 10-15 mm thick cement plaster or lined with dry plaster grade NG. A vibration joint is made in the plaster (before drying, a smooth cut is made with a spatula at a distance equal to the thickness of the insulation from the edge of block 1-3).

To protect against precipitation, a metal apron is installed in the gap between blocks 1-3 and the roof above the roof. Above the roof, the outer shells of terminal block 3 must be protected from precipitation.

After installation is complete, check the ventilation duct seams for leaks and ensure there is draft in the duct. To accurately check for draft, hold a lit candle or strip of thin paper to the open bottom of the duct. If the flame or strip of paper deflects toward the duct, draft is present.

To check the tightness of the joints of a ventilation duct operating under vacuum, use safe smoke bombs, visually checking for leaks.

Regularly, at least once a year, ventilation ducts are cleaned of dirt.

In addition to the high reliability and stability of the ventilation duct due to the reduction of the load by redistributing it to the ceiling 5 using reinforcing belts 7 or a passage block 1 built into the ceiling, the maintainability of the ventilation duct or the change of its functionality by replacing blocks without dismantling the entire ventilation duct, but only within the floor, is ensured.

Furthermore, the speed of ventilation duct construction is increased, as there is no need to wait for the mortar to harden before laying the blocks. After constructing the ventilation duct for one floor, construction of the ventilation duct for the next floor can begin immediately, as the vertical load from the ventilation duct's own weight is redistributed to floor 5. Thus, when constructing multi-story buildings or multiple buildings simultaneously, the number of work crews involved in ventilation duct construction can be reduced, and logistics can be improved. This improved logistics is achieved by eliminating the need for crews to move from one site to another while waiting for the mortar to harden during ventilation duct construction. The crew's move from one site to the next occurs after work on the site is completed. This reduces labor costs and the labor intensity of ventilation duct construction, increasing the speed of construction.

Claims (11)

1. A method for constructing a ventilation duct for a multi-story building from blocks stacked in a vertical row and fastened with mortar, characterized in that the ventilation duct is erected floor by floor from through blocks equipped with through insulated openings that form a collective duct for the passage of air through the ventilation duct and one or more satellite ducts for the intake of air into the ventilation duct from the outside, dividing blocks equipped with a through opening for communicating the satellite ducts with the collective duct and a finishing block for forming the head of the ventilation duct above the roof of the building, equipped with a through opening for communicating the collective and satellite ducts, where the upper through block of each floor is located in the opening of the interfloor ceiling intended for running the ventilation duct, and the block of the ventilation duct of the next floor is placed on a reinforcing belt located on top along the edges of the opening of the interfloor ceiling and fastened to the upper through block of the previous floor, while the ventilation duct in the opening of the interfloor The ceilings are installed with a gap on all sides; after the channel is installed, the gap is filled with non-combustible insulation based on mineral fiber, and the layer of cement mortar that binds the blocks is made with a mobility of 50-70 mm from cement of grade no lower than M100. 2. The method according to paragraph 1, characterized in that the reinforcing belt is made of a metal or composite strip, or profile, or rod. 3. The method according to paragraph 1, characterized in that the reinforcing belt is made in the form of two strips, or corners, or rods, located along opposite edges of the opening in the ceiling. 4. The method according to paragraph 1, characterized in that the edges of the reinforcing belt elements are made to protrude beyond the blocks. 5. The method according to paragraph 1, characterized in that a sealant in the form of a mineral cord is placed between the blocks near the reinforcing belt. 6. The method according to paragraph 1, characterized in that vertically oriented through holes are made in the corners of the blocks for additional connection of the blocks with rods. 7. The method according to paragraph 1, characterized in that the outside of the ventilation duct is provided with a metal frame. 8. The method according to paragraph 1, characterized in that floor lathing is installed on top of the ceiling to conceal the reinforcing belt, or a screed is poured. 9. A method for constructing a ventilation duct for a multi-story building, formed from blocks stacked in a vertical row and fastened with mortar, characterized in that during monolithic construction, the ventilation duct from through blocks equipped with through insulated openings that form a collective duct for the passage of air through the ventilation duct and one or more satellite ducts for the intake of air into the ventilation duct from the outside, dividing blocks equipped with a through opening for communicating the satellite ducts with the collective duct, is erected floor by floor from the bottom up to the calculated position of the interfloor ceiling with the upper surface of the upper through block of each floor level with or above the upper surface of the planned location of the ceiling, then formwork for the ceiling is installed around the ventilation duct, concrete is poured, the surface is leveled and after the concrete has hardened, construction of the ventilation duct of the next floor is continued, wherein the upper through block after pouring concrete for the ceiling is made mounted in the ceiling together with it with the ability to withstand the load of the part of the ventilation duct mounted above and redistributing it to the ceiling, while completing the ventilation duct above the roof of the building with a finishing block, equipped with a through hole for communication between the collective and satellite ducts and forming the head of the ventilation duct. 10. The method according to paragraph 9, characterized in that vertically oriented through holes are made in the corners of the blocks for additional connection of the blocks with rods. 11. The method according to paragraph 9, characterized in that the outside of the ventilation duct is provided with a metal frame.