RU2682384C1 - Reinforced brickwork - Google Patents

Abstract

FIELD: construction.SUBSTANCE: invention relates to the construction and can be used in the construction of multi-storey buildings in seismic areas. Reinforced brickwork includes bricks laid in rows with stitching, vertical and horizontal reinforcement, each row of masonry is formed by a combination of three spoon bricks, laid with a gap, and a pair of butt brick bricks, laid one behind the other, adjacent to their ends, the rows are displaced one relative to the other by 1/4 of a brick with the formation of vertical through channels, in which vertical reinforcement is installed, while the horizontal reinforcement is laid in the longitudinal direction into the gaps formed by spoon bricks, and in the transverse direction, the horizontal reinforcement passes through the seams, in addition, the channels and seams with reinforcement are filled with cement mortar, while the vertical reinforcement is made with helical protrusions on the outer surface, both in the longitudinal and in the transverse placement along the brickwork, the vertical reinforcement is arranged in pairs in such a way that on the first vertical reinforcement of each pair, the tangent of the helical protrusions has a clockwise direction, and on the second vertical reinforcement, the tangent of the screw-shaped protrusions has a counterclockwise direction, and a continuous chain of vertical rebar, which is pairwise located in pairs, is made, compensating for the seismic breaking forces in the reinforced brickwork. Ends of the vertical reinforcement are not less than the thickness of the brick covered with a glassy nanosized film of tantalum oxide, and the surface of the ends of the vertical reinforcement is made according to the cycloid curve as a brachistochrone.EFFECT: technical task of the present invention is to provide normalized periods for the safe operation of reinforced masonry by eliminating the erosion of cement in the joints and channels of masonry.1 cl, 6 dwg

Description

The invention relates to the construction and can be used in the construction of multi-storey buildings in seismic areas.

Reinforced brickwork is known (see RF patent No. 2427685. IPC E04B 2/34. Publ. 08/27/2011) of a two-row system, including bricks laid in rows with dressing of seams, vertical and horizontal reinforcement, with each row of masonry formed by a combination of three spoon bricks , laid with a gap, and adjacent to their ends are pairs of bonded bricks laid one after another, the rows being offset 1/4 of the brick relative to one another with the formation of vertical through channels in which vertical reinforcement is installed, while horizontally The reinforcement in the longitudinal direction is laid in the gaps formed by the spoon bricks, and in the transverse direction the horizontal reinforcement passes through the seams, in addition, the channels and seams with reinforcement are filled with cement mortar, while the vertical reinforcement is made with helical protrusions on the outer surface, and as in longitudinal and transverse to the masonry, the vertical reinforcement is arranged in pairs in such a way that the tangent of the helical protrusions on the first (of each pair) vertical reinforcement has a clockwise direction, and on the second vertical reinforcement, the tangent of the helical protrusions has a counterclockwise direction, while a continuous chain of vertically arranged pairs of vertically arranged compensates for seismic destructive forces in reinforced brickwork.

The disadvantage is the reduction of strength parameters during long-term operation, especially with the presence of precipitation, subjecting the ends of the vertical reinforcement located in the channels and seams filled with cement mortar, which is a capillary material, to intensive corrosion damage.

Known reinforced brickwork of a two-row system (see RF patent 2600951. Publ. 10.27.2016), including bricks laid in rows with dressings, vertical and horizontal reinforcement, each row of masonry is formed by a combination of three spoon bricks laid with a gap, and adjacent to their ends there are pairs of bonded bricks stacked one after another, and the rows are shifted relative to each other by 1/4 of the brick with the formation of vertical through channels in which vertical reinforcement is installed, while horizontal reinforcement in the longitudinal direction is laid in the gaps formed by the spoon bricks, and in the transverse direction the horizontal reinforcement passes through the seams, in addition, the channels and seams with the reinforcement are filled with cement mortar, while the vertical reinforcement is made with helical protrusions on the outer surface, both in longitudinal and and in the transverse arrangement on the masonry, the vertical reinforcement is arranged in pairs so that on the first of each pair of vertical reinforcement the tangent of the helical protrusions has a direction clockwise, and on the second vertical reinforcement, the tangent of the helical protrusions has a counterclockwise direction, while a continuous chain of vertically arranged pairs of vertically compensating seismic destructive forces in reinforced masonry is made, in addition, the ends of the vertical reinforcement are not less than the thickness bricks are covered with a glassy nanoscale tantalum oxide film.

The disadvantage is the decrease in safety during long-term operation, especially of ventilation shafts of industrial premises and office buildings, as well as of residential high-rise buildings in the conditions of changing weather and climate precipitation during transitional periods of the year with periodic exposure to snow and blizzard or fog and rain in contact with the ends of vertical fittings, when slowly moving wet contaminants along curved surfaces to channels and seams filling with cement mortar intensively destroy the compound Ia brickwork.

The technical task of the invention is to ensure normalized periods of safe operation of reinforced masonry by eliminating the erosion of cement in the seams and channels of the brickwork of the ventilation shafts of industrial premises and high-rise office and residential buildings due to the speed of descent of wet contaminants along the curved surface of the ends of the vertical reinforcement when cycloid as brachistochron a .

The technical result is achieved by the fact that the reinforced brickwork of a two-row system includes bricks laid in rows with dressing of seams, vertical and horizontal reinforcement, each row of masonry formed by a combination of three spoon bricks laid with a gap and adjoining pairs of bonded bricks laid to their ends one after another, and the rows are offset relative to each other by 1/4 of the brick with the formation of vertical through channels in which vertical reinforcement is installed, while horizontal reinforcement in the longitudinal direction is laid in the gaps formed by the spoon bricks, and in the transverse direction the horizontal reinforcement passes through the seams, in addition, the channels and seams with the reinforcement are filled with cement mortar, while the vertical reinforcement is made with helical protrusions on the outer surface, both in longitudinal and and in the transverse placement on the masonry, the vertical reinforcement is arranged in pairs so that on the first of each pair of vertical reinforcement the tangent of the helical protrusions has a direction clockwise, and on the second vertical reinforcement, the tangent of the helical protrusions has a counterclockwise direction, while a continuous chain of vertically arranged pairs of vertically compensating seismic destructive forces in the reinforced masonry is made, while the surface of the ends of the vertical reinforcement is made according to the cycloid curve like a brachistochron.

Figure 1 shows a perspective view of brickwork with a reinforced thickness of two bricks; figure 2 is a vertically mounted pair of reinforcement elements with helical protrusions, the direction of their tangents has a mutually opposite direction; figure 3 - distribution of the amplitude of seismic vibrations on the surface of the protrusions of a pair of vertically mounted reinforcement, figure 4 - pairwise longitudinal and transverse placement of vertical reinforcement on masonry with a compensating distribution of destructive seismic forces, figure 5 - the end face of the vertical reinforcement, covered with glass tantalum oxide nanoscale film, in Fig.6 - the surface of the end face of the vertical reinforcement is made according to the cycloid curve as a brachistochron.

Each row of the proposed masonry consists of three spoon bricks 1, laid with a gap 2. A pair of bricks 3 adjoins the ends of the spoon bricks 3 with a quarter offset of each row relative to the next, which creates vertical continuous channels 4 in which vertical reinforcement is installed 5. The horizontal reinforcement 6 in the longitudinal direction fits into the gap, and the horizontal reinforcement 7 in the transverse direction is placed in the masonry seam. The reinforcement can be laid both preliminary and simultaneously with the erection of masonry, and the channels and gaps are filled with cement mortar. The vertical reinforcement 5 is arranged in pairs in such a way that on one of the pair 8 of the reinforcement 9 on the outer surface 10 there are helical protrusions 11, the tangent of which has a clockwise direction, and on the other of the pair 8 of the reinforcement 12 on the outer surface 13 there are helical protrusions 14 whose tangent has a counterclockwise direction.

The outer surface 15 of the end face 16 of the vertical reinforcement 5 is not less than the thickness of the brick 1 is covered with a glassy nanoscale film of tantalum oxide 17.

The vertical reinforcement 5 of the masonry of a two-row system in the presence of atmospheric precipitation is subjected to intense corrosive attack. This is due to the fact that the brick, as a cement mortar, filling the channels with vertical reinforcement 5 located, is a capillary-porous material with a high coefficient of thermal moisture conductivity. Moreover, due to the transfer of heat to the environment (the evaporation process), the surface layers of the brickwork material (brick and cement mortar) are cooled and their temperature becomes lower than inside the material, i.e. at the location of the vertical reinforcement 5, then such a distribution causes a temperature gradient directed from the surface of the material to the middle, which increases the overall moisture conductivity (see, for example, pp.440-442. Nashchokin VV Technical thermodynamics and heat transfer. M., 1980, 469s., Ill.), And on the inner surface 15, especially the end 16, of each vertical reinforcement 5, fine droplets of moisture appear, which coagulate and, coarsening, form “spots” of liquid.

In addition, the coefficient of thermal conductivity of bricks and cement slurries ranges from 0.47 to 0.76 W / (m ^* g), for example, bumpy bricks, and cement-sand mortars (see SNiP 2.2.3-92 “Construction Thermophysics” ". M.: TSNTI Gosstroy of the Russian Federation, 1996), the thermal conductivity of the material (metal) of the vertical reinforcement is at least 40 W / (m ^* gr.), I.e. exceeds more than 50 times, which leads to the occurrence of counter-directed temperature gradients with the formation in the zone of the outer surface 15 of vertical reinforcement 5 with cement mortar and / or brick of a high-intensity process of drying wet material with a specific mass content gradient (see page 330. Choi P.V. Methods for calculating individual heat and mass transfer problems.M .: Energia, 1971, 384 pp., Silt). As a result, the condensate-evaporation process of the "spot" of liquid on the outer surface 15 of the vertical reinforcement 5 under conditions of an increased temperature gradient intensifies the corrosive effect of moisture, which leads to a decrease in the strength parameters of reinforced brickwork as a whole.

When the ends 16 of the vertical reinforcement 5 are coated with a glassy nanoscale film of tantalum oxide 17, finely dispersed moisture droplets do not stick to the outer surface 15, but slide off it (see, for example, Litvinova V.A., Savruk E.N. Nanosized films of tantalum oxide, obtained by the ion-plasma method // Proceedings of the regional scientific-practical conference `` Modern problems and achievements of agricultural science in animal husbandry, crop production and economics ''. - Tomsk: TEHINGAU. - Issue 12. - 2010. - P.299-301 ) and the brick is scattered throughout the volume and / or cement slurry as a capillary-porous material. Consequently, there is practically no corrosive effect of moisture from precipitation on vertical reinforcement 5. Which helps to maintain strength parameters during long-term operation of reinforced brickwork.

Reinforced brickwork of a two-row system under conditions of both exposure to varying atmospheric precipitation and seismic effects is safely safe to operate as follows. The surface 18 of the ends 16 of the vertical reinforcement 5 covered with a glassy nanoscale film 17 of tantalum oxide is made according to the curve of cycloid 19 as a brachistochron.

Reinforced brickwork of a two-row system, especially of ventilation shafts of industrial premises and office buildings, as well as residential high-rise buildings under conditions of both exposure to changing atmospheric precipitation and seismic effects, is safe to operate as follows for a long time.

The ventilation shafts of high-rise residential and office buildings, as well as industrial premises due to the presence of different concentrations of finely dispersed indoor air pollution, accumulated as the moving stream moves from the base to its outlet to the environment (see, for example, Altshul A.D. Hydraulics and aerodynamics. M.: Stroyizdat. 1987 - 414 p., ill).

With changing weather and climatic precipitation, especially during the transition periods of the year: winter-spring and autumn winter, dense wet pollution in the form of a mixture of solid particles of snow and droplet-like moisture slowly disappears without sticking to an arbitrary curved surface of 18 ends 16 of the vertical reinforcement 5 covered with a glassy nano-shaped film 15 from tantalum oxide. The small surface 18 of the ends 16 in comparison with the surface of the brick 1 and / or the seam with a gap 2 and channels 4 does not allow the evaporation of wet contaminants and they scatter, adhering to the surface of the brick 1 and / or the seam with a gap 2, which slows down the effect of the heat of the heated ventilated air to heat moist contaminants for subsequent evaporation and discharge of the vapor mass into the environment.

In addition, the increased pressure in the ventilation zone of the contact of the air coming out of its outlet opening increases the speed of the moving flow i.e. the Joule-Thomson effect is observed (see, for example, Isachenko V.P., Osipova V.A. Heat transfer - M .: Energy, 1980 - 439 s., silt) with decreasing temperature and, accordingly, additional condensation of moisture vapor from atmospheric air slowly moving along the surface of 18 ends 16. All this intensifies the wet destruction of the capillary-porous material of brick and cement mortar, followed by a decrease in the safe operation of the reinforced brickwork of the ventilation shaft of a production building or a high-rise building.

When curvature is performed according to cycloid 19 as a brachistochron of the surface 18 of the ends 16 of the vertical reinforcement 5, the particles of wet contaminants with the greatest speed under the influence of gravity and the peculiarities of curvature, which promotes the formation of centrifugal force (see, for example, Some remarkable curves p. 802. Vygodsky M. I. Handbook of Higher Mathematics, Moscow: 1969–872 p., Sludge) in the least amount of time move on the surface of a brick and / or cement joint, where they are in contact with heated ventilation air and due to its heat They evaporate non-violently without moisture exposure to the capillary-porous material. Consequently, the safe operation of the ventilation shaft is ensured in the normalized time when changing weather and climate influences.

The perturbing impulse action of a standing wave under seismic loading corresponds to the formation of a force field of stresses, which moves from bottom to top mainly in the surface region of vertically mounted reinforcement 5. Vertical reinforcement 5 is installed in vertical continuous channels 4 by pairs 8, while on reinforcement 9 pairs 8 on the outer surface 10 helical protrusions 11 are made, and on the reinforcement 12 on the outer surface 13 there are helical protrusions 14, and the tangent helical protrusions of the armature Pairs 9 and 12 of pair 8 have the opposite direction. As a result, the oscillation amplitude of the vertical reinforcement 5 of each pair 8 of the vertical reinforcement 5, having a displacement in space, intensively suppresses the force fields of stress, moving from bottom to top along the reinforced brickwork, which makes it possible to increase seismic resistance and, accordingly, the strength of a multi-story building.

The originality of the invention lies in the fact that ensuring the safe operation of reinforced brickwork of a two-row system of mainly ventilation shafts, especially production rooms with high saturation with moist pollution of internal air in high-rise buildings in changing weather and climate conditions of periodic exposure to atmospheric air, is ensured by timely evaporation of droplet and condensing moisture on the surfaces of bricks and / or cement mortar pa due to the steepest descent on a liquid surface of end vertical reinforcement formed as a cycloid curve brachistochrone the nip to heat the ventilation air.

Claims (1)

Reinforced brickwork, including bricks laid in rows with dressing of seams, vertical and horizontal reinforcement, each row of masonry formed by a combination of three spoon bricks laid with a gap and adjacent to their ends pairs of bonded bricks laid one after another, and the rows are offset one 1/4 brick relative to another with the formation of vertical through channels in which vertical reinforcement is installed, while horizontal reinforcement in the longitudinal direction is laid in the gaps formed by the spoon bricks, and in the transverse direction, horizontal reinforcement passes through the seams, in addition, the channels and seams with reinforcement are filled with cement mortar, while the vertical reinforcement is made with screw-like protrusions on the outer surface, both in longitudinal and transverse placement on brickwork the vertical reinforcement is arranged in pairs so that on the first of each pair of vertical reinforcement the tangent of the helical protrusions has a clockwise direction, and on the second vertical reinforcement the tangent of the helical protrusions has a counterclockwise direction, with a continuous chain of vertically arranged pairs of vertically compensating seismic destructive forces in the reinforced masonry, in addition, the ends of the vertical reinforcement not less than the thickness of the brick are covered with a glassy nanoscale tantalum oxide film, characterized in that the surface of the ends of the vertical reinforcement is made according to the cycloid curve as a brachistochron.

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