RU2544184C2 - Quakeproof brick wall panel - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to construction of buildings and structures in quake-prone areas. In a quakeproof brick wall panel comprising brickwork from bricks with holes in the middle of the width and at one quarter of the length from brick ends, laid onto mortar with matching of holes into channels, and reinforcement rods pulled through channels with their stiff fixation at the ends, by means of flat stops along thickness, equal to thickness of the mortar joint, and in channels near the ends of the panel there are layers of vibration-damping material of U-shaped type that perceive spatial vibration, reinforcement rods are made as damping, and each of them represents a cylindrical damping element, to the ends of which flat stiff stops are stiffly attached, and the inner cavity is filled with a layer of vibration-damping material, for instance, sand, at the same time density of the vibration-damping layer is less than the density of the outer cylindrical shell of the damping element, besides, layers of vibration-damping material structurally made as U-shaped and perceiving spatial vibration, are made of ground worn car tyres on a binder in the form of rubber glue, liquid glass or polymer binder, and at every 8-10 rows of bricks laid on mortar stiff stops are welded, and damping rods are extended using welding, besides, mortar with vibration-damping crumb is poured into channels of the middle zone to form stiffer zones, and reinforcement rods are made damping, and each of them represents coaxially arranged cylindrical shells, between which there are tubular damping elements placed coaxially from vibration-damping material, to the ends of which flat stiff stops are rigidly attached, and the inner central cavity is filled with sand, at the same time density of layers of vibration-damping material is less than density of coaxially arranged cylindrical shells.

EFFECT: increased earthquake stability of a brick wall panel by increased damping.

4 dwg

Description

The invention relates to the construction in earthquake-prone areas of buildings and structures.

The closest technical solution to the claimed object is an earthquake-resistant brick panel with dressing in half a brick made of mortar bricks with openings in the middle of the width a quarter of the length from the ends of the brick into which damping rods are fixed, fixed on the pressure plate with nuts [utility patent of the Russian Federation No. 118331 - prototype].

The design of this brick panel has the following disadvantages. Due to the increased rigidity and the absence of effective damping multilayer elements, the rods are waveguides of mechanical vibrations, which not only in seismic conditions, but also during transport loads leads to the destruction of the panel.

A technically achievable result is an increase in the seismic resistance of a brick wall panel by increasing damping.

This is achieved by the fact that in an earthquake-resistant brick wall panel containing brickwork made of bricks with openings in the middle of the width and one quarter of the length from the ends of the bricks laid on the mortar with the holes in the channels aligned, and reinforcing bars passed through the channels with their rigid fixation on the ends, by means of flat stops in thickness equal to the thickness of the mortar seam, and in the channels at the ends of the panel there are layers of U-shaped vibro-damping material perceiving spatial vibration, reinforcing bars The dies are made damping, and each of them is a cylindrical damping element, to the ends of which are rigidly fixed rigid supports, and the inner cavity is filled with a layer of vibration damping material, for example sand, while the density of the vibration damping layer is less than the density of the external cylindrical shell of the damping element, and the layers of vibration damping material, structurally made of a U-shaped type and perceiving spatial vibration, made of shredded worn cars tires on a bundle in the form of rubber glue, water glass or a polymer binder, and hard supports are welded every 8-10 rows of bricks laid on the mortar, and damping rods are lengthened by welding, and a solution with vibro-damping crumb from crushed tires is poured into the channels of the middle zone car tires for the formation of more rigid zones, and the reinforcing bars are made damping, and each of them is a coaxially arranged cylindrical shell, between which is coaxial Tubular arranged damping elements of vibration damping material, the ends of which are rigidly attached to the flat rigid supports, and the internal central cavity is filled with sand, and the vibration damping material layers density less than the density coaxial cylindrical shells.

Figure 1 shows a brick (bearing element) in a perspective view with two holes, figure 2 is an earthquake-resistant brick wall panel, a plan view, figure 3 is a diagram of a damping rod of a brick wall panel, figure 4 is an embodiment of reinforcing bars rods in the form of a set of alternating cylindrical shells and tubular damping elements.

Earthquake-resistant brick wall panel (figure 2) is made of bricks 1 (figure 1) with two holes 2 in the middle of the width and one quarter of the length from the ends of the brick. In the combined holes 2 of the bricks 1 are placed damping (reinforcing) rods 3 (Fig. 3), at the ends of which are fixed flat stops 5 in thickness equal to the thickness of the mortar joint 4.

Each of the damping (reinforcing) rods 3 is a cylindrical damping element, to the ends of which are flat rigid stops 5, and the internal cavity is filled with a layer of vibration damping material, such as sand, and the density of the vibration damping layer must be lower than the density of the external cylindrical shell of the damping element. If the density of the vibration damping layer and the outer cylindrical shell are equal, then the damping element 3 will lose its ability to dampen vibration, which is unacceptable.

To increase the efficiency of damping shock loads and vibration in the channels designed to accommodate the mortar layer 4, layers 7 of vibration-damping material, structurally made of a U-shaped type, perceiving spatial vibration and made, for example, of crushed tires, are placed at the ends of the panel (and on the side) pneumatics (worn tires) on a bunch (rubber glue, water glass, polymer binder). After reaching the projected height of the panel for shrinkage of the layers of vibration damping material 7 in time, shutter speed and last hard stops are welded 5. The remaining gap (gap) is closed in the usual way.

As bricks (load-bearing elements), not only ceramic bricks can be used, but also (bricks) load-bearing elements made of synthetic materials, impregnated wood, hollow bricks filled with light vibration-absorbing and vibration-absorbing materials (not shown in the drawing).

A possible embodiment of reinforcing bars in the form of a set of alternating cylindrical shells 3 and 6 (Fig. 4) and tubular damping elements 9, the number of which is selected taking into account the required damping, depending on the level of seismic protection of the object.

The reinforcing bars are made damping, and each of them is a coaxially located cylindrical shells 3 and 6, between which are coaxially located tubular damping elements 9 of vibration damping material, to the ends of which are rigidly fixed flat stops 5, and the inner Central cavity 8 is filled with sand, with this density of the layers of vibration-damping material is less than the density of coaxially arranged cylindrical shells 3 and 6.

A possible embodiment of damping (reinforcing) rods 3 is when their inner cavity is filled with a layer of vibration damping material, the density of which is less than the density of the outer cylindrical shell of the damping element, while crumb of solid vibration damping materials, for example, agate, anti-vibration plastic compound, is used as vibration damping material. "," Shvim "with the size of fractions of crumbs of 0.5 ... 2.0 mm, filled with an elastomer, such as polyurethane.

It is possible that between the coaxially arranged cylindrical shells 3 and 6 there are tubular damping elements 9 made of vibration damping material, to the ends of which flat rigid stops 5 are rigidly attached, and the inner central cavity 8 is filled with crumbs of solid vibration damping materials, for example, agate plastic compound, “Anti-vibration”, “Shvim” with a size of fractions of crumbs of 0.5 ... 2.0 mm, filled with an elastomer, for example polyurethane, while the density of the layers of vibration-damping material is less than the density of the coaxial but located cylindrical shells 3 and 6.

Earthquake-resistant brick wall panel is mounted and provides vibration isolation as follows.

A layer of mortar 4 is applied between the columns on the foundation (not shown in the drawing). Flat rigid stops 5 are placed in the form of strips in the form of strips with vertically welded damping rods 3 welded to them 3 with a length of 1000 mm and a diameter of, for example, 16 mm, if the hole diameter is 2 a brick is 20 mm, for example, on a brick measuring 70x120x250 mm. Every 8-10 rows of bricks 1 laid on the mortar 1, hard stops 5 are welded, and damping rods 3 are elongated using welding. In order to save reinforcement in the channels of the middle zone, a solution with vibration damping crumb from crushed tire covers (worn out) can be poured to form more rigid zones.

The earthquake-resistant brick wall panel in dynamics has the following features.

Shorter damping rods 3 of the reinforcement are not waveguides of mechanical vibrations, since the propagation of vibrations is prevented, firstly, by welding units with rigid stops 5, and secondly, layers 6 of vibration damping material located in the damping rods themselves 3. When approaching mechanical waves vibrations to the panel from the outside they are met by vibration damping material, in layers 7, placed in the channels at the ends of the panel, and dampens, preventing their penetration to the middle zone. Between the layer of mortar 4 and the surfaces of the hard stops 5, as well as bricks 1, an infinitely decreasing reflection of waves of mechanical vibrations occurs.

Compared with the prototype design, the proposed earthquake-resistant panel has the following advantages: the range of damping the fluctuations of mechanical effects due to complex design features is expanded: shorter reinforcing bars 3 and the presence of vibration-damping material 6 in their cavities, as well as layers 7 of vibration-damping material, structurally made U-shaped type and spaced around the perimeter of the panel.

In addition, it is possible to dock panels by welding outlets of flat rigid stops 5.

Installation of floor beams is carried out by welding of U-shaped overlays on a brick (not shown in the drawing), which simultaneously serve as stops 5, rigidly connected to the reinforcing bar 3. The panels are joined by welding outlets of flat rigid stops 5 (not shown in the drawing).

Installation of floor beams, fastening of pipelines, cables is carried out by welding their fastenings to U-shaped transverse overlays for bricks, at the same time performing the function of rigid stops 5, rigidly connected to the reinforcing bar 3.

An earthquake-resistant panel can be used in the construction of vehicle bodies by using bricks made of light and durable materials, impregnated wood, plastics, synthetic mixtures, microporous materials.

Claims (1)

An earthquake-resistant brick wall panel containing brickwork made of bricks with holes in the middle of the width and one quarter of the length from the ends of the brick laid on the mortar with the holes in the channels aligned, and reinforcing bars passed through the channels with their rigid fixation at the ends, by means of flat stops on thickness equal to the thickness of the mortar seam, while in the channels designed to accommodate the mortar layer, layers of vibration-damping material, structurally made P-arr, are placed at the ends of the panel azine type, and perceiving spatial vibration, while the reinforcing bars are made damping, and each of them is a cylindrical damping element, to the ends of which are rigidly fixed flat stops, and the inner cavity is filled with a layer of vibration-damping material, while the density of the vibration-damping layer is less than the density of the external a cylindrical shell of a damping element, the layers of vibration damping material being structurally made of a U-shaped type and perceiving simple artificial vibration, made of crushed worn tires on a bundle in the form of rubber glue, liquid glass or a polymer binder, and every 8 ÷ 10 rows of bricks laid on the mortar, hard stops are welded, and damping rods are lengthened using welding, and it is poured into the channels of the middle zone mortar with vibration damping chips from crushed tire covers for the formation of more rigid zones, characterized in that each of the reinforcing bars is coaxially located cylindrical shells between which tubular damping elements of vibration damping material are coaxially located, rigid rigid stops are rigidly attached to the ends of the shells, while the density of the layers of vibration damping material is lower than the density of coaxially arranged cylindrical shells, and the inner central cavity is filled with vibration damping material, such as sand, to sand solid vibration-damping materials, for example, agate, anti-vibrate, shvim plastic compound with crumbs fraction size 0, 5 ... 2.0 mm, filled with an elastomer, for example polyurethane.

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