RU87723U1 - BUILDING STONE - Google Patents

Abstract

1. A building stone with a width of wall thickness, consisting of longitudinal ribs located across the heat flux and connecting bridges that form a hollow, characterized in that the outer and middle longitudinal ribs are connected by two bridges, the longitudinal axis of which is offset from the ends by a quarter of the length of the stone forming in the middle one void and half-empty at the ends on three sides, and the middle and inner longitudinal ribs are connected by four other jumpers in such a way that they form a gap in the middle, and along there are two identical voids at the ends, while the cross section of the two middle jumpers together with the gap between them is equal to the sum of the cross sections of two other jumpers located at the ends. ! 2. Building stone according to claim 1, characterized in that the width of the inner longitudinal ribs with respect to two other longitudinal ribs is at least 0.72 parts of their total latitude. ! 3. The building stone according to claim 1, characterized in that the outer longitudinal rib is shorter than the other two longitudinal ribs by the width of the vertical outer seam between the stones. ! 4. The building stone according to claim 1, characterized in that in the jumpers connecting the middle and inner longitudinal ribs and located at the ends, grooves are selected.

Description

The utility model relates to construction, namely to the construction of building stones with a width of the entire thickness of the wall and can be used for masonry exterior walls and foundations.

The “Fortis LS” main unit is known, the cracks of which are filled with polystyrene foam, and the bearing base is made of expanded clay concrete (PPHU Wlasciciel Lacek Su Kieinnik Lodz, Poland 1999. The product is patented and certified in Russia for fire and environmental safety in 2003). of this block is that only two out of five (40%) insulated slots go to the ends, where they are interrupted for dry vertical interfacing with the neighboring block and taking into account that the polystyrene foam dries out over time, all this reduces the joint thermal resistance. In addition, the manufacture of special shaped polystyrene foam liner complicates the manufacture of stone.

Close in technical essence is the “profile wall hollow block”, with a width of the wall thickness, the structural basis of which is made of ordinary or lightweight concrete, while the voids of the outer row are filled with insulation, and the voids of the inner row are filled with concrete (see page 149 Jozsef Koso. Your new home. Energy-saving technologies. Translation and publication in Russian "CJSC Publishing Group Content. 2008)

The disadvantages of this block include the fact that the concrete straight lintels connecting the three longitudinal ribs are “cold bridges”, both in the center of the block and at the ends. If instead of concrete, polystyrene foam or cement-based chips are used for the base of the block, as indicated in the description, then the additional protection of their inner and outer sides complicates the technology of walling.

The purpose of the utility model is to create a new construction stone structure in which materials with various effective properties are optimally combined and used to increase thermal protection and wall strength.

This is achieved by the optimal combination of load-bearing longitudinal ribs and transverse bridges, forming voids, in such a new configuration that allows not only stones to be effectively insulated, but also not interrupted by equivalent insulation in vertical and horizontal joints and, at the same time, additionally strengthen the walls, if necessary, simplifying the technology of their construction.

Figure 1 presents the proposed building stone in a perspective view. In figure 2, 3 is a view of the masonry in plan (respectively 1 and 2 row)

Outer 1, middle 2 and inner 3 — longitudinal ribs located across the heat flux are connected by jumpers 4 and 5. The axis of the jumpers 4 connecting the outer 1 and middle 2 longitudinal ribs are offset from the ends of the stone by a quarter of its length and form one in the middle a through void 6, filled with an effective heater 11 and open on three sides at the ends of the half-cavity 7, which at a vertical junction with an adjacent stone form a closed void, filled also with an effective heater 11; jumpers 5 connecting the middle 2 and inner 3 longitudinal ribs together form a gap 8 in the middle, and two identical voids 9 on both sides at the ends, while the cross section of the two middle jumpers 5 together with the gap 8 is equal to the sum of two other transverse cross-sections of jumpers 5 located at the ends.

In this new combination of ribs with each other during longitudinal dressing of the masonry of the walls, the stones of the upper row coincide with the whole area and transfer pressure to the entire area of the ribs and lintels of the lower row, and, thus, the strength properties of the material are uniformly and fully used, and in matching voids, without interruption in horizontal and vertical seams, insulation 11 and, reinforcing walls, concrete filling 12 are located.

As can be seen from figures 1 and 2, the masonry of the walls is made mainly of two sizes: ordinary stone and corner element. Halves along the length of the stone for dressing the masonry and other additional elements due to the small need are obtained by sawing ordinary stones.

As an effective insulation 11, backfill from expanded polystyrene granules, perlite, vermiculite or solid inserts, etc., which fill the voids located closer to the outside, are used. The stones are laid end-to-end with the ends of the middle and inner longitudinal ribs without a solution between them, and to protect against blowing, moistening the vertical joint and securing against lateral displacement, and the device for this purpose is filled with a solution of the vertical outer seam 13 and the key 14, the outer longitudinal rib 1 is made shorter than the length stone to the width of this seam, and on the end bridges 5 selected grooves 10.

The thermal resistance test of a wall with a thickness of 380 mm, i.e. the entire width of expanded clay stone with a density of 1400 kg / m ³ , in which the voids of the outer row were filled with insulation from expanded polystyrene chips with a density of 20 kg / m ³ , confirmed that the wall of such stones satisfies normative requirements of thermal protection for a climatic zone with an external temperature of a cold five-day period of -31 ° C, and transverse bridges that are divided into two rows with an offset in plan are not “cold bridges”. An increase in thermal resistance by another 30% is achieved, as the tests confirmed, due to the additional filling of the voids of the inner row with a heater.

The width of the inner longitudinal ribs 3, to equalize the stresses in the horizontal section of the stone from the load eccentrically transmitted by the overlap, and to increase its thermotechnical properties, is at least 0.72 parts of the total width of the other two longitudinal ribs.

The compressive strength of such expanded clay concrete stones (380 mm wide, 380 mm long, 220 mm high) according to tests without deduction of voidness (50%) made by vibro-stamping reaches 75-100 grades with a stone bulk density of 700 kg / m ³ .

To further strengthen the walls and perceive local concentrated loads from beams, girders, etc. in places of their application, the carrying capacity is strengthened by filling the voids of the inner row with reinforced or unreinforced concrete. In addition, such reinforcement increases the load-bearing capacity and seismic resistance of the external walls in multi-story buildings. Half-hollows 7 at the ends of the stone are also used for fixing, sealing and warming window and door blocks by partially placing them inside the half-hollow.

Claims (4)

1. A building stone with a width of wall thickness, consisting of longitudinal ribs located across the heat flux and connecting bridges that form a hollow, characterized in that the outer and middle longitudinal ribs are connected by two bridges, the longitudinal axis of which is offset from the ends by a quarter of the length of the stone forming in the middle one void and half-empty at the ends on three sides, and the middle and inner longitudinal ribs are connected by four other jumpers in such a way that they form a gap in the middle, and along there are two identical voids at the ends, while the cross section of the two middle jumpers together with the gap between them is equal to the sum of the cross sections of two other jumpers located at the ends. 2. Building stone according to claim 1, characterized in that the width of the inner longitudinal ribs with respect to two other longitudinal ribs is at least 0.72 parts of their total latitude. 3. The building stone according to claim 1, characterized in that the outer longitudinal rib is shorter than the other two longitudinal ribs by the width of the vertical outer seam between the stones. 4. The building stone according to claim 1, characterized in that in the jumpers connecting the middle and inner longitudinal ribs and located at the ends, grooves are selected.