RU2240402C2 - Composed wall unit - Google Patents

Abstract

FIELD: building units, particularly combined elements and building envelopes.

SUBSTANCE: unit is made as parallelepiped frame having slot and extension of equal shapes and dimensions. Slot and extension are created on two parallel side walls. Side surfaces with slot and extension form masonry joint with interlock. Two other parallel side surfaces are outer and inner envelope surfaces. Closed heat insulation layers are arranged along frame height in central part and on peripheral parts thereof from inner side surfaces. Heat insulation layers are offset in opposite directions relative each other, extend towards lock beyond masonry joint and from ribs of equal thickness together with frame. Degree of heat insulation layers offset is selected in dependence of lock and heat insulation layer dimensions and is not more than 2/3 of lock height.

EFFECT: simplified structure and improved heat insulation properties, increased manufacturability and operational reliability, reduced labor inputs of wall unit mounting and decreased cost.

2 cl, 7 dwg

Description

The invention relates to the field of construction, namely to building materials, in particular, to finished components of the connection, and can be used in the manufacture of prefabricated elements and the device of building envelopes, for example walls, with the required thermal resistance for various operating conditions, as well as when creating internal architecture or layout of the internal space of buildings and structures for various purposes.

A wall block in the form of a parallelepiped is known, having a groove on the lower face, a crest corresponding to the shape on the upper side, and a groove and a comb, as well as two trapezoidal cavities in the longitudinal section, respectively. The block has semicircular hollows at the ends and on the upper face, and the voids are located along the lateral faces so that the base of the trapezoidal cavity along the face of the block is higher than the lower point of the semicircular hollow on the upper face and overlaps the base of the semicircular hollow on the end face. Moreover, the semicircular troughs at the ends and on the upper face are made at the same distance from the face of the block (see RF patent for invention No. 2024706, IPC E 04 C 1/00, publ. 15.12.1994).

A disadvantage of the known design of the wall block is the uneven distribution of the insulating layer along the width of the wall, which reduces the heat-insulating properties of the wall block. In addition, the design of the wall block complicates the technology of wall mounting, since the blocks are first connected to each other, and then the voids formed are filled with heat-insulating material.

A thermoblock is known that contains a rigid spatial structural element — a matrix with a built-in thermal diaphragm, which is made with structural cutouts in such a way that 68–70% of the perimeter of the thermal diaphragm extends in the plane of the interface joints, quarters are made in the matrix body for laying thermal liners that eliminate heat losses in the process of building assembly of thermoblocks. On the end surfaces of the matrix, grooves are provided with their vertical displacement in adjacent rows for filling with mounting solution. The fuser is reinforced for use as a bearing element of the span in an upside-down position at 180 ° (see RF patent for invention No. 2157875, IPC E 04 C 1/00, B 28 V 7/22, publ. 10/20/2000).

A disadvantage of the known thermal block is the complexity of its manufacture, which consists in the preliminary manufacture of the thermal diaphragm, fixing it in the molding cavity, imparting spatial rigidity to the structure by reinforcing the supporting elements of the spans, pouring the cavity with concrete, compacting it and aligning it. After the concrete has hardened, it is necessary to remove auxiliary elements from the device and expose the block to exposure and heat treatment.

In the known design of the fuser, the connecting grooves are made along its outer perimeter, part of the grooves during masonry are filled with masonry mortar, which leads to the formation of "cold bridges" in the joints of the connection and reduces the thermal resistance of the wall in these areas. Placing a thermal diaphragm along the outer perimeter of the block leads to the formation of condensate at the interface (i.e. materials with different thermal conductivity), which requires additional protection of the enclosure at the junction of the blocks. In addition, the need for separate manufacture of a thermal diaphragm and thermal liners leads to a higher cost of production for the manufacture of finished blocks.

The closest technical solution to the claimed is a well-known combined building block representing a cathedral frame with at least one through heat-insulating layer located along the height of the frame in its central part, while the frame is made in the form of a parallelepiped, in which two parallel side surfaces are made with the same shape and size of the groove and protrusion that form the castle, and two other parallel side surfaces form the outer and inner walls of the fence (see German patent uu on № 19952072 invention, FIG. 1, IPC E 04 C 1/41, publ. 09.08.2001 g).

The insulating layer is prepared by foaming the components of the mass of the insulating layer between the external elements and additional forms. The outer casing has a groove at least on the lower edge, and a ridge corresponding in shape to the upper edge. In another embodiment, the construction combined block additionally has depressions and corresponding protrusions on the lateral faces of the outer casing for connecting two adjacent buildings and forming a single building block.

A disadvantage of the known combined building block is the uneven distribution of the insulating layer over the surface of the structural element, which leads to the formation of "cold bridges" in the joints of the blocks and between the insulating layers. This reduces the thermal insulation characteristics of the fence. In addition, in the known construction of the building block, condensation may form at the media interface, since the heat-insulating layer extends to the outer side surface of the block, as well as the complexity of the manufacturing process of the block.

The problem to which the claimed invention is directed is to simplify the design of the wall block and improve its heat-insulating properties, increase the manufacturability and operational reliability of the wall block, reduce the complexity of installation, as well as reduce its cost by reducing the material consumption and the complexity of its manufacture.

The technical result achieved by solving the task is to optimize the relative position of the insulating layers and frame elements, as well as the ratio of their sizes.

The problem is achieved in that in the known wall block combined, which is a frame with heat-insulating layers located in its central part located along the height of the frame, while the frame is made in the form of a parallelepiped, in which two parallel side surfaces are made with the same shape and size a groove and a protrusion forming a castle, and two other parallel side surfaces of which are the outer and inner walls of the fence, according to the invention, on the peripheral parts In addition to the frame, heat-insulating layers are located on the inner side of the side surfaces, which are the outer and inner walls of the fence, while the central and peripheral heat-insulating layers are displaced in opposite directions relative to each other towards the castle outside the masonry joint and form ribs of the same thickness with the frame.

It is advisable that the amount of displacement of the insulating layers is at least 2/3 of the height of the castle.

The presence of additional heat-insulating layers, the shape and location of the central and peripheral heat-insulating layers along the cross-sectional area of the frame allows the labyrinth to be formed when assembling the wall from the claimed blocks, for air to pass in any of the sections of the fence parallel to the direction of the heat flow, which provides thermal insulation in the joints of the blocks and increases the thermal resistance of the fence. Placing heat-insulating openings in the inner space of the block frame eliminates the formation of condensate in heat-insulating openings. The distribution of heat-insulating blocks over the cross-section of the frame and the formation of frame ribs of the same thickness allows blocks with equal values of the total areas of the heat-insulating layers and the frame, thereby achieving a uniform distribution of thermal resistance over the cross-sectional area. This allows you to withstand the thermal parameters specified by building codes and rules (SNiP) of the building envelope.

The design of the combined wall unit is shown in the drawings, where Fig. 1 shows the main combined wall unit, a transverse section; figure 2-4 are examples of the execution of the block end combined, a cross section; figure 5 is an example of a masonry fence, vertical view; figure 6 is an example of a masonry fencing, view in plan; Fig.7 is an example of the implementation of the corner block, a cross section.

Positions in the drawings indicate the following: 1 - frame; 2 and 3 - side surfaces of the frame 1, forming a masonry seam; 4 - a groove on the side surface 2 of the frame 1; 5 - protrusion on the side surface 3 of the frame 1; 6 - masonry seam of the fence; 7 - the lock formed by the groove 4 and the protrusion 5 when laying the fence; 8 and 9 - side surfaces of the frame 1, forming the outer and inner walls of the fence; 10 - insulating layers located in the Central part of the frame 1; 11 - heat-insulating openings located in the peripheral parts of the frame 1; 12 - ribs of the frame 1; 13 - the first row of the fence; 14 - the second row of the fence.

In figures 1 and 5, the following notation: N - the height of the castle 7; h is the displacement value of the insulating layers 10 and 11; B is the width of the wall block.

The combined wall block is a frame 1 in the form of a parallelepiped, in which on two parallel side surfaces 2 and 3 the groove 4 and the protrusion 5 are made in the same shape and size. The side surfaces 2 and 3 with the groove 4 and the protrusion 5 form a masonry seam when laying the fence 6 with lock 7. Two other parallel side surfaces 8 and 9 are the outer and inner walls of the fence.

Along the height of the frame 1, closed heat-insulating layers 10 are located in its central part, and closed heat-insulating layers 11 are located on the peripheral parts from the inner side of the side surfaces 8 and 9. In this case, the heat-insulating layers 10 and 11 are shifted in opposite directions relative to each other towards the lock 7 beyond the masonry seam 6 and form with the frame 1 ribs 12 of the same thickness. The amount of displacement h is selected depending on the size of the lock and heat-insulating layers 10 and 11 and is at least 2/3 of the height H of the lock 7. The limitation of the amount of displacement is due to the fact that when it changes, the thickness of the ribs 12 of the frame 1 is violated (Fig. 1) .

To complete the row of fencing use end semi-blocks of various configurations (Fig.2-4).

The manufacture of building envelopes of buildings, for example walls, with the required thermal resistance for various operating conditions from individual wall blocks is as follows.

When installing the first row 13 of the fence, the protrusion 5 of one block enters the groove 4 of the other block, as a result of which the individual wall blocks are connected in one row (Figs. 5 and 6).

When laying the next height row 14 of the fence, the first block of the next row is shifted by half the width of the block of the previous row to exclude "cold bridges" along the height of the fence (Fig. 5). This increases and evenly distributes the value of heat transfer resistances over the wall volume.

Installation of wall blocks is as follows.

The masonry starts from the corner of the building with the corner block (Fig. 7), which has a special shape that allows you to pair the blocks in a mutually perpendicular direction without creating "cold bridges" at the seams. For this, a piece of the peripheral part is removed from the wall block adjacent to the corner block perpendicularly. The joining of the internal partitions with the main wall is carried out using fasteners (not shown). When laying mutually perpendicular walls to exclude a through seam in the corners at the end half block and the block docked with it, one of the peripheral parts adjacent to the perpendicular wall is removed, which creates an additional heat-insulating labyrinth in the corner masonry seam. The laying of the perpendicular wall is carried out with a shift by the size of the remote section of the docked block (Fig.6).

The inventive design of the wall block of the combined frame allows the assembly of the wall to form a labyrinth for air to pass in any of the sections of the fence parallel to the direction of the heat flow, which provides thermal insulation in the joints of the blocks and increases the thermal resistance of the fence.

In addition, this makes it possible to carry out blocks with equal values of the total areas of the heat-insulating layers and the frame, thereby achieving a uniform distribution of thermal resistance over the cross-sectional area. This allows you to withstand the thermal parameters specified by the Building Code and Rules (SNiP) of the building envelope.

Claims (2)

1. The combined wall block, which is a frame with heat-insulating layers located in its central part, located along the height of the frame, the frame is made in the form of a parallelepiped, in which two parallel side surfaces are made with the same shape and size of the groove and protrusion that form the castle , and two other parallel side surfaces of which are the outer and inner walls of the fence, characterized in that on the peripheral parts of the frame additionally made insulating layers located on the inner side of the side surfaces, which are the outer and inner walls of the enclosure, while the central and peripheral heat-insulating layers are shifted in opposite directions relative to each other towards the castle outside the masonry seam and form ribs of the same thickness with the frame. 2. The wall block according to claim 1, characterized in that the displacement of the insulating layers was at least 2/3 of the height of the castle.

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