RU181353U1 - FENDING DESIGN - Google Patents

Abstract

Usage: the utility model relates to the field of construction and can be used in the construction of external, internal walls, partitions, fences, basement walls for a cottage, multi-storey monolithic-frame, precast-monolithic or prefabricated construction, construction of residential and public buildings. In particular, the claimed design is intended for the construction of durable, warm, soundproof walls of buildings with a front decorative surface of the facade. Effect: increasing the reliability and heat-shielding properties of the building envelope while reducing the number of flexible connections between its elements. Essence: the enclosing structure is made in the form of a multilayer hollow enlarged element consisting of an outer and inner layer with a fixed distance between them and filled with structural and heat-insulating materials, while the outer and inner layers in turn consist of stacking modules formed by rigid fixation in the factory conditions of hollow block-shaped form with an open circuit on one side with a voidness of at least 67%, while laying modules, the outer and inner layers The enlarged structural element is interconnected by composite flexible connections. 1 ill.

Description

Technical field

The utility model relates to the field of construction and can be used in the construction of external, internal walls, partitions, fences, basement walls for a cottage, multi-storey monolithic-frame, precast monolithic or prefabricated construction, construction of residential and public buildings. In particular, the claimed design is intended for the construction of durable, warm, soundproof walls of buildings with a front decorative surface of the facade.

State of the art

The prior art solutions that allow you to build structures with hollow walls. So known facing-building system disclosed in patent document RU 144780 U1, published on 08.27.2014. The well-known building system is a hollow structure filled with concrete, mortar or backfill with insulating materials with internal and external walls, between which there is a fixed distance. Moreover, the walls of the building system are made up of blocks with a cavity inside, while the blocks and walls are interconnected by clamps, clamps and / or nets, and / or individual rods of steel wire or other materials similar in properties are used for reinforcement, and in as a filler in the cavities of the construction, heat-insulating lightweight or cellular concrete was used, or backfilling with heat-insulating materials. The specified design is selected as the closest analogue of the claimed solution.

A disadvantage of the known construction is the use of clamps, grids and individual rods of steel wire as wall reinforcement. Due to the high thermal conductivity of steel, the use of these products leads to the loss of heat-shielding properties of the wall structure and the formation of so-called cold bridges. The presence of temperature bridges significantly reduces the effectiveness of thermal protection of the building. In addition, temperature bridges cause condensation to form at the reinforcement points, while the steel reinforcement elements will corrode, thereby reducing the structural strength and reliability of the enclosing structure. In addition, the disadvantage of the system is a significant number of multiple operations to connect and fasten the ends of each of the blocks with U-shaped, H-shaped clamps and clamps, which leads to the use of a large number of steel ties in the claimed design.

Task and technical result

The objective and technical result of the claimed utility model is to increase the reliability and heat-shielding properties of the building envelope while reducing the number of flexible connections between its elements.

Disclosure and essence of utility model

-образной формы с открытым по одной стороне контуром с пустотностью не менее 67%, при этом укладочные модули, наружный и внутренний слои укрупненного элемента конструкции соединены между собой композитными гибкими связями.The problem is solved, and the required technical result when using the utility model is achieved by the fact that the enclosing structure is made in the form of a multilayer hollow enlarged element consisting of an outer and inner layer with a fixed distance between them and filled with structural and heat-insulating materials, while the outer and inner layers in turn, consist of stacking modules formed by rigid fixation of hollow blocks in the factory

-shaped with an open circuit on one side with a voidness of at least 67%, while the stacking modules, the outer and inner layers of the enlarged structural element are interconnected by composite flexible connections.

The essence of the utility model is illustrated in FIG. 1, which shows the following structural elements:

1 - laying module;

2 - a cavity filled with concrete, mortar or insulating material;

3 - flexible polymer composite bonds;

-образную форму за счет формирования открытого (разомкнутого) по одной стороне контура. Кроме этого, пустотелые блоки имеют пустотность не менее 67%. Пустотелые блоки жестко сцепляются между собой в модули в заводских условиях. При этом укладочные модули 1 могут состоять из 2-х или более жестко смонтированных между собой пустотелых блоков

-образной формы с открытым по одной стороне контуром. Указанные укладочные модули 1 монтируют в ряд и скрепляют между собой композитными фиксаторами. Таким образом, формируют первый ряд наружного слоя. Далее параллельно ему на фиксированном требуемом расстоянии укладывают подобный ряд внутреннего слоя ограждающей конструкции. При этом пустотелые блоки наружного и внутреннего слоя ограждающей конструкции размещают при установке разомкнутой стороной напротив друг друга. Внутренние части обоих слоев скрепляют между собой при помощи композитных гибких связей (гибкие связи периодического профиля из полимерного композита). Следующий ряд укладочных модулей 1 устанавливают на предыдущий ряд сверху с перевязкой в шахматном порядке. Композитные гибкие связи, соединяющие наружную и внутреннюю слои ограждающей конструкции, устанавливают только в местах скрепления укладочных модулей между собой. Далее производится заливка пустот ограждающей конструкции, например, бетоном или пенобетоном, или полистиролбетоном или раствором послойно через каждый метр по высоте конструкции. При этом в результате разомкнутого контура блоков заполнение бетоном или раствором происходит по всей ограждающей конструкции одновременно. Таким образом, заполнение пустот осуществляют при помощи конструкционно-теплоизоляционных материалов.As follows from FIG. 1, the claimed enclosing structure is a multilayer hollow enlarged element, which consists of an outer and inner layer with a fixed distance between them. The outer and inner layers are formed from stacking modules 1. Laying modules 1 are hollow blocks rigidly mounted between each other. At the same time, hollow blocks have

-shaped form due to the formation of open (open) on one side of the circuit. In addition, hollow blocks have a voidness of at least 67%. Hollow blocks are rigidly interlocked in modules in the factory. In this case, the laying modules 1 may consist of 2 or more rigidly mounted interconnected hollow blocks

-shaped with an open contour on one side. These stacking modules 1 are mounted in a row and fastened together by composite clamps. Thus, the first row of the outer layer is formed. Then parallel to it at a fixed required distance lay a similar row of the inner layer of the building envelope. In this case, the hollow blocks of the outer and inner layers of the building envelope are placed when installed with the open side opposite each other. The inner parts of both layers are bonded together using composite flexible bonds (flexible bonds of a periodic profile made of a polymer composite). The next row of stacking modules 1 is installed on the previous row from above with dressing staggered. Composite flexible connections connecting the outer and inner layers of the building envelope are installed only at the places where the stacking modules are fastened together. Further, the voids of the enclosing structure are filled, for example, with concrete or foam concrete, or polystyrene concrete or mortar, in layers every meter over the height of the structure. In this case, as a result of the open circuit of the blocks, the filling with concrete or mortar occurs simultaneously throughout the entire building envelope. Thus, the filling of voids is carried out using structural heat-insulating materials.

In this case, heat-insulating concrete, for example, polystyrene concrete, perlite concrete, or sioporbeton, or gypsum perlite concrete, or foam concrete, or aerated concrete, or cellular concrete or other concrete or mortars, can be used.

In places of interfacing with reinforced concrete columns or pylons, polystyrene boards or their analogues can be used as heat-insulating material.

The use of stacking modules according to the claimed solution allows to save assembly time, reduces labor costs, reduces the number of flexible connections used to fasten the blocks. At the same time, the use of composite polymer flexible connections allows to increase the heat-shielding properties of external fencing in comparison with the prototype due to the absence of heat loss.

Thus, due to the use of the claimed device of the enclosing structure, the required technical result is achieved, namely, the reliability of the enclosing structure and its heat-shielding properties are increased. At the same time, the number of flexible connections between its structural elements decreases.

Given the novelty of the set of essential features, the technical solution of the problem, the materiality of all general and particular features of the utility model, proven in the section "prior art" and "Disclosure and the essence of the utility model", proven in the section "Implementation and industrial implementation of the utility model" technical feasibility and the industrial applicability of the utility model, the solution of tasks and the confident achievement of the required technical result in the implementation and use of the utility model, in our opinion neniyu, the claimed solution meets all the requirements for eligibility requirements for utility models.

The analysis also shows that all the general and particular features of the utility model are essential, since each of them is necessary, and all together they are not only sufficient to achieve the goal of the utility model, but also allow it to be implemented in an industrial way.

Claims (1)

The enclosing structure, made in the form of a multilayer hollow enlarged element, consisting of the outer and inner layers with a fixed distance between them and filled with structural heat-insulating materials, characterized in that the outer and inner layers, in turn, consist of stacking modules formed by rigid fixation in factory conditions of hollow blocks

-shaped with an open circuit on one side with a voidness of at least 67%, while the stacking modules, the outer and inner layers of the enlarged structural element are interconnected by composite flexible connections.

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