RU84874U1 - COMBINED SPATIAL REINFORCED CONCRETE BASE - Google Patents

Abstract

1. Prefabricated spatial reinforced concrete foundation, created from prefabricated panel elements, prestressed and / or without prestressing, having a closed circuit at least in one of the sections, connected into a single structure using concrete keys, and / or welding the worker, and / or auxiliary reinforcement of elements, and / or reinforcing inserts, and / or metal inserts, and / or embedded parts, and / or monoling additional reinforcing bars, and / or tapes of any material, and / or metal in tavok and their further comprising compulsory concrete shelter layer having a thickness of at least a protective layer of concrete of appropriate constructs. ! 2. Prefabricated spatial reinforced concrete foundation according to claim 1, characterized in that the reinforcement of prefabricated panels and foundation elements can be made using tapes and / or reinforcement made of composite, and / or composite, and / or synthetic, and / or carbon, and / or aramid, and / or glass, and / or coal, and / or Kevlar, and / or various types of high molecular weight materials or their analogues, can be performed with any combination of transverse, and / or inclined at any angle, and / or longitudinal reinforcement completed and h of these materials and / or metal elements.

Description

The utility model relates to technical circumstances in which it is necessary to increase the reliability, bearing capacity and spatial stiffness of foundations, increase reliability and durability while ensuring a rational consumption of materials and reducing labor costs, if it is possible to industrialize the manufacture of its components of prefabricated panel elements.

Scope - construction.

It is known that with uneven precipitation of the foundation, its bending occurs, that is, a stress state in which the extreme zones of the cross section work most effectively, in which the maximum compression or tension occurs. This circumstance, as a physical fact, prompted in due time to create spatial monolithic reinforced concrete foundations, by analogy with the idea of creating multi-hollow reinforced concrete slabs, when the main mass of concrete was sought to concentrate near the upper and lower edges of the cross section, removing it from the middle part of the structural section. Thus, the efficiency of using construction materials in the extreme zones of the cross section increased, and at the same time, the shoulder of the inner pair of forces increased. A natural property of such structures is a closed loop along at least one of the cross sections, since only in this case it is technically possible to ensure the presence of upper and lower flat layers located at a maximum distance in the structural cross section. Thus, this property is a characteristic or peculiar hint when designing optimal designs.

Another fact is also known that prefabricated panel housing construction is the most progressive and high-quality method of construction, providing relatively comfortable conditions for workers and a stable quality of manufactured products.

The proposed idea of creating spatial reinforced concrete foundations from panel elements allows to improve the functional characteristics of the foundation: to increase the spatial rigidity, increase the load transfer area and, accordingly, reduce the specific pressure on the ground. In addition, this technical solution allows to reduce the specific consumption of materials and labor, which is the basis of economic efficiency while improving functional characteristics. Thus, optimal conditions are created for creating structures that have the best price / quality ratio.

The problem of ensuring durability, one of the main when creating foundations, and its solution involves: protecting concrete and reinforcement of structures from corrosion and eliminating the possibility of contact of reinforcement with a moist and (or) aggressive environment at the joints, which initiated the author to create options for the corresponding nodes for connecting these prefabricated foundation panel structures (in this utility model, concrete, developed joint options are not presented). In this application, when analyzing nodal connections, only one of the basic principles for creating reliable structures is taken into account, according to which when connecting panel elements it is necessary to provide for the principle of equal strength (for example, to eliminate the presence of weak links in the connection nodes). In this case, the nodal connection itself can be performed in various ways, such as using concrete keys and / or welding working and / or auxiliary reinforcing elements and / or reinforcing inserts and / or metal inserts and / or embedded parts and / or monoling additional reinforcing bars and / or tapes of any high-strength material and / or metal inserts and provide for their mandatory further covering with a layer of concrete having a thickness of not less than the protective layer of concrete of the corresponding structures. Any of the listed connection options can, with the correct design solution and appropriate calculation, satisfy the principle of equal strength and, therefore, will give the same technical result within the framework of the stated idea. The choice of a solution is determined by local conditions, the convenience of practical implementation, the economy and the appropriate engineering rationale.

Application for reinforcing prefabricated panels and foundation elements of tapes and (or) reinforcement from composite and (or) composite and (or) synthetic and (or) carbon and (or) aramid and (or) glass and (or) coal and (or) Kevlar and (or) various types of high molecular weight materials or their analogues can significantly increase their reliability and durability. The types of materials listed above have a common property - high modulus of elasticity (exceeding the modulus of elasticity of metal reinforcement) and strength. As a result, the proposed alternative to their use gives the same technical result, since at the moment concrete reaches the ultimate tensile strength, these materials have a significantly higher voltage than metal reinforcement. The angle of the reinforcing materials is determined by the calculation of the acting forces and the corresponding engineering justification and, therefore, also does not have any effect on the claimed technical result. The fact of the presence or absence of prestressing reinforcing materials also does not in any way change the circumstances considered above.

Preload stress, in accordance with the fundamentals of the theory of reinforced concrete, affects the deformability and crack resistance of these panels, therefore, the creation of prestress in the manufacture of panels completing the foundation does not change the claimed technical result in comparison with the option to create these panels without prestressing. The use of prestressing in accordance with the fundamentals of the theory of reinforced concrete is advisable in the case of the creation of either large-sized panels, or the implementation of the task of reducing their deformability and / or increasing crack resistance. The choice in favor of the implementation of a particular option is determined by local conditions, the availability of special equipment and appropriate engineering justification.

The closest in technical essence to the invention is a spatial foundation platform, adopted as a prototype [copyright certificate for the invention No. 2206665 from 2003.06.20]. The main feature of the analogue, which coincides with the essential features of the claimed model, is the spatial work of the upper and lower precast concrete slabs.

The disadvantage of the prototype is the use of open metal structures and welded joints to create the spatial rigidity of the foundation, which during the operation of the structure will inevitably undergo corrosion, which in turn will affect the reliability and durability of the foundation and structure.

The essence of the utility model is expressed by the following features:

1. The use of precast concrete panels to create the spatial rigidity of the foundation.

2. The metal contact of the supporting structures and nodal joints with the environment is excluded.

3. Maintainability and the possibility of reinforcement, expressed in the fact that, if necessary, it is possible to perform an increase in sections or additional reinforcement of almost all the elements of the foundation.

4. The ability to carry out preliminary special processing of these elements during their manufacture and, above all, the bottom surface of the base plate, which will subsequently come into contact with the soil (with a monolithic version of the manufacture of the foundation, it is either impossible or extremely difficult to do).

5. To avoid corrosion and to increase durability, it is proposed, as an option, to use for reinforcing prefabricated panels and foundation elements tapes and (or) reinforcement made of composite and (or) composite and (or) synthetic and (or) carbon and (or) aramid and (or) glass and (or) coal and (or) Kevlar and (or) various types of high molecular materials or their analogues, which can be performed with any combination of transverse and (or) inclined at any angle and (or) longitudinal reinforcement, made from data materials and metallic elements.

The objective of the utility model and at the same time its expected technical result is the creation of economical, prefabricated, panel spatial foundations, increasing their reliability and durability, ensuring the technical possibility of their maintainability and the possibility of strengthening during operation or when changing existing loads.

An essential feature of the utility model is the prefabricated panel principle of creating a spatial foundation while excluding the metal contact of the supporting structures and nodal joints with the environment.

Features characterizing a utility model

1. Prefabricated spatial reinforced concrete foundation is created by a single structure of panel elements by connecting them using concrete keys and / or welding working and / or auxiliary reinforcement of elements and / or reinforcing inserts and / or metal inserts and / or embedded parts and / or monoling additional reinforcing bars and / or metal inserts and providing for their mandatory further shelter with a layer of concrete having a thickness of not less than the protective layer of concrete of appropriate design uktion.

2. Use, as an option, for reinforcing prefabricated panels and foundation elements of tapes and (or) reinforcement from composite and (or) composite and (or) synthetic and (or) carbon and (or) aramid and (or) glass and (or ) coal and (or) Kevlar and (or) various types of high molecular materials or their analogues, which can be performed with any combination of transverse and (or) inclined at any angle and (or) longitudinal reinforcement made of these materials and / or metal elements.

3. Contact of metal reinforcement of structures and metal reinforcement of butt joints with the external environment is excluded.

4. Panel elements of prefabricated spatial reinforced concrete foundations are made prestressed and / or without prestressing.

5. The prefabricated spatial reinforced concrete foundation has a closed loop in the cross section of at least one of the cross sections. Figure 1 shows a variant of the fundamental solution of the utility model.

Utility Model Implementation

The proposed prefabricated spatial reinforced concrete foundation is, in fact, an offer of panel housing construction of foundations, subject to careful shelter of metal structures and joints from contact with the external environment.

Separate panel elements are either pre-stressed or non-prestressed. In the places of the future connection of the elements, reinforcement releases and (or) embedded parts are provided, corresponding grooves or recesses and (or) the conditions for forming angular concrete slopes are provided for the subsequent reliable shelter of the reinforcement and (or) metal inserts from the influence of the external environment.

It is advisable to pre-treat the structures with special compounds to ensure moisture and water protection and (or) water resistance.

Assembly is carried out by welding and (or) monolinging connecting rods and (or) metal inserts. The butt joints and embedded parts are closed with a layer of non-shrinking or expanding cement or their analogues with a thickness not less than the thickness of the protective layer of concrete structures. For monolithic joints and for the manufacture of structures of the lower layer, it is especially desirable to use fiber-reinforced concrete or any other type of concrete having increased resistance and deformation characteristics under the influence of tensile forces.

To ensure reliable joint operation of concrete and tapes and (or) reinforcement from composite and (or) composite and (or) synthetic and (or) carbon and (or) aramid and (or) glass and (or) coal and (or) Kevlar and (or) various types of high molecular weight materials or their analogues, the ends of these tapes and (or) fittings are anchored and (or) wrapped and (or) attached to rods transverse to them in the upper and lower planes of the plates. To provide this connection of tapes and (or) reinforcement, as an option, a knitting wire can be used.

Claims (2)

1. Prefabricated spatial reinforced concrete foundation, created from prefabricated panel elements, prestressed and / or without prestressing, having a closed circuit at least in one of the sections, connected into a single structure using concrete keys, and / or welding the worker, and / or auxiliary reinforcement of elements, and / or reinforcing inserts, and / or metal inserts, and / or embedded parts, and / or monoling additional reinforcing bars, and / or tapes of any material, and / or metal in tavok and their further comprising compulsory concrete shelter layer having a thickness of at least a protective layer of concrete of appropriate constructs. 2. Prefabricated spatial reinforced concrete foundation according to claim 1, characterized in that the reinforcement of prefabricated panels and foundation elements can be made using tapes and / or reinforcement made of composite, and / or composite, and / or synthetic, and / or carbon, and / or aramid, and / or glass, and / or coal, and / or Kevlar, and / or various types of high molecular weight materials or their analogues, can be performed with any combination of transverse, and / or inclined at any angle, and / or longitudinal reinforcement completed and h of these materials and / or metal elements.