RU2546990C1 - Method of determination of deformation characteristics of protective tight shell - Google Patents

Abstract

FIELD: measurement equipment.

SUBSTANCE: method of determination of deformation characteristics of a protective tight shell consists in marking by pre-set sections of the protective tight shell of control points and execution of cycle-by-cycle identifications of their position. Control points are bound to geodetic field compilation points, the measurement information is analysed. The field compilation geodetic substantiation is formed as many-tier both outside of the structure, and inside it in the uniform coordinates system. This coordinates system is combined with the coordinates system of the protective tight shell, the studied points are places in moment, transitional, momentless zones of structural elements of the protective tight shell on its external and internal surfaces, monitoring of geometrical parameters is performed step by step.. During the monitoring the internal and external geometrical parameters of the protective tight shell are simultaneously determined at all stages of observations. Positions of the studied points placed in a momentless zone are determined with an accuracy providing reliable determination of the total expected maximum value of deformation of reinforcement bars.

EFFECT: improvement of accuracy of deformation measurements.

2 dwg

Description

The invention relates to the field of construction of nuclear power plants and, in particular, to the period of prestressing of hermetic protective shells of reactor compartments with a WWR-1000 reactor (1250, 1500).

A technical solution is known - a method for determining the deformation characteristics of structures (V. G. Kazachek, N. V. Nechaev, S. N. Notenko, V. I. Rimshin, A. G. Roitman. Inspection and testing of buildings and structures. - M. , Higher school, 2007, p.223-227), which consists in marking according to given sections of the construction of controlled points and performing cyclic definitions of their position, while one of the controlled points is tied to a geodetic benchmark, then the measurement information is analyzed.

The disadvantage of the described technical solution is that it does not take into account the features of constructive building solutions of the object, their physical properties and features of work during testing and operation and, as a result of this, the determination of complete and reliable information about the deformation characteristics of the object of study is not provided.

The closest technical solution to the claimed one is a method for determining the deformation characteristics of structures (Patent No. 2426089, G01M 99/00, publ. 08/10/2011, Bull. No. 22), which consists in marking the given points of the construction of controlled points and performing cyclic definitions of their position, at the same time, the controlled points are tied to the geodetic planning-high-altitude points, then they analyze the measurement information, while the multi-tier planning-high-altitude geodetic substantiation is preliminarily formed as outside the structure inside and inside it in a single coordinate system, and this coordinate system is combined with the coordinate system of the structure, then the studied points are marked, and they are placed in the moment zone of the building structures of the object under study with a step equal to about half the thickness of the given building structure, in the transition zone - with a step equal to approximately the thickness of the building structure, in the momentless zone - with a step equal to two or more thicknesses of the building structure, control of the external geometric parameters of the structure I perform it in stages, while controlling the position of points located on vertical building structures is determined by spatial polar notching, the positions of controlled points located on horizontal building elements are determined by geometric leveling, while the positions of the studied points located in the moment zone are determined ten times more precisely than the positions of the studied points located in the momentless zone, the positions of the studied points located in the transition zone, fissioning five times more accurately than the position of the test points, distributed in the area of the membrane, interior structures geometric parameters determined before and after carrying out all the steps to determine the outer geometry parameters.

The disadvantage of the described technical solution is that it does not provide a determination of the correlation of the strains of the internal and external geometric parameters of the protective hermetic shell, it does not provide a determination of the strains of the reinforcement located in the non-momentous zone of its building elements.

The task of the invention is the determination of complete and reliable information about the deformation characteristics of the object of study.

The essence of the invention lies in the fact that in the method for determining the deformation characteristics of a protective hermetic shell, which consists in marking the points according to the given sections of the protective hermetic shell and performing loop-by-loop definitions of their position, the controlled points are tied to geodetic planning-height points, then the measurement analysis is performed information, while the planning-high-altitude geodetic substantiation is formed by multilevel both outside the structure and inside it in a single system coordinate subject, moreover, this coordinate system is combined with the coordinate system of the protective hermetic shell, the studied points are placed in the momentary, transitional, momentless zones of the building elements of the protective hermetic shell on its external and internal surfaces, the geometric parameters are monitored in stages, according to the invention, the internal and the external geometric parameters of the protective hermetic shell are determined simultaneously at all stages of observation, while the measurements at each cycle e observations are performed twice, the first time immediately after the end of the previous stage of rope tension, the second immediately before the next stage of rope tension and, finally, before the sheath is tested for tightness and strength, while the positions of the studied points located in the momentless zone, determined with accuracy, ensuring reliable determination of the total expected maximum value of the deformation of the reinforcing bars, the positions of the studied points located in the moment and transition zones, op share with accuracy providing reliable determination of their cyclic movements.

The proposed technical solution of the method for determining the deformation characteristics of a protective hermetic shell provides a simultaneous determination of the displacements of the studied points located on the external and internal surfaces of the protective shell, thereby determining the parameters of the shape deformations of the internal and external surfaces, the comparison of which allows to determine the degree of their correlation, and, in addition, comparison of the displacement of controlled points located on the outer and inner sides of the shell wall in momentless zones and located in the same section, coinciding with the direction of the rod radial reinforcement, allows you to determine the magnitude of its deformation. This provides an increase in the completeness and reliability of information about the deformations of the building elements of the protective hermetic shell during its prestressing.

The invention is illustrated by drawings, where are given:

Figure 1 - diagram of the formation of the geodetic justification (view from the top).

Figure 2 - diagram of the geodetic justification (side view) and the placement of controlled points.

A method for determining the deformation characteristics of a protective hermetic shell when it is prestressed, which consists in preliminarily forming a multi-tiered planning-high-altitude geodetic justification both outside of building 1, 2, 3, and inside 4 of it in a single coordinate system, and the generated coordinate system is combined with the system coordinates of the structure. For the containment, the first stage 1 of the plan-height justification is formed outside the structure at a horizon close to construction zero. The second stage 2 of the external geodetic network is formed on the outbuilding of the reactor compartment in the form of a closed polygon, with four points located on the construction axes of the containment. The third stage 3 is formed on the support ring of the containment, here also four points are combined with its axes. Internal justification 4 is formed in the main hall (room GA-701) of the reactor compartment, here also four points are combined with its axes. The connection between the external geodetic network 1 and the internal 4 provides through the transport corridor of the containment zone. Marking according to given sections of the construction of the controlled points 5 is carried out in such a way that the points are placed and marked on the dome of the containment axial and half-inverted directions, and they are placed in the moment zone, the zone of direct adjacency to the support ring, with a step equal to about half the thickness of this building structures, in our case, half the thickness of the protective shell is 600 mm, such intervals, fixed by points 5 in each direction, mark two. Point 5 is placed in the transition zone with a step approximately equal to the thickness of the building structure, in our case 1200 mm, two intervals are marked with such intervals fixed by points in each direction. In the momentless zone, points are placed with a step equal to two or more thicknesses of the building structure, in our case 2500-3000 mm, thus, all the remaining parts of the controlled directions are broken. On the outer cylindrical part of the protective shell, the controlled points 5 are placed in vertical sections - coinciding with the axial sections, with a distribution step similar to the dome part, also counting from the support ring. On the inner part of the protective shell, the controlled points 5 are placed in sections uniformly distributed on the inner surface, and the internal geometrical parameters of the containment are determined before and after all the stages of control to determine the external geometrical parameters. The control of external geometric parameters is carried out in stages according to the program for creating excess pressure inside the containment. During the phased control of the external geometric parameters of the containment, the position of the controlled points 5 located on the cylindrical part in vertical sections is determined by the spatial polar notch, for example, with a Set 3030 R total station, the position of the controlled points 5 located on the dome part of the containment is determined by geometric leveling, for example Dini 03. Moreover, the positions of the studied points 5 located in the moment zone are determined ten times more accurately than the positions studied x points located in the momentless zone, the positions of the studied points 5, placed in the transition zone, determine five times more accurately than the positions of the studied points located in the momentless zone.

The proposed technical solution of the method for determining the deformation characteristics of a structure provides for dividing the surfaces of building structures into moment, transition and momentless zones, the magnitude of the recorded displacements of points in which are not the same. At the same time, performing phased measurements with an accuracy differentiated by these zones provides a reliable determination of the displacements of the studied points. This allows you to increase the reliability of obtaining the desired information.

Claims (1)

The method for determining the deformation characteristics of a protective hermetic shell, which consists in marking the points under control cross-sections of the hermetic protective shell and performing loop-by-loop definitions of their position, while the controlled points are tied to geodetic plan-altitude points, then analysis of measurement information is performed, while the plan-altitude geodetic the rationale is formed in multi-tier both outside the structure and inside it in a single coordinate system, and this coordinate system t is combined with the coordinate system of the protective hermetic shell, the test points are placed in the momentary, transitional, momentless zones of the building elements of the protective hermetic shell on its external and internal surfaces, the geometric parameters are controlled in stages, characterized in that the internal and external geometric parameters of the protective an airtight shell is determined simultaneously at all stages of the observation, while the measurements at each observation cycle are performed twice, the first time after the end of the previous stage of rope tension, the second immediately before the next stage of rope tension and, finally, before the shell begins to be tested for tightness and strength, while the positions of the test points located in the momentless zone are determined with an accuracy that ensures reliable determination of the total the expected maximum strain of the rod reinforcement, the positions of the studied points located in the moment and transition zones, are determined with accuracy, ensuring reliable determination of their cyclic movements.

Images