RU2282847C2 - Method to determine fire-resistance of faced metal columns of building - Google Patents

Abstract

FIELD: fire fighting, particularly to provide fire safety of buildings and building structures.

SUBSTANCE: method to perform tension member tests without member destructing to determine simple quality indicia and to estimate indicia values by means of static check involves determining metal column dimensions, pattern of weak column sections heating during fire, column end fastening conditions, density, humidity and thermal diffusion indicia of facing material, as well as basic load values in weak sections of load-bearing column rods; determining fire-resistance rating of columns from nomographic chart.

EFFECT: increased reliability and reduced costs of static check and non-destructive test.

15 cl, 2 dwg, 1 tbl

Description

The invention relates to the field of fire safety of buildings and structures, further - buildings. In particular, it can be used to classify metal structures of buildings according to their resistance to fire. This makes it possible to justify the use of lined metal columns with an actual fire resistance limit in buildings of various categories for their fire hazard.

The need to determine the fire resistance of metal columns arises during the reconstruction of a building, strengthening its parts and elements, bringing the fire resistance of the columns in accordance with the requirements of modern building standards, during the examination and / or restoration of building structures after a fire.

A known method for determining the fire resistance of metal columns of a building according to the results of a study of the consequences of a natural fire. This method includes determining the position of the structure in the building, assessing the state of the structure by inspection and measurement, making control steel samples, determining the time of the onset of the limit state by the loss of the bearing capacity of the structure, that is, collapse under conditions of external load and the thermal effect of a natural fire (Ilyin N .A. Consequences of the fire effect on reinforced concrete structures. - M.: Stroyizdat, 1979. - P.34-35; 90) [1].

The reasons that impede the achievement of the following technical result when using the known method include the fact that in the known method, the fire resistance limits are determined approximately by the results of a study of the consequences of a past fire. A detailed study determines the long-term work of an expert. At the same time, it is impossible to determine the fire resistance of full-scale structures having other sizes and other external loads. It is difficult to compare the results with standard fire tests of similar designs. Therefore, this method is expensive, has little technological ability to re-test, time-consuming and dangerous for testers.

There is a method of evaluating the fire resistance of metal columns according to the results of full-scale fire tests of a building fragment in which the structures are inspected, the steel grade is determined, the static load on the structure is assigned in accordance with the actual operating conditions of the building, the factors affecting the fire resistance of the tested structure are determined, and the fire resistance limit (NPB) 233-97 Buildings and fragments of buildings - The method of full-scale fire tests - General requirements - M .: VNIIPO, 1997. - S.6-12) [2].

The reasons that impede the achievement of the following technical result when using the known method include the fact that in the known method there are high economic costs for conducting fire tests, monitoring the state of structures in an experimental fire is difficult and unsafe, due to differences in the thermal regime of the experimental and standard fires determination of the true values of the fire resistance limits of structures, the causes of the destruction of the metal columns of the fragment may not be established Lena due manifold fire simultaneously operating factors. The ultimate fire resistance of lined metal columns may not be reached due to earlier destruction of the coating elements or fragment walls (Fire resistance of buildings. V.P. Bushev, V.A. Pchelintsev, BCFedorenko, A.I. Yakovlev. - M. : Stroyizdat, 1970. - S.252-256) [3].

The closest method of the same purpose to the claimed invention by a combination of features is a method for determining the fire resistance of clad metal columns of a building by testing, including conducting a technical inspection, establishing the grade of steel and the type of material of the lining, identifying the conditions of support and fastening of the ends of the columns, determining the time of the onset of the limiting state by a sign of loss of the bearing capacity of the structure under standard load under standard thermal exposure. (GOST 30247.1-94. Building structures. Fire test methods. Bearing and enclosing structures. - M .: Publishing house of standards, 1995. - 7 p.) [4] - adopted as a prototype.

The reasons that impede the achievement of the technical result indicated below when using the known method adopted as a prototype include the fact that in the known method the tests are carried out on a design sample that is subjected to constant and continuous loads in their calculated values with a safety factor equal to one, then There are design regulatory loads.

Tests are carried out on special bench equipment in fire furnaces until the destruction of structural samples. The size of the samples is limited depending on the openings of stationary furnaces. Consequently, standard fire tests are laborious, not effective, not safe, have little technological capabilities for testing various sizes and variously loaded structures, and do not provide the necessary information about the effect of individual structural quality indicators on its fire resistance. Determination of the fire resistance of clad metal columns by a single quality indicator, for example, by the thickness of the cladding, as a rule, underestimates the suitability of the structure in a building with a given degree of fire resistance. The economic costs of testing increase due to the costs of dismantling the columns, transportation to the installation site of the heating furnaces and the creation of a standard thermal regime in them. By a small number of tested samples (2-3 pcs.) It is impossible to judge the actual condition of the columns of the building. The results of the fire test are sporadic and do not take into account the diversity in fixing the ends of the columns, their actual dimensions, the actual scheme of heating the dangerous section of the test structure in a fire.

The invention consists in the following. The problem to which the claimed invention is directed is to establish fire safety indicators of a building in terms of the guaranteed duration of resistance of metal structures in a fire; in determining the actual fire resistance limits of lined metal columns during the design, construction and / or operation of a building; in reducing economic costs when testing structures for fire resistance.

EFFECT: elimination of fire tests of a structure in a building or its fragment; reducing the complexity of determining the fire resistance of structures; expanding the technological capabilities of determining the actual fire resistance of variously loaded structures of any size and the possibility of comparing the results with tests of similar building structures; the ability to test structures for fire resistance without disturbing the functional process in the building; reduction in economic costs of testing; maintaining the serviceability of the building during inspection and non-destructive testing of structures; simplification of conditions and reduction of the test time of structures for fire resistance; the use of nomograms to determine the fire resistance of structures; increased accuracy and expressiveness of the test; getting the opportunity to solve the inverse problems of fire resistance of structures and using the method of selection of variable values of its structural parameters; the use of integral structural parameters to determine the fire resistance of structures and simplification of the mathematical description of the process of thermal resistance of loaded structures; increasing the reliability of the test results of a group of similar designs; accounting for the real resource of the design for fire resistance using a set of individual indicators of their qualities; increasing the reliability of determining the thickness of the facing coating and the heating conditions of the supporting rod of the column in a fire; clarification of individual quality indicators of structures that affect their fire resistance, and determination of the minimum number of tests; reducing the sample of tested structures to a minimum, ensuring sufficient reliability of the test results; the ability to determine the guaranteed fire resistance of a compressed steel element according to its design parameters.

The specified technical result during the implementation of the invention is achieved by the fact that in the known method for determining the fire resistance of clad metal columns of a building by testing, including technical inspection, determining the type of facing material, steel grade of the supporting rod of metal columns, identifying the conditions for their support and fastening, determining the time of the limit conditions on the basis of loss of bearing capacity of columns under standard load in conditions of standard heat action, the feature is that the test of metal columns is carried out without destruction on a set of individual quality indicators of the materials of the cladding and steel of the supporting rods of the metal columns, determine the number and location of sections in which the quality indicators are determined, technical inspection is supplemented by instrumental measurements of the geometric dimensions of the cladding and bearing rods of metal columns, establish the cross-sectional area of the bearing rods of metal columns in dangerous sections, identify patterns heating them in case of fire, experimentally determine the density of the cladding materials and their moisture content in the natural state and / or the value of the coefficient of thermal diffusion of the cladding material, find the ultimate resistance of steel to compression, set the standard working load on the columns and the value of the intensity of power stresses in dangerous sections and using the obtained integral parameters of the lined metal columns - D _ar - coefficient of thermal diffusion of the material of the insulating coating, mm ² / min; δ _about - the minimum thickness of the insulation coating of the column, mm; m _o - an indicator of the heating conditions in a fire bearing rod of metal columns with an insulating coating; J _σs is the intensity of normal stresses in the cross section of the supporting rod of metal columns from the working standard load; τ _us is the duration of resistance to the thermal effect of the supporting rod of metal columns without taking into account the fire protection of the insulating coating, min, the actual fire resistance limit Fur, min is calculated from the nomogram.

The next feature of the proposed method is that the intensity of normal stresses in the cross section of the supporting rod of metal columns from the working standard load, operating in conditions of fire tests, is calculated by the formula (1)

where N _ρ is the longitudinal force from the working standard load acting on the columns under standard fire tests, kN;

And _s is the area of the compressed section of the supporting rod of the net column, cm ² ;

R _уn - yield strength of steel according to GOST, MPa (see appendix 1 SNiP II-23-81 * "Steel structures". - M., 1990. - P.63-66);

e is the base of the natural logarithms (e = 2.72);

k is an integral indicator of the flexibility of the supporting rod of metal columns, calculated by the formula (2)

where λ = μ · l / i is the flexibility of the supporting rod;

μ is the coefficient of the estimated length of the metal columns; see adj. 6, Table 71, a, SNiP II-23-81 * (0.5≤μ≤2);

l is the length of the supporting rod of metal columns, cm;

i is the radius of the cross section of the supporting rod of the metal columns, see

A further feature of the proposed method is that for various values of the limiting temperature of heating the steel of the supporting rod of metal columns t _u , ° С, which differ from the critical temperature of steel t _cr , ° С, the actual (design) intensity of normal stresses (J _σs ) in the cross section of metal columns is calculated by the formula (3)

where J _σs is the intensity of normal stresses in the cross section of the supporting rod of metal columns (0 ÷ 1);

t _u —limit temperature of steel heating (° С), at which differently loaded supporting rods of metal columns lose their bearing capacity;

t _cr is the critical temperature of steel heating (° C) of the supporting rod of metal columns (at a standard stress intensity J _n = 0.625 for Art. 3 t _cr = 510 ° C);

n - empirical exponents depending on steel grades (n = 2.8 for Art. 3).

The next feature of the proposed method is that at t _u = t _cr ± 50 ° C, the intensity of normal stresses in the cross section of the supporting rod of metal columns is calculated approximately by the formula (4)

where J _n - the standard intensity of stresses in the cross section of the supporting rod of metal columns (0 ÷ 1).

The next feature of the proposed method is that the indicator of the heating conditions of the supporting rod of metal columns with a structural insulating coating under the standard fire test (for a _x > a _y ) is calculated by the formula (5)

where a _x ; a _y - respectively, the thickness of the insulation coating of the shelf (wall) of the supporting rod of the metal columns along the x and y axis, mm;

In - the width of the section of the supporting rod of the metal columns, mm

Provided that a _x > a _y in formula (5), these factors are interchanged; when changing the coordinate axes, the width of the section B, mm, of the supporting rod of the metal columns is replaced by a height H, mm.

Another feature of the proposed method is that the coefficient of thermal diffusion of the material of the insulating coating of metal columns D _ar , mm ² / min, is determined experimentally or calculated at an averaged temperature t _m = 450 ° C according to the formula (6)

where λ ₀ and b are empirical numbers for calculating the coefficient of thermal conductivity of the facing material;

t _m is the averaged heating temperature (450 ° C) of the facing material over the column section;

C ₀ and d are empirical numbers for calculating the specific heat of the facing material;

ω is the humidity of the facing material mass,%;

ρ _{with the} density of the dry material, kg / m ³ ;

k _ρ = 0.75 at ρ _with more than 1000 kg; k _ρ = 1 at ρ _s less than 1000 kg / m ³ .

The averaged values of the thermal diffusivity (thermal diffusion) coefficients for a number of facing materials with their natural moisture content (1 cm ² / h = 1.67 mm ² / min) are given in Table 1.

The next feature of the proposed method is that the duration of resistance to thermal effects of the supporting rod of metal columns without taking into account the fire protection of the insulation coating τ _us , min, is determined by the formula (7)

where J _σs is the intensity of normal stresses in the cross section of the supporting rod of metal columns from the action of the working standard load in case of fire (0≤J _σs ≤1);

T _sr - reduced thickness of the metal of the supporting rod of metal columns, cm, calculated by the formula (8)

where And _s is the cross-sectional area of the supporting rod, cm ² ;

P _o - the perimeter of the heating of the cross section in case of fire, see

Table 1. Thermophysical characteristics of the facing materials of metal columns Cladding material Density ρ _s , kg / m ³ Humidity ω,% The parameters of thermal conductivity, W / m · ° C, and heat capacity of the material, J / kg · ° C Heat diffusion coefficient D _ar , mm ² / min λ ₀ b C ₀ d 1. Asbestos cement slabs 1800 9 0.31 0.08 0.84 0.63 9.0 2. Asbestos perlite cement slabs 960 6 0,087 0.23 0.84 0.63 6.0 3. Plaster concrete slabs 1300 twenty 0.4 0.08 0.84 0.6 12.0 4. Gypsum plaster 900 twenty 0.2 0.35 one 0.6 9.0 5. Expanded clay 750 6 0.18 0.08 0.32 0.48 12.0 6. The same 950 6 0.23 0.13 0.85 0.58 13.0 7. The same 1400 6 - - - - 14.0 8. Perlite concrete 1250 6 0.4 0.05 0.85 0.38 19.0 9. Perlite cement-based plaster 500 8 - - - - 17.0 10. Masonry made of silicate brick 1730 one 0.79 -0.35 0.84 0.61 24.0 11. Masonry of ordinary ceramic bricks 1580 2 0.46 0.23 0.72 0.42 21.3 12. Heavy concrete on crushed stone 2250 3 1.15 -0.55 0.71 0.84 24.0 13. The same 14. Heavy concrete with granite aggregate 2400 3 1,2 -0.3 0.72 0.2 28.0 15. The same 16. Fireproof coating OFP-PM 250 16.5 0,046 0.35 0.92 0.63 24.2 17. Cement and sand plaster 1930 2 - - - - 24.0 18. Sand concrete 2000 3 1.16 0.62 0.75 0.77 35.6 19. Glass wool mats one hundred 5 - - - - 80.0

A feature of the proposed method lies in the fact that for the individual quality indicators of lined metal columns that affect the fire resistance limit, they take: the geometric dimensions of the dangerous section, the conditions for fixing the ends of the columns, the resistance of the steel to compression, the working normative load, the intensity of power stresses in dangerous sections, humidity and the density of the cladding material in its natural state, the thickness of the insulation coating, thermal diffusion indicators of the cladding materials.

A feature of the proposed method is that the number of tests n _{and a} single indicator of the quality of metal columns, with a probability of a result of 0.95 and an accuracy of 5%, is taken according to the formula (9)

where υ is the sample coefficient of variation of the test results,%.

A feature of the proposed method lies in the fact that the heating scheme of the cross sections in the fire conditions of the test metal columns is determined depending on the actual location of the building parts.

A feature of the proposed method is that in the case when all the individual quality indicators of the concrete metal columns (with M more than 9 pcs.) Are within the control limits, the minimum integer number of metal columns in the sample according to the plan of shortened tests M _min , pcs, is prescribed from condition (10)

where M is the number of columns of the same type in the building, pcs.

In the case when at least one of the single indicators of the quality of the metal columns goes beyond the control limits, the minimum number of columns in the sample is determined by the norm according to the formula (11)

In the case when at least one of the single indicators of the quality of the metal columns goes beyond the permissible limits or M≤5 pcs., All building columns of the same type are subjected to a non-destructive test piece by piece.

A feature of the proposed method is that it additionally calculates the guaranteed fire resistance limit of the concrete metal columns according to the nomogram by solving the inverse fire resistance problem.

A feature of the proposed method for determining the fire resistance of metal columns of a building is that non-destructive tests are carried out for a group of columns of the same type, the differences between the thickness of the insulating coating and the fluidity of steel which are caused mainly by random factors.

Schemes for heating sections of test metal columns under fire conditions are determined depending on the actual location of the building parts.

The causal relationship between the totality of features and the technical result is as follows.

The elimination of the fire tests of the columns of an existing building and their replacement with non-destructive tests reduces the complexity of determining their fire resistance, expands the technological capabilities of detecting the actual fire resistance of variously loaded columns of any size, makes it possible to test structures for fire resistance without disturbing the functional process of the building under examination, as well as comparing the results obtained with standard tests of similar columns and maintaining operational suitability the building under investigation without disturbing the bearing capacity of its columns during the test. Therefore, the conditions for testing the columns for fire resistance are greatly simplified.

Reducing the economic costs of testing include reducing the cost of dismantling, transportation and fire tests of samples of columns.

The use of a mathematical description of the process of resistance of lined metal columns to standard thermal testing and the use of the constructed parametric nomograms increase the accuracy and expressiveness of their fire resistance assessment.

The use of the nomogram is convenient due to its simplicity, visibility, the possibility of solving inverse problems of fire resistance of columns and the use of the method of selecting variable values of its design parameters.

The use of integral structural parameters, such as: intensity of steel stress and coefficient of thermal diffusion of cladding materials, simplifies the mathematical description of the process of resistance of loaded columns to thermal effects.

The proposed technical solution provides for testing not one, but groups of the same type of columns. This allows you to 5-15 times increase the number of test columns and increase the reliability of the test results and technical inspection of the building. Determination of the fire resistance of structures by only one quality indicator, for example, by the thickness of the insulation coating, leads, as a rule, to underestimating their fire resistance limit, since the influence of variations in individual quality indicators on it has different signs, and the decrease in fire resistance due to one indicator can be compensated by others . As a result, in the proposed method, the assessment of the fire resistance of the columns is provided not for one indicator, but for a set of individual indicators of their quality. This allows you to more accurately take into account the real fire resistance of metal columns.

The complex of individual quality indicators of lined metal columns that affect their fire resistance, determined by non-destructive tests, has been clarified.

The minimum number of non-destructive tests of a single quality indicator of metal columns has been clarified.

The accepted sample size from the total number of building columns of the same type provides reliability, reduces the time and complexity of testing.

Figure 1 shows the nomogram for assessing the fire resistance of lined metal columns, heating from 4 sides. The nomogram of the mesh type is given. Inclined lines are drawn inside the grids. An arrow is drawn on each beam of lines or rays, which shows the direction of increase of the variable parameter. The name of the parameter in alphabetic terms and in units of measurement is placed on the arrow. To the left and right of the arrow on the rays are the values of the variable parameter.

The procedure for the production of samples or "key":

D _ar (mm ² / min) -δ ₀ (mm) -m ₀ -J _σs -τ _us (min) -F _ur (min).

Figure 2 shows a diagram of a centrally loaded metal column with an insulating coating, the length of the column 280 cm; hinged ends, 4-sided heating, thermal mode of a standard fire; the cross-sectional dimensions of the column B × H = 270 × 160 mm;

l - bearing rod - steel tee No. 22, b × h × d = 11 × 22 × 0.54 cm; reduced metal thickness T _sr = 0.35 cm; cross-sectional area of 30.6 cm ² ; steel grade St.3, temperature limit t _u = 500 ° C; critical temperature t _cr = 510 ° C; axial distances to the design point of the I-beam shelf a _x1 = δ ₀ = 35 mm; a _y1 = 53 mm <N / 2 = 80 mm; and _y2 = H-a _y1 = 160-53 = 107 mm; an indicator of heating of a shelf of an I-beam m ₀ = 0.79; intensity of power stresses in the metal J _σs = 0.64; the duration of resistance to the thermal force of an unprotected supporting rod τ _us = 13 min; the fire resistance of the column on the basis of loss of bearing capacity F _ur = 97 min (1.62 hours; experience - 1.6 hours);

2 - filling the inner cavity: concrete composition 1: 3: 3 (cement: sand: crushed stone); density 1990 kg / m ³ ; humidity 4.7%;

3 - plaster - composition 1: 0.2: 2.5 (cement: lime: sand), humidity 3%; thickness 25 mm; coefficient of thermal diffusion D _ar = 24.2 mm ² / min.

Information confirming the possibility of carrying out the invention with obtaining the above technical result. The sequence of operations of the method for determining the fire resistance of lined metal columns of a building is as follows.

First, a visual inspection of the building is carried out. Then determine the group of the same type of columns and their total number in it. The sample size of the same type of columns is calculated. Assign a set of individual indicators of the quality of the structure, affecting fire resistance. The conditions for fixing the ends and dangerous sections of metal columns are revealed. Calculate the number of tests of a single indicator of the quality of the columns depending on its statistical variability. Then, single quality indicators of the columns and their integral parameters are evaluated, and finally, the fire resistance of the tested structures is found from them.

Visual inspection means checking the condition of the columns, including identifying the conditions for fixing and heating the metal columns, determining the material of the structural protection of the metal columns from heating in case of fire (ordinary concrete, expanded clay concrete, brick, hollow blocks, gypsum boards, vermiculite boards, plaster, perlite-asbestos cladding and t .p.), type of hire (I-beam, channel, angle), cross-sectional shape of the supporting rod of a metal column, its geometric dimensions, steel grade (grade), working normative loading.

During the inspection, groups of the same type of columns are determined. A group of structures in a building is understood to mean the same type of metal columns manufactured and built under similar technological conditions and under similar operating conditions.

Schemes for heating cross sections of lined metal columns under fire conditions are determined depending on the actual location of the building parts, the arrangement of claddings, and the laying of adjacent structures that reduce the number of sides of the heating.

The minimum integer number of columns in the sample according to the plan of normal or reduced tests is assigned from the conditions (13 and 14).

Example 1. With the number of structures of the same type in the group M = 120 pieces, the number of test metal columns is taken at the rate

M _n = 5 + M ^0.5 = 5 + 120 ^0.5 = 16 pcs., According to an abridged plan;

M _min = 0.3 · (15 + M ^0.5 ) = 0.3 · (15 + 120 ^0.5 ) = 7.78≈8 pcs.

When the number of designs in the group M≤5, they are checked individually.

The number and location of sections in which the quality indicators of the columns are determined are determined as follows. In a column having one dangerous section, sections are placed only in this section. In a column having several dangerous sections, the test sections are placed evenly on the surface with the obligatory location of part of the sections in dangerous sections.

The main single quality indicators of lined metal columns providing fire resistance include: coefficient of thermal diffusion and density of the insulation coating material, indicator of the heating conditions of the supporting rod of the metal column with insulation coating, thickness of the insulation coating, steel grade, its yield strength, critical temperature, reduced thickness the metal of the supporting rod, its flexibility, the intensity of normal stresses in the section of the supporting rod, the resistance time of thermosilic Effects unprotected metallic carrier rod string.

The number of tests of a single indicator of the quality of structures, with a probability of result equal to 0.95, and an accuracy rate of 5%, is determined by the formula (12);

the coefficient of variation of the sample υ = ± 100 · σ / A;

arithmetic mean A = (l / n) · Σm _i ,

standard deviation from mean σ = ± [(l / (nl)) · Σ (x _i ) ² ] ^0.5 ;

average error ΔА = ± σ / (2 · n) ^0.5 ;

here m _i is the result of the i-th test;

Σ (x _i ) ² is the sum of the squares of all deviations from the mean.

Checked geometric dimensions are: the thickness of the insulation coating, the width and height of the cross section of the supporting rod of the metal column.

Dangerous sections of metal columns are assigned in places of greatest moments from the action of the regulatory load.

The dimensions of the structure are checked with an accuracy of ± 1 mm.

The coefficient of thermal diffusion of the cladding material under thermal exposure is determined at 450 ° C. To calculate its integral parameter by the formula (8), determine the density of the cladding material in its natural state, its moisture content, as well as the thermal conductivity and heat capacity at 450 ° C.

Using the obtained integral parameters

D _ar (mm ² / min), δ ₀ (mm), m ₀ , J _σs , τ _us (min),

the nomogram (see figure 1) find the fire resistance of the lined metal columns of the building.

With the same values of the integral parameters, the fire resistance of columns with different static schemes of operation, the intensity of normal stresses in the cross section of the supporting rod of the metal column from the action of the working normative load, the varying degrees of fire protection of the supporting rod with an insulating coating, the duration of resistance to the thermal force of an unprotected supporting rod, is calculated by the formula (one).

The guaranteed fire resistance of lined metal columns, F _ur , min, is calculated from the above nomogram (see figure 1) with a corresponding change in design parameters:

J _σs is the intensity of normal stresses in the cross section of the supporting rod of the column from the standard load;

δ ₀ - the thickness of the insulation coating of the column minimum, mm;

m ₀ - an indicator of the heating conditions of the bearing rod of a lined metal column in a fire;

D _ar (mm ² / min) - indicator of thermal diffusion of the material of the insulation coating (thermal diffusivity at 450 ° C);

τ _us (min) - the duration of the resistance to the thermal force of the unprotected supporting rod of the metal column.

Thus, the above information indicates that when using the claimed method the following set of conditions:

a) a tool embodying the claimed method in its implementation, is intended for use in the construction industry, namely in the classification of metal columns of buildings according to their resistance to fire;

b) for the claimed method in the form described in the independent clause of the claims, the possibility of its implementation using the means and methods described in the application is confirmed;

c) the proposed method is applied in assessing the actual fire resistance limits of metal columns tested in the VNIIPO fire furnace. The continuous cross section of the column, lined with stucco with a thickness of δ ₀ = 35 mm, represents a supporting rod in the form of an I-beam No. 22, with dimensions b × h × d = 11 × 22 × 0.54 cm, the metal area A _s = 30.6 cm ² ; the limiting and critical temperatures for steel grade 3 are respectively 500 and 510 ° C; coefficient of thermal diffusion of the insulation coating D _ar = 24.2 mm ² / min, (see figure 2) the fire resistance determined during fire tests is 1.6 hours (96 min}. The fire resistance of a metal column, calculated according to the non-destructive test, equal to 97 min (1.62 h); the calculation error is 1.25%, which is less than 5%.

Therefore, the claimed invention meets the condition of "industrial applicability".

Information sources

1. Ilyin N.A. The consequences of fire on reinforced concrete structures. - M.: Stroyizdat, 1979. - 128 p. (see p. 16; 34-35).

2. Buildings and fragments of buildings. The method of full-scale fire tests. General requirements. Fire safety standards. NPB 233-97. - M .: VNIIPO, 1997 .-- 14 p.

3. Fire resistance of buildings. V.P. Bushev, V.A. Pchelintsev, B.C. Fedorenko, A.I. Yakovlev. - M .: Stroyizdat, 1970 .-- 261 p. (see p. 252-256).

4. GOST 30247.1-94. Building constructions. Test methods for fire resistance. Bearing and enclosing structures. - M .: IPK Publishing House of Standards, 1995. - 7 p.

5. SNiP II - 23-81 *. Steel structures. Design Standards. - M .: GUP TsPP, 1990. - 95 p. (see p. 63-66).

Claims (15)

1. A method for determining the fire resistance of clad metal columns of a building by testing, including conducting technical inspection, determining the type of cladding material, steel grade of the supporting rod of metal columns, identifying the conditions for their support and fastening, determining the time of the onset of the ultimate state based on the loss of bearing capacity of columns under standard load under standard thermal effects, characterized in that the test of metal columns is carried out without destruction, using a complex of individual indicators of the quality of the materials of cladding and steel of the supporting rods of metal columns, determine the number and location of sections in which the quality indicators are determined, technical inspection is supplemented by instrumental measurements of the geometric dimensions of the cladding and bearing rods of metal columns, the cross-sectional area of the bearing rods of metal columns in dangerous sections, identify their heating patterns in case of fire, experimentally determine the density indicators of the cladding materials moisture content in the natural state and / or the coefficient of thermal diffusion cladding material are limiting resistance of steel under compression set value of the working characteristic load on the column and the magnitude of force of the stress intensity in hazardous sections, and using the obtained integral parameters coated metallic columns - D _ar - coefficient of thermal diffusion of the material of the insulating coating, mm ² / min; δ ₀ - the minimum thickness of the insulation coating, mm; m ₀ is an indicator of the heating conditions in a fire of the supporting rod of metal columns with an insulating coating; J _σs is the intensity of normal stresses in the cross section of the supporting rod of metal columns from the working standard load; τ _us is the duration of resistance to the thermal effect of the supporting rod of metal columns without taking into account the fire protection with an insulating coating, min, the actual fire resistance limit Fur, min is calculated from the nomogram. 2. The method according to claim 1, characterized in that the intensity of normal stresses in the cross section of the supporting rod of the metal columns from the working standard load, operating in conditions of fire tests, is calculated by the formula (1)

where N _ρ is the longitudinal force from the working standard load acting on the columns under standard fire tests, kN; A _s - the area of the compressed section of the supporting rod net, cm ² ; R _yn - yield strength of steel according to GOST, MPa; e is the base of the natural logarithms (e = 2.72); k is an integral indicator of the flexibility of the supporting rod of metal columns, calculated by the formula (3)

where λ = μ · l / i is the flexibility of the supporting rod; μ is the coefficient of the estimated length of the metal columns (0.5≤μ≤2); l is the length of the supporting rod of metal columns, cm; i is the radius of the cross section of the supporting rod of the metal columns, see 3. The method according to claim 1, characterized in that at different values of the limiting temperature of heating the steel of the supporting rod of the metal columns t _u , ° C, different from the critical temperature of the steel t _cr , ° C, the actual (design) intensity of normal stresses (J _σs ) in the cross section of metal structures is calculated by the formula (3)

where J _σs is the intensity of normal stresses in the cross section of the supporting rod of metal columns; t _u —limit temperature of steel heating (° С), at which differently loaded supporting rods of metal columns lose their bearing capacity; t _cr is the critical temperature of steel heating (° C) of the supporting rod of metal columns (at a standard stress intensity J _n = 0.625 for Art. 3 t _cr = 510 ° C); n - empirical indicators depending on steel grades (n = 2.8 for Art. 3); 4. The method according to claim 1, characterized in that at t _u = t _cr ± 50 ° C, the intensity of normal stresses in the cross section of the supporting rod of metal columns is calculated approximately by the formula (4)

where J _n - standard stress intensity in the cross section of the supporting rod of metal columns. 5. The method according to claim 1, characterized in that the indicator of the heating conditions of the supporting rod of metal columns with a structural insulating coating under standard fire test (for a _x > a _y ) is calculated by the formula (5)

where a _x , a _y is the thickness of the insulation coating of the shelf (wall) of the supporting rod of the metal columns, respectively, along the axes x and y, mm; In - the width of the section of the supporting rod of the metal columns, mm, provided that a _x > a _y in formula (5), these factors are interchanged, when the coordinate axes are changed, the width of the section B, mm, of the supporting rod of the metal columns is replaced by the height H, mm. 6. The method according to claim 1, characterized in that the coefficient of thermal diffusion of the material of the insulating coating of metal columns D _ar , mm ² / min, is determined experimentally or calculated at an average temperature t _m = 450 ° C according to the formula (8)

where λ ₀ and B are empirical numbers for calculating the coefficient of thermal conductivity of the facing material; t _m is the averaged heating temperature (450 ° C) of the facing material over the column section; C ₀ and d are empirical numbers for calculating the specific heat of the facing material; ω is the humidity of the facing material mass,%; ρ _{with the} density of the dry material, kg / m ³ ; k _ρ = 0.75 at ρ _with more than 1000 kg / m ³ ; k _ρ = 1 at ρ _s less than 1000 kg / m ³ . 7. The method according to claim 1, characterized in that the duration of resistance to thermal effects of the supporting rod of metal columns without taking into account the fire protection of the insulation coating τ _us , min, is determined by the formula (7)

where J _σs is the intensity of normal stresses in the cross section of the supporting rod of metal columns from the action of the working standard load in case of fire (0≤J _σs ≤1); T _sr - reduced thickness of the metal of the supporting rod of metal columns, cm, calculated by the formula

where A _s is the cross-sectional area of the supporting rod, cm ² ; P _about - the perimeter of the heating of the cross section of the columns in case of fire, see 8. The method according to claim 1, characterized in that the geometric dimensions of the dangerous section, the conditions for fixing the ends of the columns, the resistance of the steel to compression, the working standard load, the intensity of dangerous voltage sections, moisture and density of the cladding material in its natural state, the thickness of the insulating coating, indicators of thermal diffusion of the cladding materials. 9. The method according to claim 1, characterized in that the number of tests n _{uc of a} single quality indicator of metal columns with a probability of a result of 0.95 and an accuracy of 5% is taken according to the formula (9)

where υ is the sample coefficient of variation of the test results,%. 10. The method according to claim 1, characterized in that the heating circuit of the cross-sections under fire conditions of the test metal columns is determined depending on the actual location of the parts of the building. 11. The method according to claim 1, characterized in that in the case when all the individual quality indicators of the concrete metal columns (with M more than 9 pcs.) Are within the control limits, the minimum integer number of metal columns in the sample according to the plan of shortened tests M _min , pcs, appoint from condition (10)

where M is the number of columns of the same type in the building, pcs. 12. The method according to claim 1, characterized in that in the case when at least one of the individual quality indicators of the metal columns goes beyond the control limits, the minimum number of columns in the sample is determined by the norm according to the formula (11)

13. The method according to claim 1, characterized in that in the case when at least one of the individual quality indicators of the metal columns is outside the acceptable limits or M≤5 pcs., All building columns of the same type are subjected to a non-destructive test piece by piece. 14. The method according to claim 1, characterized in that it further computes the guaranteed fire resistance limit of the concrete metal columns according to the nomogram by solving the inverse fire resistance problem. 15. The method according to claim 1, characterized in that non-destructive tests are carried out for a group of the same type of columns, the differences between the thickness of the insulation coating and the fluidity of the steel which are caused mainly by random factors.

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