RU2814454C1 - Wall ring loading test unit - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to construction, particularly to testing equipment. Installation includes a collapsible stand, a loading device, steel distributing traverses, wooden beams to them, rubber gaskets for wooden beams, a force-measuring device, thrust elements. Loading device is made in the form of a horizontal load-bearing frame, the thrust elements of which include thrust and support steel beams and metal ties. Thrust steel beam of the load-bearing frame is made composite and contains a base in the form of a thin-walled channel with stiffeners and a reinforcing element in the form of an H-section welded to the base. In the slot of the base channel, in the middle of the length of the thrust steel beam of the load-bearing frame, a cargo jack is installed, and its housing is tightly fixed in place by adjusting screws, the jack rod is borne against the flange of the H-section of the reinforcing element. Thrust and support distributing traverses are made composite, metal-wood from steel bars of H-section and section of thin-walled channel attached to it.

EFFECT: creation of a compact self-contained plant; simplified manufacturing of distributing traverse and composite steel beam of load-bearing frame; simplification of the system for transferring the load to the wall ring; reduction of metal consumption of installation elements; obtaining more reliable test results.

7 cl, 7 dwg

Description

The invention relates to the field of construction, in particular, to testing equipment intended for testing materials and structures, and is applicable for studying the physical parameters of the strength and crack resistance of concrete and reinforced concrete cylindrical rings, for example, manholes under loading conditions without the use of a load-bearing floor slab.

There is a known installation for loading a beam structure, which includes a collapsible stand, a loading device, a thrust and test structure, and connections using rigid clamps. /Patent 2351910 RU, IPC G 01 N3/10. Experimental installation for testing beam structures / Kolchunov V.I., Skobeleva E.A., appl. Orel State Technical University: 11/13/07, publ. 04/10/09. Bull. No. 10/ [1].

Disadvantages: the complexity and material consumption of the structure of the loaded platform, the system of transferring the load to the test beam structure is complex, during testing it is possible for the strands to be displaced from the test sample and the supporting structure.

The closest in essence to the proposed invention is an installation for testing the loading of a cylindrical wall ring, containing wooden blocks, rubber gaskets, steel cross-beams and the base of the installation. /GOST 8090-2016. Concrete and reinforced concrete structures for wells. Technical specifications (clause 7 Test and control methods, Appendix B) / [2], - prototype.

Disadvantages of the known design solution: tests of the wall ring are carried out in a horizontal position, which does not correspond to the working position under operating conditions of the manhole; the given alternate arrangement of a wooden beam and a rubber gasket in a metal-wood traverse leads to an increase in the height of the composite structure of the fixed support and to a loss of stability of its elements; an additional device for a load-bearing floor plate is required to create the load-bearing frame of the test facility; the construction of a load frame to create a test load is cumbersome; it is necessary to manufacture a bulky base for installation.

The essence of the proposed design solution for the testing installation is the manufacture of a compact, autonomous, universal and simple design of the testing installation, which allows testing without the use of a load-bearing slab of the floor of the room, taking into account the spatial arrangement of the test wall ring, corresponding to the conditions of its operation during operation, as well as in increasing reliability of operation of thrust elements of the load frame, power device, composite metal-wood cross beams.

The technical result of the invention is the creation of a compact, autonomous, universal installation for testing the loading of a wall ring with the possibility of its operation without installing a load-bearing slab for the floor of the room; simplification of the manufacture of a metal-wood distribution beam and a composite steel beam of a power frame; simplification of the load transfer system to the wall ring; reducing the metal consumption of plant elements; increasing the reliability of test results compared with design data; increasing the functionality and reliability of the installation for testing the wall ring by loading.

The specified technical result is achieved by the fact that in the known installation for testing the loading of a wall ring, which includes a collapsible stand, a loading device, steel distribution beams, wooden beams for them, rubber gaskets for wooden beams, a force-measuring device, thrust elements, the peculiarity is the fact that the collapsible stand is made portable, autonomous, with the ability to work without the use of a power slab of the floor of the room; the loading device is made in the form of a horizontal load frame, the thrust elements of which include thrust and support steel beams and metal ties, equipped with tension and thrust nuts, as well as spring washers to fix the position of the test wall ring; metal strands are made in the form of fixed steel rods with a cross-sectional area adopted for tensile strength calculations; the thrust steel beam of the load frame is made composite, containing a base in the form of a thin-walled channel with stiffeners and a reinforcing element in the form of a section of an I-section connected to the base by welding; in the groove of the base channel, in the middle of the length of the thrust steel beam of the load frame, a cargo jack is installed and its body is tightly fixed in place with set screws, the jack rod rests against the I-beam flange of the reinforcing element; the thrust and support distribution traverses are made of composite, metal-wooden beams from steel beams of an I-beam profile and a piece of thin-walled channel attached to it, with a length equal to the height of the test wall ring; a wooden beam with a rubber gasket is tightly attached to the groove of the thin-walled channel on the protruding part of the wooden beam in the plane of support on surface of the test wall ring. The cross-sectional dimensions of the elements of the thrust steel beam of the load-bearing frame: the base - a section of a thin-walled channel and the reinforcing element - a shortened section of an I-beam profile are taken according to the calculation of their bending strength. The internal part, the groove of the thin-walled channel of the base of the thrust steel beam of the load frame, has a size no less than the width of the cargo jack. To load the wall ring, a load jack was used for testing building structures with a load capacity of 800÷1000 kN. The cross-sectional dimensions of the distribution beam are taken to account for the bending of a beam on an elastic base under the action of a symmetrical concentrated load from the load jack rod. The dimensions of the wooden beam of the distribution beam are assumed to be width h ₁ , mm, equal to h ₁ =h _w -2∙δ _w ; thickness b ₁ , mm, equal to b ₁ =c+(b _w -d _w ); length l _d , mm, equal to l _d ≈H _st ; here h _w and δ _w are, respectively, the height and thickness of the channel - the base of the traverse, mm; b _w and d _w - the width of the flange and the thickness of the channel flange - the base of the traverse, mm; c - the protrusion of the wooden beam (20÷30 mm); H _st - height of the wall ring, mm. The diameter of the metal cord d _strand , mm, of the load frame is calculated using equation (1):

where N _b is the force in the strand, kN; R _bt - design tensile strength of steel, MPa; γ _c and γ _m - coefficients of operating conditions and reliability for the material; ñ=3.142 is an irrational number.

The cause-and-effect relationship between the set of characteristics and the technical result is as follows: a compact, autonomous and universal installation for testing the loading of a wall ring (without the use of a load-bearing slab of the floor of the room) significantly reduces the costs of design, manufacturing and testing; simplification of the manufacture of the distribution cross-beam and the steel beam of the load-bearing frame of the testing facility reduces the cost of metal and wood; the natural, vertical spatial arrangement of the test wall ring, which corresponds to the operating conditions of the manhole during operation, contributes to obtaining more accurate test results. The use of metal rods, the ends of which are equipped with tension and thrust nuts, as well as spring washers, increases the reliability of the power frame of the testing facility; installation and fastening of a cargo jack in the groove of the channel-shaped base of the composite steel beam of the load frame reduces the dimensions of the test installation and increases the reliability of its operation.

In fig. 1 and 2 show a wall ring loading test setup; A-A - installation section; B-B - top view:

1 - wall ring; 2 - wooden beam; 3 - rubber gasket; 4 - thrust distribution beam; 5 - cargo jack; 6 - support distribution beam; 7 - thrust steel beam of the power frame; 8 - supporting steel beam of the power frame; 9 - metal rod equipped with tension, thrust nuts and spring washers; 10 - beam stiffener - limiters for the placement of the cargo jack and the distribution beam with set screws; 11 - support table; P - load jack force, kN; P ₁ - pushback force of the supporting distribution beam, kN.

In fig. 3 and 4 show a diagram of the load frame of the test installation; section B-B - top view; section Г-Г - side view: 7 - thrust steel beam of the power frame; 8 - supporting steel beam of the power frame; 9 - metal rod; 12 - weld; 13 - hole for cord; P - compression force from the cargo jack, kN; N _b - tensile force in the cord.

In fig. 5 and 6 show cross-sections of the steel beam of the power frame (Fig. 5) and the distribution beam (Fig. 6): 2 - wooden beam; 3 - rubber gasket; 10 - beam stiffener; 12 - weld; 14 - set screw; 15 - base of the steel beam - thin-walled channel; 16 - reinforcing element of a composite beam - I-beam; P - compression force from the cargo jack, kN; b _t and h _t - width of the shelf and height of the I-beam, mm; b _w and h _w - width of the shelf and height of the channel, mm; b _db - width of the wooden beam, mm.

In fig. Figure 7 shows the details of the steel beam of the load frame and the distribution beam of the test installation: 10 - stiffener of the beam; 12 - weld; 13 - hole for cord; 14 - set screw; 15 - base of the steel beam - thin-walled channel; 16 - reinforcing element of a composite beam - I-beam; b _t and h _t - width of the shelf and height of the I-beam, mm; b _t and h _t - width of the flange and height of the channel, mm; b _w and h _w - width of the shelf and height of the I-beam, m; l _w and l _t - length of the channel and I-beam section, mm.

Example. Given: the metal rod is subject to a longitudinal force N _b =250 kN, steel class 5.8, design tensile strength R _bt =295 MPa, operating conditions coefficient γ _c =0.9, reliability coefficient for the material γ _m =1.05.

It is required to determine the diameter of a round metal rod.

Solution. The required diameter of the cord is calculated using equation (1):

where N _b is the force in the strand, kN; R _bt - design tensile strength of steel, MPa; γ _c and γ _m - coefficients of operating conditions and reliability for the material; ñ=3.142.

The installation for testing the loading of a wall ring is made portable, autonomous, with the ability to operate without the use of a load-bearing floor plate of the room. The loading device of the proposed testing installation is made in the form of a horizontal load frame, including a thrust steel beam of the load frame - 7, a supporting steel beam of the load frame - 8 and metal ties - 9 (with threads at the ends) made in the form of fixed steel rods, the ends of which are equipped with tension and thrust nuts, as well as spring washers. The thrust steel beam of the load frame - 7 is made composite, containing the base of the steel beam - 15 in the form of a thin-walled channel with beam stiffening ribs - 10 and the reinforcing element of the composite beam - 16 in the form of a piece of I-profile connected to the base by a weld - 12. In the groove of the thin-walled channel , in the middle of the length of the thrust steel beam of the load frame - 7, a cargo jack - 5 is installed, the body of which is tightly fixed in place with set screws - 14, the jack rod rests against the I-beam flange of the reinforcing element of the composite beam - 16.

The thrust distribution cross-beam - 4 and the supporting distribution cross-beam - 6 are made of a steel beam of an I-beam profile and a piece of thin-walled channel attached to it, with a length equal to the height of the test wall ring - 1. A wooden beam - 2 with a rubber gasket - 3 is tightly installed in the groove of the thin-walled channel , located on its protruding part, with which it rests on the surface of the test wall ring - 1.

The installation for testing the loading of a cylindrical wall ring is brought into working condition as follows: first, support tables are installed - 11 with a height of 0.5∙H _st , where H _st is the height of the wall ring, mm; then the elements of the power frame are laid on them, a thrust steel beam of the power frame - 7, a supporting steel beam of the power frame - 8 and distribution cross-beams are installed; then a load jack - 5 is installed in the channel grooves of the thrust steel beam of the load frame - 7 and secured in place with set screws - 14; secure with thrust and tension nuts to the bases of the thrust steel beam of the power frame - 7 and the supporting steel beam of the power frame - 8, passing metal strands through the holes made in them - 9.

The work place for testing the wall ring -1 is a leveled horizontal platform or concrete floor on which the wall ring - 1 is installed; support tables - 11 for the load frame and measuring instruments are installed on the sides of the wall ring; on the support table - 11, the parts of the power frame are assembled; a load jack - 5 (800÷1000kN) is installed in the groove of the channel in the middle of the span of the thrust steel beam of the load frame - 7; the magnitude of the applied load is measured by a pressure gauge; The jack is placed between the thrust steel beam of the power frame - 7 and the composite thrust distribution beam - 4.

The force (P, kN) created by the cargo jack is taken as the test load - 5; the force from the cargo jack P, kN, to the wall ring - 1 is transmitted through the thrust steel beam of the load frame - 7 and the supporting distribution cross-beam - 6; a load jack is used to push with a given force the thrust steel beam of the power frame - 7 and the thrust distribution beam - 4, which is placed perpendicular to the side surface of the wall ring - 1 according to a given test pattern, metal ties - 9 connect the thrust steel beam of the load frame - 7 and the supporting steel beam of the power frame - 8, evenly distributing the load from the cargo jack -5.

The wall ring is installed on the platform or floor of the room in a vertical position, that is, in its working position during operation. The test load is applied in a horizontal position of the load frame; the own weight of the wall ring is not included in the test load value. A load is applied to the wall ring being tested, adjusting it in magnitude and loading speed; the strength parameters of the test wall ring are measured in a given time interval.

Therefore, a compact, self-contained and universal design of the installation for loading testing of a cylindrical wall ring of a manhole is proposed.

Information sources:

1. Patent 2351910, IPC G 01 N3/10. Experimental installation for testing beam structures / Kolchunov V.I., Skobeleva E.A., appl. Orel State Technical University: 11/13/07, publ. 04/10/09. Bull. No. 10.

2. GOST 8090-2016. Concrete and reinforced concrete structures for sewer, water and gas pipeline wells. (Clause 7 Test and control methods. Appendix B).

Claims (9)

1. Installation for testing the loading of a wall ring, including a collapsible stand, a loading device, steel distribution cross-beams, wooden beams for them, rubber gaskets for wooden beams, a force-measuring device, thrust elements, characterized in that the collapsible stand is made portable, autonomous, with the ability to work without the use of a power slab of the floor of the room; the loading device is made in the form of a horizontal load frame, the thrust elements of which include thrust and support steel beams and metal rods, equipped with tension and thrust nuts, as well as spring washers, to fix the position of the test wall ring; metal strands are made in the form of fixed steel rods with a cross-sectional area adopted for tensile strength calculations; the thrust steel beam of the load frame is made composite, containing a base in the form of a thin-walled channel with stiffeners and a reinforcing element in the form of a section of an I-section connected to the base by welding; in the groove of the base channel, in the middle of the length of the thrust steel beam of the load frame, a cargo jack is installed and its body is tightly fixed in place with set screws, the jack rod rests against the I-beam flange of the reinforcing element; the thrust and support distribution traverses are made of composite, metal-wooden beams from steel beams of an I-beam profile and a piece of thin-walled channel attached to it, the length equal to the height of the test wall ring; a wooden beam with a rubber gasket on its protruding part in the plane of support on the surface of the test is tightly installed in the groove of the thin-walled channel wall ring. 2. Installation according to claim 1, characterized in that the cross-sectional dimensions of the elements of the thrust steel beam of the power frame: the base - a section of a thin-walled channel - and the reinforcing element - a shortened section of an I-section - are taken according to the calculation of their bending strength. 3. Installation according to claim 1, characterized in that the inner part of the groove of the thin-walled channel of the base of the thrust steel beam of the power frame has a size not less than the width of the cargo jack. 4. The installation according to claim 1, characterized in that a load jack is used to load the wall ring for testing building structures with a load capacity of 800÷1000 kN. 5. Installation according to claim 1, characterized in that the cross-sectional dimensions of the distribution beam are taken based on the bending of a beam on an elastic base under the action of a symmetrical concentrated load from the load jack rod. 6. Installation according to claim 1, characterized in that the dimensions of the wooden beam of the distribution beam are assumed to be width h ₁ , mm, equal to h ₁ =h _w -2⋅δ _w ; thickness b ₁ , mm, equal to b ₁ =c+(b _w -d _w ); length l _d , mm, equal to l _d ≈H _st ; here h _w and δ _w are the height and thickness of the channel - the base of the traverse, respectively, mm; b _w and d _w - width of the flange and thickness of the channel flange - traverse base, mm; c - protrusion of a wooden beam (20÷30 mm); H _st - height of the wall ring, mm. 7. Installation according to claim 1, characterized in that the diameter of the metal strand d _strand , mm, of the load frame is calculated using the equation: d _strand =2⋅[(N _b / )/R _bt ⋅(γ _c /γ _m )] ^0.5 ; where N _b is the force in the strand, kN; R _bt - design tensile strength of steel, MPa; γ _c and γ _m - coefficients of operating conditions and reliability for the material; =3.142 is an irrational number.