RU2584432C1 - Trapezoid-shaped support with control of operating mode - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to fastening openings of trapezoidal-section metal frame supports of special profile for underground works. Trapezoid lining with control mode, including two straight racks and beams connected to frame by two rounded elements with straight sections at their end nodes compliance with limiters. To increase bearing capacity of lining, due to impact on horizontal array beams, pressure caused by hingeless connection counters and ends frame nodes beams vertical and horizontal compliance lining elements with rounded radius of not more than 0.5-0.7 m, which have at their ends straight sections of equal vertical and horizontal compliance lining project and amount of overlap in nodes of compliance with limiters, excluding offset them from design position. Stable operation is provided of lining in operation pliable and smooth transfer of its work in hard mode with exhaustion of project compliance lining, due to increase of friction forces and crushing material mating components are mounted on contact began bends rounded areas with elements of compliance units.

EFFECT: technical result is to increase carrying capacity of frames of trapezoidal lining.

1 cl, 2 dwg

Description

A constructive solution of a trapezoidal metal frame support from a special profile with the control of the limits of its vertical and horizontal compliance with jointless mounting of the support frames intended for fastening workings in the coal and mining industry, as well as in other industries where the construction and operation of horizontal underground workings are trapezoidal, is claimed cross section.

Currently, in the coal industry, mainly during the excavation of rifled workings, the trapezoidal cross-sectional shape is widely used as the most rational for placing equipment with a minimum amount of rock excavation. The fastening of such forms of workings is carried out mainly by a metal frame support from a special profile. Structurally, the trapezoidal supports consist of a rectilinear upper, articulated on a rack. The weakest link in such roof support structures is the upper, which receives the bending moment from the influence of the vertical component of the rock pressure, which, in most conditions of the construction of the workings, significantly exceeds the horizontal loads perceived by the struts. Due to the articulation of the uprights with the upper, the horizontal loads acting on them are transferred to the upper as compressive, practically without affecting the magnitude of the bending moment acting on the upper.

The use of nodes of vertical compliance in the trapezoidal lining, with the articulated connection of the racks with the upper, allows to slightly increase the service life and stability of its operation, but at the same time, the presence of compliance nodes does not affect the nature of the diagram of the stresses acting in the lining elements.

Thus, the main factor determining the bearing capacity of the trapezoidal support frames of traditional structures is the limiting value of the bending moment acting on the upper.

Known designs of trapezoidal lining, allowing to increase the bearing capacity of the upper due to the installation of special struts with supports on the racks and the upper. Such a support structure significantly complicates both the manufacturing technology and its installation in the development, and stress concentrations arise in the strut supports. Reducing the bending moment on the upper due to the use of additional racks is limited by the requirements of the PB on ensuring the minimum allowable gaps between the lining elements and the equipment used in the development.

To increase the bearing capacity of the upper tower, the DonUGI Institute developed a trapezoidal support structure using balancing struts and external upper console for the articulation of the racks with the compliance nodes with the upper. (Mining. Encyclopedic reference book. - Moscow: Ugletekhizdat 1985, p. 125.) This design provides a reduction in the bending moment on the upper, but due to the extreme complexity of the support structure, the high cost and complexity of its manufacture and construction, as well as the design of the output circuit under the console , the latter did not find application in the practice of constructing workings on an industrial scale.

A well-known design of trapezoidal lining with the use of tops with rounded sections at their ends, ensuring their hinge-free connection with the uprights (Copyright certificate SU 1081353 A, Bul., No. 11 of 03.23.84, Stesin EA), designed to reinforce two mating between workings using a T-shaped element. In this support structure, the main factor in reducing the bending moments on the roof supports is the presence of an average rack, and the influence of the rounded parts of the upper and their hingeless attachment to the posts, in this design, does not significantly affect the amount of bending moment. In addition, the use of this type of support structure for fastening newly constructed workings is technically and economically inexpedient.

Patent RU 2065966 C1 (Moscow State Mining University), 08.27.1996, provides for the fastening of excavations of an arched shape when using two types of rolled products: box-shaped - for the manufacture of racks and a special profile - for the upper with adjusting the friction forces in the compliance nodes.

The exceptional complexity of the design of the ductility nodes according to the patent RU 2065966 C1 and the uncertainty of setting the decay forces in them, which can lead either to excessive ductility or to the transfer of its work to hard mode, as well as the use of two types of rolled products for its manufacture, does not meet the requirements of mass production and use of such a support structure. At the same time, the nature of the stresses acting in the elements of such a lining is similar to that acting on the same sections of the lining (with the same values of the external load) when using typical designs of arch lining and does not completely correspond to the nature of the stresses acting in the elements of the lining of a trapezoidal shape.

The closest analogue of our proposal, widely used in the practice of constructing trapezoidal mine workings using the special SVP profile, is made in accordance with the requirements of GOST Ρ 53960-2010.

In this regard, the design of the trapezoidal lining (GOST Ρ 53960-2010. Support metal pliable frame. The lining is trapezoidal. General technical conditions. - Moscow: Standartinform, 2011, p. 7, Figure 1) without the use of additional racks under the top is adopted as a prototype .

The design of the prototype is shown in the drawing (see Fig. 1).

The main disadvantage of the construction of the trapezoidal lining according to the prototype is the articulation of the struts with the upper, which does not ensure the use of the horizontal component of the rock pressure acting on the supports to reduce the bending moment perceived by the upper from the action of the vertical component of the rock pressure.

An analysis of the known constructions of analogues and the prototype of the trapezoidal lining shows that only in the design according to a.c. S.U. 1081353 A insignificantly provides the influence of the lateral component of rock pressure as an active factor in reducing the bending moment on the upper lining. In other designs of the trapezoidal lining, including the prototype, the interaction of the horizontal component with the vertical is not provided.

The aim of the invention is to increase the bearing capacity of the frames of the trapezoidal lining from a special profile by reducing bending moment in the upper due to the impact of lateral loads on it, transmitting the bending moment of the opposite direction to the upper, while ensuring the limit value (provided by the project) of the values of vertical and horizontal flexibility.

These results on the proposal are achieved due to the hinge-free connection of the straight racks and the upper platform into the frame by means of rounded elements with straight sections at their ends by nodes of vertical and horizontal flexibility of the lining with devices to limit the displacement of their elements from the design position, ensuring stability of the lining in a flexible mode and smooth its transfer to hard mode with the exhaustion of the vertical and horizontal design compliance of the lining due to the growth of friction and crushing forces The material on the contact of the beginnings of the bends of the rounded sections with the elements of the compliance nodes.

The following graphic material with elements of compliance nodes is attached to the claimed proposal: 1 - trapezoidal support structure according to the prototype (GOST R 53960-2010) (see Fig. 1); 2 - the construction of the trapezoidal lining from a special profile with the control of compliance and the mode of its operation upon request. The design of the proposed version of the trapezoidal lining of the special profile is shown in FIG. 2. The lining consists of two straight racks 1 and the upper 2, equal to the overall dimensions of the development, taking into account the dimensions of the rounded elements 3 lining. Rounded elements 3 with a radius of not more than 0.5-0.7 m have straight sections at their ends equal to the vertical 4 and horizontal 5 design flexibility of the lining and the size of the overlap in the compliance nodes. Verkhnyak and strut supports are connected to the frame by means of typical flexibility units when their ends are located from the beginning of the fillet elements 3, equal to the design support flexibility. The retention of compliance elements (clamps) in the design position relative to the ends of the uprights and the upper tower is provided by plug-in stops 6, with supports 7 and 8, respectively, into the ends and shelves of the uprights and the upper tower without their fastening.

The proposed design of the trapezoidal lining ensures its operation in the initial period in a compliant mode of operation and smoothly transfers it to hard mode, when the rounded sections of elements 3, in contact with the corresponding parts of the ductility nodes, begin to experience inelastic deformations, which leads to a significant decrease in the flexibility of the lining and causes it transfer to hard mode.

This interposition of the lining elements is objective information about the need to strengthen it to exclude emergency situations and to ensure the minimum allowable gaps between the lining and the rolling stock and equipment.

Limiters 6 prevent the displacement of the elements of the compliance nodes from their design position and hold them in place in the process of contacting them with the rounded sections of the elements 3, help stabilize the operation of the lining in a compliant mode and smoothly transfer it to hard mode.

The hinge-free mounting of the support frames using rounded elements 3 ensures the interaction of lateral loads with vertical. Based on the assessment of the stress state parameters in the lining elements, it was found that the proposed design provides a significant reduction in the magnitude of the bending moment in the upper and the appearance of bending moments in the regions of the contour of the elements 3 and the compliance nodes of the lining frames. In this case, the vectors of bending moments in these zones are directed toward the massif, as a result of which their value will decrease under the influence of rock rebounds, the vector of which is directed in the opposite direction.

The main differences between the proposed construction of the trapezoidal lining from the known analogues and the prototype is that the connection of the lining elements to the frames is made by the joints of the malleability to the rounded elements with straight sections at their ends, equal to the total values of the malleability of the lining and lapping in the nodes of flexibility, while ensuring the sizes from the beginning rounding to the end parts of the compliance nodes, equal to the vertical and horizontal design compliance of the lining, respectively. To ensure the stability of the support in a supple mode and smoothly transfer it to hard mode, the elements of the suppleness nodes are provided with limiters that hold them in the design position.

In the proposed design of the trapezoidal lining, a smooth transfer of its work to the hard mode is provided due to the increase in the efforts of pressing the lining elements by the compliance nodes at the contact with the rounded zones and the increase in the friction and crushing forces of the material of these lining sections.

The hinge-free mounting of the lining frames using rounded elements and ductility nodes provides a reduction in the bending moment on the upper due to the influence of the horizontal component of the pressure of the array, which is perceived and transmitted by the uprights to the upper on the bending moment in the opposite direction.

The proposed design of the trapezoidal lining with elements of control of the mode of its operation provides information on the increase in the load on the lining to the maximum level and the need for its strengthening without the use of special sensors or complex devices for adjusting the compliance nodes.

Experimental studies of rock pressure parameters found that with inclined and steep bedding and their high bedding and heterogeneity characteristic of coal formation rocks, horizontal loads on the lining can be significant and in some conditions comparable with the vertical load, and if disjunctive disturbances are present, they can exceed her several times. Under these conditions, a decrease in the bending moment on the upper lining, due to horizontal pressure, can be significant, which will significantly increase the bearing capacity of the trapezoidal lining frames. Based on a quantitative assessment of the efforts in the frames of the lining of the proposed design, it was found that it allows to increase the bearing capacity of the frames by 1.1-1.5 times with the ratio of vertical to horizontal load ranging from 3.0 to 1.0.

The claimed construction of the lining can be manufactured at enterprises having equipment for the production of metal frame lining from a special profile of both trapezoidal and arched cross-sectional shapes. Since the radius of the rounded lining element is constant for all sizes of lining provided by GOST Ρ 53960-2010, it is recommended to bend the rounded element in special forms to increase productivity, manufacturing accuracy and eliminate plastic deformations of the cross-sectional shape of a special profile. Rounded elements of the same size can be used in most conditions for fastening workings of various sections, which, ultimately, reduces the cost of their production.

The economic effect of the invention, in comparison with the prototype and the known designs of trapezoidal supports, is achieved mainly by increasing the bearing capacity of the supports, which will allow, in most conditions of the construction of the workings, to increase the installation step of the supports in 1.2-1.5 times or expand the scope of the trapezoidal lining without installing an intermediate rack or reduce their number. This will reduce the intensity of the lining and the specific labor costs for its construction. The cost of manufacturing the roof supports of the proposed design will not significantly exceed the cost of manufacturing the roof supports according to the prototype, since the additional costs of manufacturing rounded elements, ductility nodes and limiters are partially covered by the costs of manufacturing five straight-line (instead of three) roof supports and nodes of the hinged joints of the uprights and the top. A certain increase in the cost of manufacturing roof supports is significantly less than the economic effect of its use due to a decrease in the specific laboriousness of its construction and operating costs with a higher reliability of the roof support.

Breaking of the rock in the area of interfacing of the uprights with the upper by the prototype takes place in a clamped environment, therefore it is very energy intensive and with any methods of penetration is associated with significant sorting of the rock in these areas. This leads to a decrease in the stability of the workings due to the high roughness of the surface contouring the production in these areas. At the same time, the complexity of wedging the nodes of the mates of the uprights with the upper increases significantly. The presence of fillets at the interface of the upper with the uprights allows to improve the quality of the contouring of the mine, increase its stability and reduce the overkill of the rock.

Visual control of the relationship of the elements of the limiters and the nodes of the support lining allows you to get information about the condition of the lining and the increase in load to the maximum level with exhaustion of compliance.

Claims (1)

Trapezoidal lining with control of the operation mode, including two straight racks and an upper, connected to the frame by two rounded elements with straight sections at their ends with malleability nodes with limiters, characterized in that to increase the load-bearing capacity of the lining, due to the horizontal component of the pressure of the array acting on the upper due to the hinge-free connection of the ends of the uprights and the upper platform in the frame with nodes of vertical and horizontal compliance of the lining with rounded elements with a radius of not more than 0.5- 0.7 m, with straight sections at their ends equal to the vertical and horizontal design compliance of the lining and the size of the overlap in the compliance nodes with limiters eliminating their displacement from the design position, which ensures stable operation of the support in a flexible mode and smooth transfer of its work to hard the mode of exhaustion of the design flexibility of the lining, due to the growth of friction and crushing of the material of the mating lining elements at the contact of the beginnings of the bends of the rounded sections with the elements of the compliance nodes.

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