RU2058492C1 - Powered support assembly for sloping beds - Google Patents

Abstract

FIELD: mining industry. SUBSTANCE: powered support assembly has sections with base, hydraulic columns and roof. Guiding beams positioned between sections have front ends pivotally connected with conveyor and rear ends connected with section base through hydraulic trolley jacks positioned in guiding beams, with sections being disposed at both sides of guiding beams. Conveyor is mounted at an angle to longitudinal axes of guiding beams and staged support sections. Guiding beams are connected with conveyor through vertical pivot joints. Guiding beams are provided with projection positioned on their rear ends. Sections are divided into groups, in which base of higher section and roof of lower section are provided with brackets having flexible member for coupling with hydraulic jack. Flexible member is positioned within column spacing of section at an angle to longitudinal axes of columns in parallel with conveyor axis. EFFECT: increased efficiency and enhanced reliability in operation. 6 cl, 5 dwg

Description

 The invention relates to the mining industry. The object of the invention is a complete-aggregate mechanized support for inclined formations in the system of complex-mechanized and automated working faces during underground mining of stratified mineral deposits, mainly coal.

Known complete mechanized support for inclined formations, consisting of separate groups not connected with each other and with a common base of three sections of "triples", placed along the length of the inclined face. Every three sections of the "three" are interconnected by a beam located in the transverse direction. The middle section in the group forms a single structural unit with the beam, relative to which both adjacent support sections are moved using hydraulic jacks. The downstream section to ensure its stability is connected to the middle base section by means of a diagonally located hydraulic jack and chain segments. To adjust the directional movement of the lower section, use a hydraulic jack located in the plane of the reservoir across the sections and connecting the lower section to the upper one by means of chain segments [1]
The disadvantage of complete mechanized support is the high complexity of the work when moving the sections, associated with the need to adjust the position of the sections in the plane and the dip of the formation and clearing intersection gaps from collapsed rocks in the interval between the groups of sections "triples". In addition, this mechanized lining with a perpendicular arrangement of the base beam, and hence the bottom of the formation relative to the axes of the sections, does not meet the safety criteria in the conditions of inclined formations, it is unreliable, labor-consuming to maintain and cannot be automated for the above reasons.

Also known is a complete-aggregate mechanized lining, including linear sections having ceilings, water stands and bases, guide beams located between the sections, the front ends of which are pivotally connected to the conveyor, and the rear with the help of hydraulic jacks of the movement located in the guide beams, with the bases of the sections located on both sides of the guide beams. Moreover, in order to meet the safety criteria in conditions of inclined seams, the conveyor is located at an angle to the longitudinal axes of the guide beams and support sections, which are arranged in steps, the hinges of the connection between the guide beams and the conveyor are vertical, and each guide beam is made with a protrusion at the rear end, which is relatively longitudinal the axis of the conveyor is located on the side of an acute angle formed by the longitudinal axes of the guide beams and the conveyor [2]
A disadvantage of the known complete-aggregate mechanized lining in conditions of inclined formations with an unstable roof is that it does not have the means to ensure stability and correction of the upper base of the lining of the ceilings relative to the lower base of the bases when the sections are stepped in terms of layout.

 Mechanized roof supports are also known. St. N 1227815, class E 21 D 23/00; N 976094, CL E 21 D 23/04; N 1086180, CL E 21 D 23/00; N 1320440, class E 21 D 23/12, in which, to ensure the stability of the lining sections in inclined formations, the lining sections are paired by means of hydraulic jacks located in the inner space of the sections at an angle to the longitudinal axis of the sections and obliquely relative to the vertical plane passing in the longitudinal axis of the sections, the hydraulic jacks being connected one end with an overlap, and the other with the base of a adjacent section or conveyor.

 The disadvantages of these mechanized supports are the difficulty of managing the adjustment of the spatial position of the sections, the clutter of these devices of the working space of the human operator in the supports, the increased danger and the inability to use the devices in the working faces with their diagonal arrangement relative to adjacent workings.

 The aim of the invention is to increase the reliability of operation, reducing the complexity of maintenance and improving safety when using lining in the face, located diagonally relative to adjacent workings.

 The industrial applicability of the proposed complete-aggregate mechanized lining for inclined formations is realized by a combination of features, which are linear sections consisting of a base, hydraulic stands and overlapping guide beams installed between them, the front ends of which are pivotally connected to the conveyor, and the rear ends with the help of hydraulic jacks of the shift placed in guide beams, with the bases of the sections located on both sides of the guide beams, and the conveyor is located at an angle to the longitudinal axes the guide beams and the support sections, which are arranged in steps, the hinges of the guide beams with the conveyor are vertical, and each guide beam is made with a protrusion at the rear end, while the protrusion relative to the longitudinal axis of the conveyor is located on the side of an acute angle formed by the longitudinal axes of the guide beams and the conveyor, the linear sections of the lining in the working face are divided into groups, in each of which the base of the upstream boundary section and the overlap of the downstream boundary section are provided with Stein, which are equipped with a mutual flexible connection hydraulic jack, situated in the inner space group mezhstoechnom space sections at an angle to their longitudinal axes and parallel to the conveyor axis.

 The brackets for flexible connection are made in the form of a bracket and two protruding stops rigidly connected to the supporting surface of the sections, for example, ceilings, the bracket being located in the plane of the transverse axis of the section. A flexible connection is made in the form of segments of a rope or chain and placed in an elastic shell such as a rubberized sleeve.

 Figure 1 shows a complete aggregate mechanized support for inclined formations, a top view where part of the sections is shown without overlap; in FIG. 2 is a view of the support for the face, section AA in figure 1; figure 3 section lining, side view; in FIG. 4 view of the ceiling from below with a bracket and flexible connection; in Fig.5 view B in Fig.4.

The mechanized-aggregate mechanized lining for inclined formations includes linear sections consisting of a base 1, hydraulic stands 2 and floors 3, guide beams 4 installed between them, the front ends of which are hinged 5 to the conveyor 6, and the rear using hydraulic jacks 7 are placed in guide beams 4, with bases 1 of the sections located on both sides of the guide beams 4. The conveyor 6 is located at an angle β to the longitudinal axes OO of the guide beams 4 and the support sections, which are located in steps, communication hinges apravlyayuschih beams 4 with the conveyor 6 are vertical, and each guide beam 4 is provided with a projection 8 at the rear end, which relative to the longitudinal axis O ₂ -O ₂ of the conveyor 6 is located by the acute angle formed by the longitudinal axes ρ guide beams and conveyor OO O ₂ - O ₂ .

The linear sections of the lining in the working face are divided into groups L, in each of which the base 9 of the upper boundary section and the overlap 10 of the lower boundary section are equipped with brackets 11, which are equipped with a mutual flexible connection 12 with a hydraulic jack 13 located in the inner space of the section group in the inter-pillar space under angle to their longitudinal axes O ₃ -O ₃ and parallel to the axis O ₂ -O _{2 of the} conveyor 6. Brackets 11 for flexible connection are made in the form of a bracket 14 and two protruding stops 15, rigidly connected to the supporting surface sections, for example, ceilings 3, and the bracket 14 is located in the plane of the longitudinal axis O ₃ -O ₃ sections, and the stops 15 on both sides of the bracket 14 in the plane of the transverse axis O ₄ -O ₄ sections in the inter-rack space. Flexible connection 12 is made in the form of segments of a rope or chain and is placed in an elastic shell such as a rubberized sleeve.

 The overlap of 3 lining sections is provided with bottom-hole consoles 16, which can be different-sized and curved, as shown in Fig. 1, and sliding shields 17 with power elements 18. The lining sections are equipped with guide mechanisms 19 and protective guards 20.

 Complete-aggregate mechanized lining for inclined formations operates as follows.

In the initial static position, the conveyor 6 occupies a position diagonally at an angle γ relative to the direction of the formation dip α _pad , and the guide beams 4 and sections of the powered support are located in the direction of the formation α _pr

 As the fossil is excavated by a mining machine, for example, a combine harvester, and moved along the conveyor 6, for example, from the lower part of the lava to the upper, sections of the mechanized roof support are sequentially unloaded and moved to the face, securing the freshly exposed roof.

 Power movement of the lining sections is carried out by means of hydraulic jacks 7 covering each section, and the directed movement of the sections is carried out by means of guide beams 4 installed between the sections.

When moving in the group of sections L of the downstream boundary section, stabilization of its spatial position is ensured by means of a flexible connection 12 and a hydraulic jack 13. In this case, the flexible power P connection 12 of the base 9 of the upper section located in the group L with the overlap 10 located in the boundary section group and placement of the flexible power connection 12 in the interior sections of the group in mezhstoechnom space at an angle to their longitudinal axis O ₃ -O ₃ and parallel to the axis O ₂ -O ₂ of the conveyor provide a suitable expansion yc Leah P flexible coupling. The force P _in the plane of the reservoir (Fig. 1) is decomposed by the recovery force P _{in the} lower boundary section and the force P _CR in the direction of movement of the section, improving the conditions for its movement. The force P _in the plane of the transverse axis of the section (Fig. 2) is decomposed by the recovery force P _{in the} lower boundary section and the force P _p in the direction of the formation soil, improving the conditions for its stabilization. The stabilization of the spatial position of the sections within the group L in the process of their movement is carried out by means of sliding shields 17 with power elements 18.

 The flexible connection bracket 11 provides quick and reliable fastening of the flexible connection 12 in the supporting surfaces of the mechanized roof support section, for example, ceiling 3, as shown in Figs. 4 and 5. During the installation of the flexible connection 12, it is weakened by a hydraulic jack 13, the flexible connection loop 12 inserted under the bracket 14 and put on the stops 15, protruding above the bracket 14, the flexible connection is again tensioned.

 The proposed device of a complete aggregate mechanized lining for inclined formations also provides the possibility of any other scheme of movement of sections of a mechanized lining. The number of lining sections in group L is determined by the operating conditions depending on the power and angle of incidence of the formation, the stability of the direct roof, the intended purpose of the lining in the system of complex mechanized and automated faces, etc. The number of functional groups L along the length of the lava is determined similarly. There can be one L group in the face, for example, at the lower end section of the lava. Functional groups of sections can be arranged sequentially along the length of the lava or dispersed. The proposed device of a complete aggregate mechanized lining for inclined formations provides increased efficiency, reliability and safety and can function automatically.

Claims (6)

 1. COMPLEX-MECHANIZED MECHANIZED FASTENERS FOR TILTED LAYERS, including linear sections, consisting of a base, hydraulic stands and floors, guide beams installed between them, the front ends of which are pivotally connected to the conveyor, and the rear ends with the help of hydraulic jacks for moving placed in the guide beams with the bases of the sections located on both sides of the guide beams, in which the conveyor is located at an angle to the longitudinal axes of the guide beams and the support section, which are located in steps, communication hinges the guide beams with the conveyor are vertical, and each guide beam is made with a protrusion at the rear end, and the protrusion relative to the longitudinal axis of the conveyor is located on the side of an acute angle formed by the longitudinal axes of the guide beams and the conveyor, characterized in that the linear sections of the lining in the face are divided into groups, in each of which the base of the upper boundary section and the overlapping of the lower boundary section are equipped with brackets that are equipped with a mutually flexible connection with rodomkratom situated in the inner space group mezhstoechnom section in space at an angle to their longitudinal axes and parallel to the conveyor axis.  2. The lining according to claim 1, characterized in that in the face is placed one group of sections on the lower end section of the lava.  3. The support according to claim 1, characterized in that the groups of sections are placed sequentially along the entire length of the working face.  4. The support according to claim 1, characterized in that the groups of sections are dispersed along the length of the working face.  5. Hold on PP. 1 to 4, characterized in that the brackets for flexible connection are made in the form of a bracket and two protruding stops rigidly connected to the supporting surface of the section, for example, ceilings, the bracket being located in the plane of the longitudinal axis of the section, and the stops on both sides of the bracket in the plane of the transverse axis sections in the inter-rack space.  6. Hold on PP. 1 to 5, characterized in that the flexible connection is made in the form of segments of a rope or chain and placed in an elastic shell such as a rubberized sleeve.

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