RU2101509C1 - Sectional power support for sloping seams of above-medium thickness - Google Patents

Abstract

FIELD: mining industry. SUBSTANCE: this relates to working strata minerals, primarily coal seams. Sectional power support has sections with cover, hydraulic props, guarding, guide mechanism, hydraulic rams for advance, device for work face guarding. Support sections in stoping face are divided into functional groups which are formed by supporting-correcting sections, with linear sections located between them. Covers of supporting-correcting sections are provided with hitching units and flexible links with hydraulic rams arranged successively over length of stoping face. Hitching units of supporting-correcting sections are located on covers of sections in propless space of support between hydraulic props and work face guarding with possible turning of flexible links and hydraulic rams in planes of supporting surface of covers and lateral plane of sections. In upper functional group adjacent to ventilation drift, upper supporting-correcting section is provided with hitching unit located on base, flexible link in this case can be diagonal. Hitching unit can be in the form of bracket rigidly connected with supporting surface of cover or base of supporting-correction sections in their inner space and provided with cylindrical end with groove for seating double-arm journal. One arm of it by means of hinge with axle located in perpendicular to groove axis is connected with hydraulic ram, second arm has end bore and inserted through it is flexible link in the form of round-link chain, and detent for possibility of changing length of flexible link and its fastening in journal. EFFECT: high efficiency. 2 cl, 4 dwg

Description

 The invention relates to the mining industry. The object of the invention is the mechanized support for inclined formations above average power in the system of complex mechanized treatment faces during underground mining of stratified mineral deposits, mainly coal.

Known integrated mechanized support for inclined formations above average power, consisting of separate, not connected with each other and with a common base of groups of three sections of the "three", located 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 sections are moved using hydraulic jacks. The downstream section to ensure its stability is connected to the middle base section by 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 segments of the chain [1]
The disadvantage of this lining 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, the complete support is not amenable to automation.

The closest known to the claimed is the aggregate mechanized lining for inclined formations above average power, including sections having an overlap, hydraulic stands and guards, a guiding mechanism, hydraulic ram jacks and a device for guarding the face [2]
However, such a lining does not ensure safety due to the fact that the convergence of the massif from the roof leads to a different subsidence of the overlapping adjacent lining sections and their possible stepwise position. In addition, the main passage for the operator should be located, according to safety requirements, in the inter-rack space of the roof support sections protected from bottomhole.

 The task to which the invention is directed, is to increase the safety and functional reliability of the use of aggregate mechanized lining in conditions of inclined formations above average power.

 To solve this problem, aggregate mechanized support for inclined formations above average power, including a section having overlap, hydraulic stands, guards, a guiding mechanism, hydraulic jacks for moving and a device for guarding the face, is divided into functional groups of sections formed by supporting-correcting sections, between which linear sections, and the floors of the supporting-correcting sections are equipped with trailed devices and are equipped with mutually the bottom of the bottom with flexible connections with hydraulic jacks, while the towed devices of the support-correcting sections are placed on the sections of the sections in the non-rotational space of the lining between the hydraulic stands and the devices of the bottom face and are made with the ability to rotate the flexible connections and hydraulic jacks in the planes of the supporting surface of the floors and the transverse plane of the sections. In the upper functional group adjacent to the ventilation drift, the upper supporting-correcting section may have a towing device located on the base, and the flexible connection may be located diagonally. In addition, the trailing device can be made in the form of a bracket rigidly connected to the supporting surface of the floor or the base of the support-correcting sections in their internal space and provided with a cylindrical tip with a groove on which a two-arm trunnion is located, with a hinge, with one arm using a hinge with an axis located perpendicular to the axis of the groove, is connected with a hydraulic jack, and the second shoulder is made with an end bore into which a flexible connection in the form of a round link chain is passed and a clamp for the possibility of changing the length of the flexible connection and its fixing in the pin.

 In FIG. 1 depicts a support, a top view; in FIG. 2 section along AA, rotated; in FIG. 3 section lining, side view; in FIG. 4 node I in FIG. 1 (tow hitch, general view).

 Aggregate mechanized lining for inclined formations above average power includes sections having an overlap 1, a hydraulic stand 2, a base 3, a guard 4, a guiding mechanism 5, hydraulic ram jacks 6 and a device for guarding the face 7.

 The lining sections in the working face are divided into functional groups L, formed by the support-correcting sections A, between which the linear sections B are placed, and the overlappings of 1 support-correcting sections A are equipped with trailing devices (unit I) and are equipped with flexible flexible sequentially located along the length of the working face by connections 8 with hydraulic jacks 9. Trailer units-nodes I of support-correcting sections A are placed on the overlap of 1 sections in the non-rack space of the lining between the hydraulic pillars 2 and the fence device bout 7 and rotatable flexible links 8 and 9 jacks in planes overlap one support surface and lateral axis section 10 (A-D).

 In the working face with aggregate mechanized support, the upper functional group adjacent to the ventilation drift can be equipped with a tow hitch located on the base 11 above the section located in front of the hydraulic stands 2 and equipped with a diagonal flexible connection 12 with a hydraulic jack 9 connected to the base 11 and with overlapping 13 of the section located in the group through trailing devices.

 The hitch can be made in the form of a bracket 14, rigidly connected with the supporting surface (floor 1 or base 3) of the support-correcting sections in their inner space, equipped with a cylindrical tip 15 with a groove 16, on which the two-arm axle 17 is rotatably mounted the shoulder of which 18, by means of a hinge with an axis 19, perpendicular to the axis of the groove 16, is connected with a hydraulic jack 9, and the second shoulder is made with an end bore 20, into which a flexible connection 8 (or 12) in the form of round links second latch circuits 21 and 22 for the possibility of changing the length of the flexible connection 8 (or 12) and its fixing in the pivot 17. The pin 17 rotatably around the cylindrical bore 16, tip 15, arm 14 is attached by the ring 23.

 The downhole conveyor 24 is made with skis 25 with the possibility of approaching under it the bases of 3 sections of powered roof supports during their movement. Overlappings of 1 roof support sections are also equipped with 26 power sliding sides.

 Aggregate mechanized support for inclined formations above average power works as follows.

 In the initial position, the conveyor 24 is moved towards the bottom of the formation, and the sections of the powered support are separated from the conveyor by the size of the movement step.

 As the fossil is removed by a mining machine, for example a combine harvester, and moved along the conveyor 24, for example, from the lower part of the lava to the upper, sections of the powered roof are sequentially unloaded from the rock pressure and moved to the face, securing the freshly exposed roof.

The power movement of the sections of the powered roof support is carried out by hydraulic jacks 6, covering each section, and the directional movement of the sections is carried out by skis 25 and power barriers 4. The conveyor 24 is kept from sliding down the dip with an angle α _pad by the bases 3 of the roof supports through the skis 25 of the conveyor 24.

 When unloading and moving in the functional group L of the support-corrective section of the support A, located on the dip side of the formation (Fig. 2), it is held and adjusted by flexible coupling 8 and a hydraulic jack 9 with a force P relative to the expanded support-corrective section A, located in functional group from the side of the uprising of the reservoir. After completion of the process of moving it bursts between the roof and the soil of the reservoir, and the flexible connection 8 with the hydraulic jack 9 is partially weakened. Linear sections B are moved in the space between the support-corrective sections A inside the functional group and, if necessary, are adjusted by means of the sliding sides 25 of the floors 1 from the support to the lower located support-corrective or linear section.

 Equipping the support-correcting sections with mutually flexible couplings 8 successively arranged along the bottom of the working face 8 with hydraulic jacks 9 makes it possible to correct the support-corrective section located in one functional group from the side of the formation uprising by means of the support-corrective section located in another sequentially located functional group with side of the uprising of the reservoir, which gives the device absolute reliability. From FIG. 2 it follows that the proposed device aggregate mechanized lining eliminates the possibility of failure of the functioning of the lining system even when unloading any section in a group of cases, for example, the formation of a dome over the lining (Fig. 2, the middle part), etc.

 The placement of the trailed devices (nodes I) on the ceilings 1 in the non-enclosed space of the lining between the water pillars 2 and the face fence device 7 (Fig. 3) ensures the safety of the operator in the space protected from the bottom and from flexible power connections between the water columns 2 and the guard 4.

 The provision of mechanized support in such a way that in the working face the upper functional group adjacent to the ventilation drift and formed by supporting-correcting sections, in which the base of section 11 located above the group has a towing device (unit I), located in front of the hydraulic posts 2 and equipped with a diagonal flexible connection 12 with a hydraulic jack 9 with overlapping section 13 located in the group below, ensures the reliability and safety of the functioning of the powered roof support also in case of loss of pressure from the roof s uppermost group of supporting-correction section, for example in the presence of voids in the dome and above the roof bolting (FIG. 2, upper part).

 The implementation of trailed devices with the ability to rotate flexible couplings 8 and 12 and hydraulic jacks 9 in the planes of the supporting surfaces of the floors 1 and the base 3 and the transverse plane of the DD sections also helps to increase the safety and functional reliability of the aggregate mechanized lining device for inclined formations above average power.

 The implementation of trailed devices (nodes I) with the ability to quickly change the length of the flexible connections 8 and 12 and their fixation extends the functionality of the lining.

Claims (3)

 1. Aggregate mechanized lining for inclined formations of higher power, including sections having an overlap, water stands, guards, a guiding mechanism, hydraulic jacks for moving and a face fence device, characterized in that the lining sections in the working face are divided into functional groups formed by supporting-correcting sections between which linear sections are placed, and the floors of the supporting-correcting sections are equipped with trailed devices and are equipped with mutual successively arranged Line stope flexible links with hydraulic jacks, the hook device musculoskeletal correcting section slabs placed on sections besstoechnom space between the lining and devices gidrostoykami fence face and rotatable flexible linkages and hydraulic jacks in planes bearing surface and overlaps the transverse plane sections.  2. The support according to claim 1, characterized in that in the upper functional group adjacent to the ventilation drift, the upper support-correcting section is equipped with a towing device located on the base, and the flexible connection is made diagonal.  3. The support according to claims 1 and 2, characterized in that the towing device is made in the form of a bracket rigidly connected to the supporting surface of the floor or the base of the support-correcting sections in their inner space and provided with a cylindrical tip with a groove on which it is rotatably mounted a two-arm trunnion, one shoulder of which is connected with a hydraulic jack with a hinge with an axis located perpendicular to the axis of the groove, and the second shoulder is made with an end bore into which a flexible connection in the form of a circle is passed ozvennoy chain and lock to be able to change the length of the flexible connection and secure it in the journal.

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