RU182240U1 - SECTION OF THE MECHANIZED FASTENING FASTENING MOUNT WITH THE COAL FORCING DEVICE - Google Patents

Abstract

The section of the powered roof support lining with a coal forced-release device contains a ceiling pivotally connected to the fence on one side, a base pivotally connected to the fence on its other side, hydraulic stands connected to the base and the ceiling, hydraulic ram jacks installed on the base, the opening, made in the fence, the screen pivotally connected to the fence and equipped with hydraulic jacks and a dynamic cleaver, the chute with the sides installed in the opening of the fence are inclined a tray attached to the fence pivotally with a possibility of rotation around the horizontal axis at the level of the lower edge of the opening from the side of the worked out space. A distinctive feature is that from the obstructed side to the fence at a level not higher than the upper edge of the opening, a metal hopper is made, made in the form of a box having one entrance from above and two exits from below, one of which is made in the alignment with an opening in the fence, the other is in the alignment with the tray, and the obstruction edge of the hopper is connected to the bases by means of metal racks Niemi support frame. The width of the hopper is equal to the width of the lining section, the length is no more than the projection length in plan from the top edge of the opening to the obstruction edge of the tray, and the width of the tray is no more than the step of installing metal racks. 4 ill.

Description

The technical solution relates to mining, in particular, to the fastening of the working face and relates to the construction of mechanized supports designed to maintain the working space in the working faces during the development of powerful seams with the forced release of coal from the subroofing layer.

A known construction of a section of powered roof support, comprising a ceiling pivotally connected to the fence on one side thereof, a base pivotally connected to the fence on its other side, hydraulic struts associated with the base and the ceiling, moving jacks mounted on the base, an opening made in the fence, a screen pivotally connected to the fence and provided with control hydraulic jacks, and a chute with sides installed in the opening of the fence. In this case, a retractable dynamic cleaver is placed in the inner cavity of the screen, directed by the cleaving element away from the working space of the lining [Pat. 155577 for a utility model of the Russian Federation, IPC E21D 23/00; Mechanized lining section of the face of a powerful seam with forced release of coal; application No. 2015117301, filed May 6, 2015, patent holder of the Institute of Law of the SB RAS, publ. 10/10/2015, bull. No. 28 (analogue)].

The disadvantage of this design is that only part of the coal of the subroofing layer can collapse into the opening in the enclosure during collapse, the other, most of this coal will fall onto the soil behind the fence, in addition, with a significant thickness of the subroofing, the geometrical parameters of the cleaver will not be enough to force destruction of the subroofing thickness by its power. An array of subroofing strata will be destroyed only due to the forces of rock pressure, and this will happen not above the outlet window, but somewhat further when the section has already passed the zone of effective coal production. In this regard, a significant part of the coal under the roof will be lost in the worked out space.

The closest analogue adopted as a prototype is a section of a powered lining for a face with a forced coal discharge device, containing a ceiling pivotally connected to the fence on one side, a base pivotally connected to the fence on its other side, and a hydraulic stand connected to the base and overlap, hydraulic ram jacks installed on the base, an opening made in the fence, a barrier pivotally connected to the fence and equipped with hydraulic jacks for control and dynamic rocks ers, trough with flanges mounted in an aperture barriers, and sloping trough shaped tray pivotally rotatable about a horizontal axis at the lower edge of the outlet opening attached to the enclosure by the goaf [Pat. 165049 for a utility model of the Russian Federation, IPC E21D 23/03; Mechanized roof support section with a face coal forcing device; application No. 2016117004, filed April 28, 2016, patent holder of the FIC UUH SB RAS, publ. 09/27/2016, bull. No. 27 (prototype)].

At the beginning of the release of the under-roofing stratum, a part of the coal of the collapsed massif adjacent to the overlap of the lining section falls into the opening and the tray, then the part that was located higher, at the very top of the formation. With a thickness of the subroofing thickness of 5-6 m (this power determines the height of the falling pieces of coal), the incident mass has a high kinetic energy, in the event of a collision with the lining section, which is converted into the corresponding dynamic effect, which can damage its individual components, for example, a gutter. Therefore, the roof support section is first moved with a closed screen - a cushion of collapsed coal is formed on the tray, which receives coal from the upper layers of the subroofing massif; then, after moving, they open the screen and produce coal. In this regard, the disadvantages of the prototype are:

- when the subroofing thickness collapses, the lumps of coal, having high kinetic energy and hitting the guard of the lining section, will bounce in the direction of the worked out space, i.e. go to the blockage;

- the greatest dynamic impact exerted by the flow of collapsed coal is perceived by the tray located on the side of the worked out space; collapsed roof rocks can put the tray out of action, which will significantly increase the operational loss of coal.

These shortcomings reduce the efficiency of the lining section for the production of coal subroofing.

The purpose of the technical solution is to increase the efficiency of the use of lining sections with a device for the forced release of coal due to the capture and temporary retention of the bulk of the coal in the subroofing layer during production.

This goal is achieved by the fact that in the section of the mechanized lining of the face with a forced coal discharge device containing a ceiling pivotally connected to the fence on one side, a base pivotally connected to the fence on its other side, hydraulic stands associated with the base and the ceiling, hydraulic jacks movings installed on the base, an opening made in the fence, a screen pivotally connected to the fence and equipped with hydraulic jacks and a dynamic cleaver, a chute with sides, installed in the opening of the fence, and an inclined tray attached to the fence pivotally with the possibility of rotation around the horizontal axis at the level of the lower edge of the opening from the side of the worked out space, in accordance with the technical solution, from the obstructed side to the fence at the level not higher than the upper edge of the opening is attached a metal hopper made in the form of a box having one entrance at the top and two exits at the bottom, one of which is made in the alignment with an opening in the fence, the other in the alignment with the tray, and the obstruction edge of the hopper the metal racks are connected to the base of the lining section, and the width of the hopper is equal to the width of the lining section, the length is no more than the projection length in plan from the top edge of the opening to the obstruction edge of the tray, and the width of the tray is no more than the step of installing metal racks.

The design of the lining section is illustrated by diagrams. In FIG. 1 shows the layout of the lining section (side view); in FIG. 2 - the same (plan view); in FIG. 3 - hopper (axonometry); in FIG. 4 - operation of the lining section during the extraction of coal of a powerful seam.

The section of the powered roof support lining with a coal forced release device comprises a base 1 pivotally connected to the fence 2 on one side thereof, which, in turn, on the other side is pivotally connected to the ceiling 3. The base 1 and the ceiling 3 are interconnected by hydraulic struts 4 . In the fence 2 is made through the opening 5 of a rectangular shape. A barrier 6, controlled by hydraulic jacks, is pivotally attached to the upper edge of the fence 2 from the side of the working space with the possibility of rotation around the horizontal axis 7. In the inner space of the barrier 6 a retractable dynamic cleaver 8 is installed, the cleaving element of which is directed away from the working space of the lining.

In the region of the lower edge of the through opening, the fence 2 is pivotally connected with the horizontal axis 9 to one edge of the tray 10, the other edge of which is connected by hydraulic jacks 11 to the base 1 of the lining section.

In the mounting chamber, the lining sections are interconnected by moving jacks (not shown) and from the side of the worked out space on the guard of each section, using pins 12, a metal hopper 13 is fixed. The hopper 13 is made in the form of a box having one entrance 14 on top and two exits, one of which - 15 is made in alignment with the opening 5 in the fence 2, the other 16 - with the tray 10 (this exit closes with the tray). The sides of the hopper, oriented vertically in the upper part, gradually taper towards the outlet window in the fencing section of the lining. The obstruction edge of the hopper is connected by two metal racks 17 with skis 18, which are a continuation of the base 1 in the direction of the worked out space. At the same time, the width of the hopper along the upper edge is taken equal to the width of the lining section, the length is equal to the projection length in plan from the top edge of the opening to the obstruction edge of the tray, the shape of the tray is assumed to be flat, and the width of the tray is taken no more than the step of installing metal racks 17.

The operation of the mechanized lining section during the excavation of a powerful flat bed is as follows. The section supports the working space of the working face due to the spread between the soil and the array of under-roof strata with a closed opening. After the section has been moved, the lower part of the subroofing massif rushes down under the action of gravity and enters through the inlet 14 to the hopper 13. Since the hopper 13 is located directly under the subroofing massif, the drop height of the beaten-off coal is relatively small, but then the kinetic energy of the incident coal flow is also small subroofing thickness. Since the screen 6 is closed, this coal is trapped in the hopper 13, forming a damping pad. Next, coal begins to flow from the layers of the subroofing layer located at a higher height; the kinetic energy of this stream is much higher, but it falls on the damping pad, without harming the construction of the lining section. At this moment, open the screen 6 and carry out the release of coal through the opening through the chute to the downhole conveyor. Since the cross section of the aperture is much smaller than the receiving section of the hopper, a damping cushion is retained during the outlet, protecting the exhaust devices. At the same time, even with the shutter closed, the entire volume of collapsed coal collapsed in the zone of responsibility of this section of coal in the form of a cone with the angle of repose of loosened coal can be accommodated in the hopper.

When the subroofing thickness collapses into large pieces, the impact energy is primarily perceived by the vertical sides of the upper part of the bunker, due to which the coal breaks up, and the dynamic impact energy is transmitted along the metal struts to the base and further to the soil of the formation.

In the case of filling the hopper with collapsed roof rocks, with the beginning of moving the roof support sections, turn the tray, opening the exit 14 from the hopper (with the screen closed) - the rock will gravity exit the hopper into the worked out space, preventing dilution of the coal flow of the subroofing thickness.

Thus, due to the presence of the hopper, the coal of the subroofing layer is captured, temporarily held, then gravity fed into the opening, providing continuous release and reducing operating losses. Due to the vertically oriented sides of the upper part of the hopper and its support on metal racks, the required resistance to dynamic loads is provided. In addition, from the side of the worked-out space, the tray is protected by metal racks, which reduces the likelihood of its failure when the roof rocks collapse, and when filling the hopper with rock, it is left in the worked-out space between the metal racks supporting the hopper, releasing it along the tray. All of the above indicates an increase in the efficiency of coal production of the subroofing stratum, i.e. to achieve the goal.

Claims (1)

The section of the powered roof support lining with a coal forced release device, comprising a ceiling pivotally connected to the fence on one side, a base pivotally connected to the fence on its other side, hydraulic stands connected to the base and the ceiling, sliding jacks installed on the base, an aperture made in the enclosure, a screen pivotally connected to the enclosure and provided with hydraulic control jacks and a dynamic cleaver, a chute with sides mounted in the opening of the enclosure and a tray attached to the fence pivotally with a possibility of rotation around a horizontal axis at the level of the lower edge of the opening from the side of the worked out space, characterized in that from the obstructed side to the fence at a level not higher than the upper edge of the opening is attached a metal hopper made in the form of a box having one the entrance is from above and two exits from below, one of which is made in the alignment with an opening in the fence, the other is in the alignment with the tray, and the obstruction edge of the hopper is connected to the base of the lining section by means of metal racks moreover, the width of the hopper is equal to the width of the lining section, the length is no more than the projection length in plan from the top edge of the opening to the obstruction edge of the tray, and the width of the tray is no more than the step of installing metal racks.

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