FR2529614A1 - Mechanised retaining section. - Google Patents

Abstract

The invention relates to coal-extraction techniques. The retaining section which is the subject of the invention is of the type comprising particularly a hydraulic jack 13 arranged in such a way that its movable element 14 is displaced transversely relative to the displacement of the movable element 10 of the hydraulic jack 7 and cooperates with the pusher 11 by means of a slide 15 connected kinematically to the sole plate 3, and is characterised in that the pusher 11 is arranged on the wall 12 and, during the displacement of the mechanised retaining section, serves as a slideway for the slide 15 which is constantly laid against the pusher 11 by the movable element 14 of the other hydraulic jack 13, of which the chamber on the piston side is constantly connected to a pressure source for this purpose, whilst the working-face part 4 of the sole plate 3 can rise above the wall in the event of a variation in the height of the hydraulic props, thus keeping the cap in contact with the roof. The invention can be used both in boom-type supports and in boom-type and shield-type supports.

Description

The present invention relates to mechanized coal extraction and in particular relates to a mechanized retaining section
The invention can be used in arrow supports as well as in arrow and shield supports.

 The invention can be applied most effectively to the mechanization of stripping of layers with a small opening (less than 1 m).

 The invention can also be applied to the mechanical extraction of other minerals.

 Mechanized support sections are known, the movement of which is carried out without interruption of contact with the roof and which can be used when the roofs are unstable, as well as to eliminate the need to clean the caps by hand.

These support sections include a sole in contact with the wall (the ground) and a cap coming into contact with the roof, which are connected together by hydraulic props9
A hydraulic cylinder incorporated in the sole of the section and the end of the movable element of which is connected to a conveyor is used for independent movement of the section and of the conveyor (cf. the book by VeN. Khorine, 'Hydraulic support of works of size ", p. 145, editions ''Nedra'l, 1973) o
In this mechanized retaining section, the contact of the bonnet with the roof during its movement towards the working face is ensured by maintaining residual pressure in the hydraulic props.

Given the presence of two friction planes (cap-roof and sole-wall), the displacement of the support section with the cutting face imposes significant efforts on the hydraulic cylinder for shifting the section
The use of such a retaining section becomes impossible when the walls are irregular or when they are soft or flooded.

 The hydraulic system of the retaining section is complicated by the fact that it must include a device intended to maintain a residual pressure in the props.

 Another type of mechanized retaining section is known, comprising a sole connected to a shield on the side of the caving and a cap connected by articulation to the shield, and by hydraulic props, to the sole.

 The sole of the retaining section is connected to the conveyor by means of a hydraulic shifting cylinder and comprises on the face of the face another hydraulic cylinder, with relatively short stroke, supported on a shoe connected by articulation to the sole and resting on the wall (cf. patent NO 2,291,345 issued in France).

 During the movement of this support section, the p1e cEtd bont of size of the sole is raised above the wall by another hydraulic cylinder with short stroke, whose movable element rests on the shoe at a certain distance from the articulation which connects it to the sole rotates the shoe from a certain angle.

 Such an embodiment of the retaining section allows the insertion of the sole into the wall during the shifting of the pile towards the cutting face, but this results in significant unit pressures of the shoe on the wall because of its weak surface of support, which inevitably leads to the depression of the shoe in the wall and to a reduction in the efficiency of lifting of the sole, especially on soft or flooded walls.

 When moving such a support section without interrupting its contact with the roof, the unit pressures of the shoe on the wall are even greater, so that it is necessary to use a shifting cylinder ensuring a more great tensile force.

 A mechanized retaining section was horned, which can be considered as a prototype of the present invention, and which comprises a cap connected by hydraulic props to a sole composed of a part on the caving side and a part on the pruning side. The caving side of the sole has a hydraulic cylinder for independent movement of the conveyor and the section; for this purpose, its mobile element is connected to one end of a pusher, the other end of which is connected to the conveyor provided with a loading ploughshare.

The front face side of the sole has another hydraulic cylinder mounted so that its movable element is connected to a slide through which the pusher passes. The slider is kinematically connected to the sole to release transverse forces from the mobile element of the other hydraulic cylinder. The chambers of the two hydraulic cylinders are connected in parallel to a pressure source (see author's certificate NO 447517 issued in the USSR
Such an embodiment of the mechanized support section allows
a) during the shifting of the conveyor (the chambers on the piston side of the hydraulic cylinders being in action): the transmission to the loading share of the conveyor of the force developed by the other hydraulic cylinder, by means of the slide clamped by this cylinder hydraulic against the pusher connected to the conveyor, and this, to keep said ploughshare tight against the wall
b) during the movement of the retaining section towards the cutting face (the rod side chambers of the hydraulic cylinders being in action): the tightening of the cutting side side of the sole of the supporting section against the wall by the force developed by the other hydraulic cylinder and transmitted via the same slider raised above the wall by this hydraulic cylinder at the same time as the pusher passing inside the slider, to increase transverse stability of the section.

 The fact of providing a slide surrounding the pusher makes it possible to clamp the latter against the wall only when the section is stationary; during the movement of the supporting sectinn, the slide comes into contact with the wall, which creates additional resistance to the movement of the section.

The displacement of such a support section without interrupting its contact with the roof n1 is possible only thanks to the maintenance of a residual pressure in the hydraulic props; in this case, the force developed by the rod chamber of the other hydraulic cylinder is not
necessary only to remove the contact between the slide and the wall, while the tightening of the sole against the wall under the action of this hydraulic cylinder causes additional resistance to movement of the section.

The residual pressure in the hydraulic props and the force developed by the rod side chamber of the other hydraulic cylinder generate a significant unit pressure on the wall, which, in turn, makes it impossible to use such a section of support on soft or irregular walls.

 It has therefore been proposed to develop a mechanized retaining section, the movement of which would be effected without interrupting its contact with the roof and the design of which would reduce the forces necessary for its displacement towards the working face.

 This problem is solved with the aid of a mechanized size retaining section, of the type comprising a cap connected by hydraulic props to a sole, the caving side of which comprises a hydraulic cylinder which allows movement independent of the conveyor and the mechanized retaining section, the movable element of this air cylinder, at this end, connected to one end of a pusher whose other end is connected to the conveyor, while the front face part of the sole has another hydraulic cylinder, arranged so that its mobile element moves transversely to the movement of the mobile element of the hydraulic cylinder and cooperates with the pusher by means of a slide kinematically connected to the sole, characterized, according to the invention, in that the pusher is arranged on the wall (the ground) and, during the movement of the mechanized support section, serves as a slide for the slide which is constantly tightened against the pusher by the mobile element of the other hydraulic cylinder, the piston chamber of the latter being, at this year, in constant communication with a pressure source, the front side of the sole being able to s '' move away from the wall if the height of the hydraulic props varies, thus keeping the bonnet in contact with the roof.

It is preferable to make a groove in the face of the slider oriented towards the pusher, and to provide on the pusher a projection engaging in this groove to stabilize the slider relative to the pusher during its movementX
Such a connection between the slide and the pusher completely excludes contact between the slide and the wall, thus preventing any damage to the slide by the wall.

 While being of relatively simple construction, the mechanized size support section making ltdSet of the present invention makes it possible to significantly reduce the forces necessary for its movement towards the cutting face, while keeping the cap in contact with the roof whatever the nature of the wall.

The invention will be better understood and other objects, details and advantages thereof will appear better in the light of the explanatory description which follows of an embodiment given solely by way of nonlimiting example, with references to non-limiting drawings appended in which
- Figure 1 shows an overview of the mechanized oeatioedesoutemnement according to the invention
- Figure 2 is a sectional view along line II-II of Figure 1.

 The mechanized support section includes a cap 1 (FIG. 1) connected to the sole 3 by hydraulic sta nons 2.

 The sole 3 includes a part 4, front face, and a part 5, caving side, coupled together by springs 6.

 In part 5 on the lightning strike side of the sole 3 is disposed a hydraulic cylinder 7 used for independent movement, on the one hand, of the conveyor 8 provided with a loading plow 9, and on the other hand, of the mechanized support section.

 The mobile element 10 of the hydraulic cylinder 7 is connected to one end of a pusher 17 disposed on the wall (the ground) 12 and whose end wall is connected to the conveyor 8.

 Another hydraulic cylinder 13 is arranged in the part 4 c3té size front of the sole 3. This hydraulic cylinder is arranged so that its movable member 14 moves transversely to the direction of movement of the movable member 10 of the hydraulic cylinder 7 and that it constantly clamps the slide 15 against the pusher; 11. The piston side chamber of the hydraulic cylinder 13 communicates permanently with an independent pressure source (not shown in the drawings).

 To completely exclude the contact between the slider 15 and the wall 12, a groove is made in the face of the slider oriented towards the pusher, while on the pusher There is a projection 16 (FIG. 2) engaging in this groove. The slider 15 is connected by an articulated tie-rod 17 to the part 4 on the cutting face side of the sole 3.

 It is also possible to provide between the slide and the sole another mode of connection for ensuring the relative movement of the slide and the sole transversely to the movement of the movable element 10 of the hydraulic cylinder 7.

 The pusher It is of relatively low height, which makes it possible to obtain a sufficiently free passage in the support when this support section is used in a layer with a small opening.

The piston side chamber of the hydraulic cylinder 13 is constantly in communication with an autonomous pressure source (not shown in the drawings;
The pressure can be adjusted by any known and appropriate means, which makes it possible to use the mechanized support section on practically any ground, by adjusting the clamping force of the shield 1 against the roof according to the mining conditions. and geological.

 The hydraulic cylinder 7 and the hydraulic props 2 are connected to the pressure source (not shown) in any known manner.

 The mechanized support section works as follows.

 In the starting position, the bonnet 1 is clamped by the hydraulic props 2 against the roof, and the sole, against the wall 12.

 Under the effect of the pressure, the hydraulic cylinder 13 clamps the slide 15 against the projection 16 16 of the pusher 11.

Before moving the support section, the height of the hydraulic props 2 is reduced by a certain value, thereby causing an extension of the same value of the hydraulic cylinder 13 at the same time. By pressing the push-button II via the slider 15, the hydraulic cylinder 13 moves aside from the wall 12 the part 4 on the cutting face of the sole 3, while keeping the bonnet in contact with the roof
When the rod side chamber of the hydraulic cylinder 7 is actuated, its movable element 10 performs a reentry movement and the support section is shifted towards the cutting face while the part 4 c8te cutting face of the sole 3 is raised above the wall and that the cap 1 is kept in contact with the roof.

During this movement, the slide 15 slides on the projection 16 of the pusher II as on a slide,
The fact that, during the movement of the retaining section, the part 4 facing the size of the sole 3 is held in the raised position above the wall 12 by the hydraulic cylinder 13 supported by the slide 15 on the pusher II as on a slide, - and that the cap 1 remains in contact with the roof, makes it possible to considerably reduce the pressures exerted on the wall by the support section and to reduce the forces necessary for the displacement of the support section.

 The fact that the pusher II is provided with a projection 16 and that the slide 15 is provided with a groove in which the said projection engages makes it possible to exclude any contact of the slide 15 with the wall 12 during the movement of the section support and thereby protect the slider against damage, as well as reducing the forces required to move the support section.

 After displacement of the support section over a certain distance towards the cutting face, that is to say when the movable element 10 of the hydraulic cylinder 7 is completely retracted, an extension of the hydraulic props 2 of the retaining section and the part 4 on the cutting face side of the sole 3 is clamped against the wall 123 The mobile element 14 of the hydraulic cylinder 13 then moves upwards under the action of the force of the hydraulic props 2, thus driving out part of the working fluid from the piston side of the piston cylinder 13. The effort with which the movable element 14 of the hydraulic cylinder 43 clamps the slide 15 against the pusher. It remains coeistant.

 This done, we put the chamber c8-tee piston of the h-ydrauliqlle cylinder 7 in coIL'n, j2q-ication with the pressin source.

 mobile element 10 of the hydraulic cylinder 7 exits and cuts the pusher II and therefore the conveyor 8 with its loading share 9 The force developed by the hydraulic cylinder 13 is transmitted to the loading share 9 of the conveyor 8 via the pusher 11.

 A prototype mechanized support including support sections produced in accordance with the invention was successfully tested in a layer opening size of 0.7 m. During these tests, the force developed by the shifting cylinder during the displacement of the support sections without interruption of contact with the roof differed only slightly from the effort required to move the same sections with interruption of contact between the cap and the roof. The sections moved easily on the uneven waist wall.

Claims (2)

 1. Mechanized size retaining section, of the type comprising a cap (1) adjacent to the roof and connected by hydraulic props (2) to a sole 530 in the caving side part (5) of which is mounted a hydraulic cylinder (7 ) for the displacement of a conveyor (8) and of the support section independently of one another, the movable element (10) of said jack being connected for this purpose to one of the ends of a pusher (11 ) whose other end is connected to the conveyor (8), while in the part (4) on the cutting face side of the sole is mounted another hydraulic cylinder (13), arranged so that its movable element (14) is moves transversely to the movement of the movable element (10) of the hydraulic cylinder (7), and cooperates with the pusher (11) by means of a slide (1-s) kinematically connected to the sole (3), characterized in that the 9th pusher (11) is arranged on the wall (12) and, during the movement of the mechanized support section, serves as e slide to the slide (15) which is constantly tightened against 16 pusher (11) by the movable element (14) of the other hydraulic cylinder (13) whose chamber on the piston side is constantly connected, for this purpose, to a source pressure, while the part (4) on the cutting face side of the sole (3) can be raised above the wall in the event of variation in the height of the hydraulic props, thereby keeping the bonnet in contact with the roof.  2. retaining section mechanized according to claim 1, characterized in that in the face of the slide (15) oriented towards the pusher (11) is formed a groove and that the pusher (11) is provided with a projection (16) engaging in said groove in order to stabilize the slide (screw) relative to the pusher (11) during its movement.