HU205981B - Structure for supporting mineral area particularly area being at the appointment of drift and mining - Google Patents

Abstract

The present invention relates to a structure for securing an area at the junction of a mining area, in particular a cut and a quarry, having a base element, a roof element, hydraulic couplings connecting them, and a stabilizer. The structure according to the invention consists in the fact that some of the hydraulic shafts (4 ') of the hydraulic shafts (4, 4') form a three-hinged frame structure with the base element (3) and / or the roof element (2) and / or have a stabilizing device (5). having a hinge structure enabling the movement of the roof member (2) and the base member (3) relative to each other at least two axes, preferably a three-axle joint (12). CQ EN 205 981 Figure 1 Scope of description: 8 pages (including 4 sheets)

Description

BACKGROUND OF THE INVENTION The present invention relates to a device for providing a mining area, in particular a space where a cut and quarry meet.

The device according to the invention relates to locking devices having a base member, a roof member, hydraulic supports connecting them, and a stabilizing device.

Particularly advantageous is the application of the invention to self-propelled, that is to say, movable safety devices capable of following the progress of the workplace.

With known locking devices, the stabilizer can provide a connection between its roof members and the base member as the distance between the upper and lower rock surfaces of the underground workplace changes and when the hydraulic rider slips under load or unloading, so that their position relative to one another remains sideways.

The stabilizer also plays an important role in advancing the self-propelled fuse unit. At the time of advancement, the base member is retracted, and the top contacting the upper rock surface is lagging behind the base due to friction. The ski stabilizer strives to relieve the lateral loads of the hydraulic mast connected to the sole and roof at both ends by ball joints.

The stabilizing mechanism plays a particularly important role in advancing the fusing unit with reduced tension on the bar. In this case, the frictional force between the roof element and the upper rock surface increases considerably.

Unusually high loads can hit the stabilizer when the frictional surfaces are tilted relative to the rock load due to uneven surfaces of the accompanying rock or when the entire workplace is inclined, such as in steep colonies.

Known advancement fuses can be classified into two groups in terms of the stabilizer structure. Fuses of one group only allow one-way movement, otherwise they have a rigid stabilizing structure. The other group includes solutions in which the stabilizing mechanism is adjustable, to a certain extent tolerant, flexible.

Examples of fuse units with otherwise rigid stabilizer structures for unidirectional movement are described in UK-PS 2 007 749 and UK-PS 1 517 763. In the structures described in the printed forms, the base element and roof element cannot follow the unevenness and inclination of the free surfaces of the accompanying rock, therefore eccentric loads are created on the structure. Such unwanted loads occur especially in workplaces in wells. they are prevalent here. Such rigid structures have eliminated - or at least largely eliminated - the lateral loading of the hydraulic rams, since the stabilizing structures alone absorb the lateral loads without being subjected to a significant lateral load of 9 ^: 7. However, these stabilizing structures are necessarily robust in design, and robust structures are known to have the disadvantage of being bulky, expensive, and difficult to move and assemble in a mine.

According to the above-mentioned arbitrary grouping, fuses with a lenient stabilizer are described in US-PS 4,020,640 and UK-PS 1,474,558. In these structures, the position of the stabilizer is usually adjusted by hydraulic cylinders. However, these structures do not eliminate the lateral loading of the hydraulic mast. This results in a damaging load on the sailor, which, in an unfavorable case, is destroyed. Increasing the degree of leniency can also lead to loss of fuse unit stability.

The device according to the invention largely eliminates the drawbacks of known structures of the same purpose.

The object of the present invention was to allow a transverse displacement of the base member and the roof member relative to one another, with lateral stabilization of the securing device and with sufficient rigidity.

The device according to the invention ensures that the object is achieved by having a hinge allowing the lateral movement of the roof member and the base member relative to one another, comprising at least two hinges which move about each other, preferably three axes, and providing lateral stability. with a more appropriate arrangement of the supporting hydraulic ram. Advantageous location of the hydraulic rack means that their supporting points are located on the base member and the roof member so as to form a three-pivot frame structure in the forward direction, where one of the members of the frame member is the base member or the roof member. Thereby, the lateral displacement of the roof element and the base element relative to one another and the hydraulic boom leniency! by changing its limit, it can always be kept within the stability limit.

With the application of the invention, as the fuse unit advances, it is achievable that the base member and roof member advance to their new position at the same rate and extent, and the stabilizing mechanism allows the base member and roof member to deviate from parallel position without causing undue stress. All these results can be achieved with the tension force and adjustability of the hydraulic bar, which is otherwise necessarily built-in.

Thus, the structure of the present invention is characterized in that some of its hydraulic rams form a three-pivot frame structure with the base member and / or the roof member and / or a stabilizer structure having a pivot axis that allows the roof member and base member to move relative to each other at least two axes. he has a wrist.

In a preferred embodiment of the structure according to the invention, the stabilizing mechanism for the roof element is shown in Figs

The 205 981 Β has a rear axle joint which is connected to it by means of a hinge joint and to which, directly or indirectly, the base member is connected by means of hinges.

Another preferred embodiment of the device according to the invention is the use of a coupling member inserted between the rod members and the base member, which is pivotable about an axis parallel to its stepping direction.

The invention is exemplified by the drawings. with reference to the exemplary embodiment.

In the drawings it is Figure 1 as an example! shows a side view of the structure, a Figure 2 left - X of Figure 1; Figure 3 rabbit - view of Fig. 2 shows A in detail and in section, a Figure 4 and a section taken along the plane I-I in Figure 3. 20

In the drawings, the structure according to the invention is exemplary! embodiment, which can be used for folding out slits, collapses and meeting points of fronts and their accompanying slits.

The structure (1), as a rule such locking devices, has (3) a base member and (2) a roof member. The spherical nests (9) formed on the roof element (2) and the base element (3) are supported by the respective counterparts of the hydraulic ram (4) and the hydraulic ram (4 '). In particular, Fig. 2 shows that the lower ends of the hydraulic rams 30 (4 ') are joined by the joints (10) to the base member (3), while the joints (10) at their first ends are joined. Accordingly, the hydraulic ram (4 ') and the base member (3) form a three-pivot frame (11). 35

Fig. 2 illustrates the structure (1) with one side - the left side - shown in a stretched state, while the right part shows the structure in an unstretched position.

It is seen that the base element (3) and (2) 40 ^f 'between the roof element (4, 4' outside) hydraulic Tárnok the stabilizing device (5) is incorporated, which in the example In the embodiment, the base member (3) comprises a rod member (14) and a rod member (15) coupled to the base member (3), a back member (16) hingedly connecting the opposite end thereof and a triaxial joint (12). The stabilizing mechanism (5) may be a single rod preferably arranged in an upwardly sloping direction and provided with at least one of its attachment points (12) with a 3-axis hinge, while the other, preferably at the end of its connection to the base member (3) to provide a connection allowing rotation about two axes in a parallel plane. Advancement of the structure (1) is effected by a stepping cylinder (8) connected to the base element (3), either relative to the point fixed in the track or, e.g. .

The operation and / or use of the structure (1) illustrated in the drawings with reference to the function of the stabilizer (5) will now be described.

When using the locking device according to the invention, the front end is generally used at the end of the cut when folding in or out of the cut, or at the intersection of the cut-off and cut. two (1) devices are installed in front of the interlocking device. Installation and construction of the final securing of the cut and the loading and unloading work are carried out under the protection of a pre-hood protruding from the roof element (2) of the structure (1). When moving forward, the hydraulic supports (4 ') of one of the structures (1) must be relieved and the foot (3) must be pulled forward with the stepping roller (8), while the retractable hinges (17) being pushed out of the roof element (2) or pulled back. After the advancement is complete, the hydraulic mast (4 ') must be retracted again. The stabilizing mechanism (5) acts primarily during the advancement with the hydraulic rams (4 ') forming the frame structure (11).

After releasing the hydraulic rack (4 '), the position of the roof member (2) would become unstable if the hydraulic rack (4') of the frame structure (11) did not lock their hinges (10) along the common axis in a most advantageous position. This provides lateral stability of the structure (1). When moving forward, the roof element (2) may encounter obstacles. Such obstacles may be the frictional force between the upper rock surface (7) and the roof element (2) or protruding rock and the like. In this case, the roof element (2) is below the degree of advancement of the base element (3). This retardation is prevented by the stabilizing structure (5) by linking the distance and position of the roof element (2) and the base element (3) to a defined path or surface, from which surface the roof element (2) and the stabilizing device (5) 16) the three-axis joint (12) connecting the rear member cannot be removed.

Due to the direction change of the cuts and the unevenness of the cut surface, the position of the roof element (2) and the base element (3) may be different from the parallel, therefore the vertical axis (19) of the triaxial joint (12) connecting the rear element intended to track changes in the direction of the cut, lowering the roof element (2) when moving the structure (1) and tracking the expansion or decrease of the cross section through the horizontal axis of the triaxial joint (12) and laterally adjusting the roof element (2) 20) provided by a transverse axis (21) perpendicular to the horizontal axis.

The triaxial joint (12) is an example! 3 and 4, respectively.

The triaxial joint (12) is connected to the roof element (2) by means of a tab (23) which is pivotable in a bearing (23) formed on the tab (23). The tab (23) engages the bearing housing (24) of the triaxial joint (12), while the bearing housing (24) comprises a transverse pin (25), one of which is pivotally mounted and the other pin is released. The other pin of the cross-member (25) is exposed at the top of the rear member (26)

GB 205 981 Β is rotatably embedded in the ear (this tab is not included in the drawing).

In the exemplary embodiment, it has been mentioned in connection with Figures 1 and 2 that the stabilizing mechanism (5) can be connected to the base element (3) by means of the connecting element (13). This connecting element (13) can pivot about the axis (22) parallel to the base member (3) and thus allow the lateral movement of the roof member (2) and the base member (3) relative to one another.

It will be apparent from the description of the present invention that the construction allows the lateral displacement of the roof element 2 and the roof member 2 in addition to the positioning or surface quality of either the lower rock surface 6 or the upper rock surface 7 (3) in the contact of the base member without the dangerous use of the hydraulic mast.

An advantage of the device according to the invention is that the protection of the hydraulic ram against lateral forces can be solved by means of the device without significant mass increase.

Generally, a plurality of devices of the invention may be interconnected, and their coordinated operation may be facilitated by guides (18) known per se.

Claims (3)

PATENT CLAIMS A device for providing a mining area, in particular a space at the intersection of a cut and a quarry, comprising a base member, a roof member, hydraulic supports connecting them, and a stabilizing structure, characterized in that some of its hydraulic supports (4, 4 ') the base member (3) and / or the roof member (2) forming a three-pivot frame structure (11) and / or a stabilizing member (5) which allows the roof member (2) and the base member (3) to move relative to each other at least two axes has a joint structure, preferably a three-axis joint (12). Device according to Claim 1, characterized in that the back (16) of the stabilizing device (5) connected to the roof element (2) by means of the triaxial joint (12) and to this and directly or indirectly to the base element (3) via hinges. having rod elements (14, 15). Device according to Claim 1 or 2, characterized in that a connecting element (13) is disposed between the rod elements (14, 15) and the base element (3) and pivotable about an axis (22) parallel to the stepping direction.