Patent Grant
10822949
This application is the national phase entry of International Application No. PCT/CN2019/106101, filed on Sep. 17, 2019, which is based upon and claims priority to Chinese Patent Application No. 201910201871.2, filed on Mar. 18, 2019, the entire contents of which are incorporated herein by reference.
The present invention relates to a hydraulic support auxiliary apparatus, and in particular, to an apparatus for protecting a roof tray when a gob-side entry retaining end support migrates, and belongs to the field of underground support devices.
After a working face is mined, a specific technical means is adopted to recover protective coal pillars left in a conventional mining mode, and a gate road of a previous section is shored again for use by a next section. Such a method of retaining an entry at an original gate road position along an edge of a gob is referred to as gob-side entry retaining. During the gob-side entry retaining, a constructed roadside filling body is directly related to advancement of a coal mining face, and a proper space between the roadside filling body and the coal mining face is generally controlled through a mechanical structure of an overlying roof of the roadside filling body.
However, according to an actual construction situation on site, during advancement of a working face, a hydraulic support that produces a supporting effect needs to advance to further support a roof of a mined part of the working face. However, because a top portion of a roadway is reinforced and shored when the roadway is initially excavated, where a typical shoring mode is shoring with an anchor rob or an anchor cable, such a roadway roof shoring form may expose some anchor robs or rob structures of anchor cables of a tray and the tray. During advancement of a hydraulic support of an end, a top portion of the hydraulic support is extremely likely to mesh with the tray and some anchor rod/anchor cable structures that are exposed. Consequently, the tray and some anchor rod/anchor cable structures that are exposed are damaged, resulting in a shoring failure, further a failure of all anchor rod or anchor cable structures, even large deformation of a roadway roof, and a threat to production safety of the working face.
Previously, a method for preventing an anchor rod or an anchor cable from being damaged by an end support in actual on-site gob-side entry retaining construction of a coal mine is placing a sleeper with a specific size between an end support and a roof, to prevent the end support from damaging a tray and some anchor rod/anchor cable structures that are exposed. However, because compression strength of the sleeper is relatively small, the sleeper cannot function for a long time, and is likely to fail. In addition, because a contact area between the sleeper and the roof is too small, contact bearing between the end support and the roadway roof is unbalanced. Consequently, the roof partially sinks, and a supporting effect of the anchor rod is further damaged.
To overcome various disadvantages existing in the prior art, the present invention provides an apparatus for protecting a roof tray when a gob-side entry retaining end support migrates, where the apparatus can protect a tray and some anchor rod/anchor cable structures that are exposed in a support moving process of a support while balancing stress on a roof in the moving process, and can be automatically reset when the support contracts.
To achieve the foregoing objectives of the present invention, the present invention provides an apparatus for protecting a roof tray when a gob-side entry retaining end support migrates, where the apparatus is mounted at a top end position of a hydraulic support, and includes a movable bearing mechanism, an automatic expansion/contraction connecting groove mechanism, and an active reset mechanism. The movable bearing mechanism includes two parallel equal-length conveying belts and several matched rollers supporting the belts, and the rollers are mounted on and supported by a bearing mechanism. The automatic expansion/contraction connecting groove mechanism is two concave base plates fixed between the two belts, and the two concave base plates are oppositely disposed and spaced by a distance. The active reset mechanism includes two telescopic rods and reset springs sleeved on the telescopic rods, the telescopic rod is connected to an end portion of the reset spring to form a synchronous mechanism, and the two both have one end connected to one side of the concave base plate and the other end fixed at the end position of the hydraulic support through a fixed support.
After the hydraulic support is lifted, a tray and some anchor cables or anchor rods that are exposed are embedded between the two concave base plates of the groove mechanism to form a gap, and an upper portion of the belt is attached to the roof through a movable bearing mechanism. As the hydraulic support advances, the belt drives, under backward friction of the roof and forward friction of the end support, the roller to rotate, and the movable bearing mechanism drives the groove mechanism to move backwards relative to the hydraulic support at the same time, and stretches the reset spring in the active reset mechanism. When the hydraulic support is relieved and contracts, and a top beam is lowered, friction between the movable bearing mechanism and the roof is eliminated, and the reset spring in the active reset mechanism pulls the movable bearing mechanism and the groove mechanism to return under the action of resilience.
Further, the two concave base plates are connected through several telescopic springs, and the telescopic springs are all anchored on the concave base plates on two sides through an anchor member.
Because the anchor rods or the anchor cables designed during early-stage reinforced shoring of the roadway are not all arranged according to a uniform standard, the tray and some anchor rob/anchor cable structures that are exposed are misaligned. The springs between the concave base plates can make the tray and some anchor robs/anchor cables that are exposed and that are misaligned accommodated in a protection scope, and a use scope of a protection mechanism is enlarged. Due to addition of the mechanism, the tray and some anchor rob/anchor cable structures that are exposed and that are misaligned can all be included in the protection scope, thereby providing an elastic telescopic buffer range for functioning of the whole apparatus.
An implementation of an automatic expansion/contraction function is introduced as follows: When positions between the two concave base plates, namely, the tray and some anchor rod (cable) structures that are exposed are misaligned, two sides of the base plate of the groove mechanism capable of expanding/contracting for connection tend to expand under a squeezing force from the tray and some anchor rod (cable) structures that are exposed. In this case, the telescopic spring of the groove mechanism capable of expanding/contracting for connection is stretched by a pulling force, the concave base plate of the groove mechanism capable of expanding/contracting for connection is expanded, and the groove mechanism capable of expanding/contracting for connection expands to release pressure, and a spherical hinge mechanism of the automatic reset mechanism moves outwards to meet an expansion effect of groove mechanism capable of expanding/contracting for connection. When an outer side of the movable bearing mechanism is pressed inwards by the tray and some anchor rod (cable) structures that are exposed, the telescopic spring of the groove mechanism capable of expanding/contracting for connection contracts under pressure, the concave base plate of the groove mechanism capable of expanding/contracting for connection is contracted, and the groove mechanism capable of expanding/contracting for connection contracts to release pressure.
To ensure flexibility during expansion of the springs between the concave base plates, the telescopic rod is connected in a hinged manner to the fixed support through an end hinge ball.
To increase friction between the belt and the roller, one surface of the belt in contact with the roller is provided with meshing teeth, and the roller is a meshing roller matching the meshing teeth on the belt.
The telescopic rod is a damping telescopic rod, and when being reset, the damping telescopic rod may counteract a forward inertia force of the movable bearing mechanism and the groove mechanism and a contraction force of some springs, so that the apparatus can be reset better.
Further, if an expansion amount of the telescopic spring is defined as k, a length of the telescopic spring in an initial state is a, a width of each concave base plate is b, a width of each belt is c, and a total width of the support is L, k+a+2b+2c=L. If a maximum offset between anchor rods or anchor cables of each row is defined as M, M=k.
The present invention enables, by disposing the movable bearing mechanism on the upper end of the hydraulic support, the end support and the roof to actively bear pressure and move relatively in a relative movement process. The groove mechanism that is connected to the middle of a movable bearing structure and that can automatically expand and contract is used for embedding the tray and some anchor rods/anchor cables that are exposed into the structure, so that the tray and some anchor rods/anchor cables that are exposed are effectively protected during an advancement process of the hydraulic support. The springs disposed between the two concave base plates may enable all the anchor rods/anchor cables that are misaligned to be included in a protection scope, and provide elastic telescopic buffering for the whole apparatus. The active reset mechanism may enable the movable bearing mechanism and the groove mechanism to relatively move backwards during an advancement process of the hydraulic support, and in addition, can enable the movable bearing mechanism and the groove mechanism to return to original positions relative to the active reset mechanism under the action of resilience when the top beam is lowered. Advantages of the present invention are that the tray and some anchor rods/anchor cables that are exposed can all be protected in a support moving process of the hydraulic support, and in addition, high compression strength can balance stress on the roof, to prevent a failure of a roadway shoring device in the support moving process of the hydraulic support from resulting in roof separation and a roadway retaining failure.
In the figures: 1. fixed support; 2. reset spring; 3. telescopic rod; 4. belt; 5. roller; 6. anchor member; 7. telescopic spring; 8. concave base plate; 9. end hinge ball; and 10. bearing mechanism.
The following describes the present invention in detail with reference to the accompanying drawings and specific embodiments.
As shown in
After the hydraulic support is lifted, a tray and some anchor cables or anchor rods that are exposed are embedded between the two concave base plates of the groove mechanism to form a gap, and an upper portion of the belt 4 is attached to the roof through a movable bearing mechanism. As the hydraulic support advances, the belt 4 drives, under backward friction of the roof and forward friction of the end support, the roller 5 to rotate, and the movable bearing mechanism drives the groove mechanism to move backwards relative to the hydraulic support at the same time, and stretches the reset spring 2 in the active reset mechanism. When the hydraulic support is relieved and contracts, and a top beam is lowered, friction between the movable bearing mechanism and the roof is eliminated, and the reset spring 2 in the active reset mechanism pulls the movable bearing mechanism and the groove mechanism to return under the action of resilience.
Further, the two concave base plates 8 are connected through several telescopic springs 7, and the telescopic springs 7 are all anchored on the concave base plates 8 on two sides through an anchor member 6.
Because the anchor rods or the anchor cables designed during early-stage reinforced shoring of the roadway are not all arranged according to a uniform standard, the tray and some anchor rob/anchor cable structures that are exposed are misaligned. The springs 7 between the concave base plates 8 can make the tray and some anchor robs/anchor cables that are exposed and that are misaligned accommodated in a protection scope, and a use scope of a protection mechanism is enlarged. Due to addition of the mechanism, the tray and some anchor rob/anchor cable structures that are exposed and that are misaligned can all be included in the protection scope, thereby providing an elastic telescopic buffer range for functioning of the whole apparatus.
To ensure flexibility during expansion of the springs 7 between the concave base plates 8, the telescopic rod 3 is connected in a hinged manner to the fixed support 1 through an end hinge ball 9.
To increase friction between the belt 4 and the roller 5, one surface of the belt 4 in contact with the roller 5 is provided with meshing teeth, and the roller 5 is a meshing roller matching the meshing teeth on the belt 4.
The telescopic rod 3 is a damping telescopic rod, and when being reset, the damping telescopic rod may counteract a forward inertia force of the movable bearing mechanism and the groove mechanism and a contraction force of some springs, so that the apparatus can be reset better.
Further, if an expansion amount of the telescopic spring 7 is defined as k, a length of the telescopic spring 7 in an initial state is a, a width of each concave base plate 8 is b, a width of each belt 4 is c, and a total width of the support is L, k+a+2b+2c=L. If a maximum offset between anchor rods or anchor cables of each row is defined as M, M=k.
A working principle is as follows:
The mechanism is mounted at the end position of the hydraulic support through the fixed support 1. Then, the tray and some anchor rods/anchor cables that are exposed are embedded into the groove mechanism capable of automatically expanding/contracting for connection. A supporting force of the support is transferred to the roof through the movable bearing mechanism, and an end support moves under pressure in a gate road. As the end support advances, the belt 4 of the movable bearing mechanism drives, under backward friction of the roof and forward friction of the end support, the roller 5 to rotate, and the movable bearing mechanism drives the groove mechanism to move backwards relative to the hydraulic support. At the same time, the reset spring 2 and the damping telescopic rod 3 in the automatic reset mechanism are expanded under a pulling force. When the reset spring of the automatic reset mechanism stretches to a maximum extension length of the spring, the end support is relieved, the top beam is lowered, and the reset spring 2 of the automatic reset mechanism contracts and pulls the movable bearing mechanism and the groove mechanism to move forwards. The damping telescopic rod 3 contracts as the reset spring 2 contracts, and counteracts the forward inertia force of the movable bearing mechanism and the groove mechanism capable of expanding/contracting for connection and the contraction force of some reset springs in time. The apparatus is reset.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2019 1 0201871 | Mar 2019 | CN | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/CN2019/106101 | 9/17/2019 | WO | 00 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2020/186710 | 9/24/2020 | WO | A |
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