RU2448253C1 - Improved sliding anchor - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: sliding anchor includes anchor bar and anchor plate. Sliding control element with through channel is located on anchor bar. Sliding control element includes cage for sliding bodies at least with one cavity for receiving sliding body being in contact with side surface of anchor bar. Anchor plate is intended to be superimposed on the area enveloping the well mouth when sliding anchor is introduced to the well. Anchor plate has force transmitting connection with the above cage. Each cavity for receiving the sliding body passes in the above cage tangentially to side surface of anchor bar. Side surface of each cavity projects to free cross section of through channel by the pre-determined value. Each sliding body fills in the cross section of the cavity intended for it.

EFFECT: improving structural conditions for installation of the device that points quickly and reliably at still available sliding stroke.

19 cl, 9 dwg

Description

FIELD OF THE INVENTION

The invention relates to a sliding anchor for insertion into a borehole containing an anchor rod, on which is located a sliding control element with a through channel through which the anchor rod passes, and an anchor plate, which is intended to be applied to the area around the wellhead when the sliding anchor is inserted into well, and the sliding control element contains a clip for the sliding bodies with at least one recess for accommodating the sliding body in contact with the side surface Tew anchor rod.

State of the art

Such a sliding anchor is known from patent document WO 2006/034208 A1.

Sliding anchors belong to the group of so-called rock anchors. Rock anchors are used in mining, in the construction of tunnels and in special engineering construction in order to stabilize the walls of the adit, tunnel or slopes. To do this, from the adit or tunnel into the rock, a borehole is drilled, the length of which is usually from two to twelve meters. Then a rock anchor of the appropriate length is introduced into the well, the end part of which is fixed with a mortar, special adhesive materials made of synthetic resin or by mechanical extension. At the end of the anchor protruding from the well, an anchor plate or plate is usually worn, which, with the help of a nut, is pressed against the wall of the adit or tunnel. At the same time, the loads acting in the area of the adit or tunnel wall can be transferred to deeper layers of the rock. In other words, with the help of such rock anchors, rock layers farther from the wall are used to transfer loads to minimize the risk of collapse of the adit or tunnel.

Conventional rock anchors can transfer maximum loads in accordance with their structural design and are destroyed when this load is exceeded (the so-called breaking load). In order to prevent this complete failure of the installed rock anchor, for example, due to rock movement, the so-called sliding anchors have been developed. These sliding anchors are fed to a certain extent when they exceed a certain load, that is, they can increase their length within certain limits so that reduce the stress acting in the rock to such a level that the anchor is able to transmit it. These sliding anchors have a structurally defined sliding stroke that they can make when exceeding a predetermined load, that is, under the action of an increased load, the total length of the sliding anchor can be extended as much as possible by this sliding stroke. It is advisable, by means of visual inspection of the sliding anchor, to be able to quickly and unambiguously establish whether a particular sliding anchor has moved, that is, whether its sliding course has been partially or fully selected. On the one hand, this information can be used to make conclusions about rock movements and, on the other hand, it allows you to better plan the point in time by which the installed sliding anchor should be replaced or supplemented by other sliding anchors. If the sliding stroke of the sliding anchor is fully selected, then with further rock movements it can completely fail if the breaking load is exceeded.

Disclosure of invention

The objective of the invention is to provide a sliding anchor with the best structural conditions for the installation of the device, which quickly and reliably indicates the available sliding course.

In accordance with the invention, on the basis of the specified known sliding anchor, the task is achieved due to the fact that the anchor plate is in a force transmitting connection with a clip for the sliding bodies. In other words, the anchor plate is interlocked with a clip for the sliding bodies to transmit, in particular, traction and pressure forces, so that when a predetermined load on the sliding anchor is exceeded, the sliding control slides along the anchor rod, while in the known examples when When a predetermined load is exceeded, the slip control remains stationary, and the anchor rod slides along the slip control. In a conventional known sliding anchor, an anchor plate that abuts against the rock wall to be reinforced outside is rigidly connected to the anchor rod. If rock movements cause pressure on the anchor plate to exceed a predetermined load on the sliding anchor, the anchor rod slides out through the sliding control to the outside of the anchor plate to thereby reduce the load in a certain way by this targeted extension of the sliding anchor. However, such an extension of the sliding anchor, that is, the consistent use of the available sliding course depending on the movements of the rock, is not so easy to notice from the outside. Only if, when installing a sliding anchor, with it, for example, a wire is laid with it, it is possible to judge whether rock movements are occurring and what part of the sliding course has already been used.

In contrast, in the sliding anchor according to the invention, the anchor plate is in force-transmitting connection with the clip for the slide bodies, so that when rock moves and the pressure exerted on the anchor plate, the slip control slides along the anchor rod when a predetermined load is exceeded. In contrast, the anchor rod remains stationary, and its free end located in the area of the wellhead during the sliding course slides into the sliding anchor. This provides a simple opportunity to establish whether a particular sliding anchor has already passed the sliding stages and to what extent its sliding course has already been used.

According to an example embodiment of the sliding anchor according to the invention, the holder for the sliding bodies is an integral part of the mounting adapter, which serves to lay the anchor plate on the area surrounding the wellhead. In this exemplary embodiment, the cage for the sliding bodies and, accordingly, the entire sliding control is relatively close to the wellhead or even inside it. Preferably, in this embodiment, the protective tube concentrically surrounding the anchor rod extends from the anchor plate into the borehole in order to protect the anchor rod, in particular from being crushed by shifting rock formations. The protective tube may extend to the end region of the sliding anchor from the well side and may be made of metal, in particular steel, or plastic.

In this case, preferably the anchor rod protrudes from the well through the anchor plate and the mounting adapter. If the length of the anchor rod portion protruding from the well is known, then subsequent changes caused by rock movements can be easily checked based on the shortened portion. To facilitate the determination of these changes, the protruding portion of the anchor rod protruding from the well is preferably provided with one or more markers, by which the remaining sliding course can be visually determined. As an example, the section of the anchor rod protruding from the well can be provided with uniform divisions according to the type of the measuring rod, so that during the rock movements the already used sliding course can be read directly.

In a modified embodiment, the markers are color markers, preferably the region of the anchor rod closest to the anchor plate is marked in green, the region adjacent to it along the axis is marked in yellow, and the region surrounding the free end of the anchor rod is marked in red. When installing the sliding anchor, it is installed so that all three color-marked areas of the anchor rod are visible from the outside. In this case, during operation during rock movements, the green region may first “disappear”, that is, the green region will move inward, then the yellow region and finally the red region. While the green area or part of it is still visible, this indicates that everything is in order. If only the yellow region (or part of it) and the red region protrude from the sliding anchor, this indicates that this sliding anchor requires enhanced observation, since rock movements have occurred in a very obvious way. And finally, if only the red region protrudes from the sliding anchor, this indicates that the position is starting to become critical, and you should think about replacing the sliding anchor soon or installing additional sliding anchors.

In another exemplary embodiment of the sliding anchor according to the invention, the protective tube concentrically surrounding the anchor rod extends from the anchor plate towards the end of the anchor rod from the side of the well (i.e., inside the well), with one end of the protective tube mounted on a clip for sliding bodies and the other end mounted on anchor plate. Thus, here the protective tube serves to transfer forces between the anchor plate and the holder for the sliding bodies. In principle, any type of connection is suitable for attaching the protective tube to the slide for the sliding bodies or to the anchor plate, which ensures the transfer of forces between the parts connected to each other. For example, one end of the protective tube can be welded to a holder for sliding bodies. However, it can be screwed on or glued to the clip for sliding bodies. An exemplary embodiment is also possible in which the protective tube is integral with the clip for the sliding bodies. To mount the protective tube to the anchor plate, a mounting adapter screwed onto the free end of the protective tube can be used. Other types of compounds known to those skilled in the art are also possible.

When a mounting adapter is used to secure the free end of the protective tube to the anchor plate, it preferably comprises a through hole arranged concentrically with the anchor rod through which the anchor rod can pass. In this case, preferably, at the free end of the anchor rod or in its region, a thrust element is fixed, the diameter of which is larger than the diameter of the through channel. At the same time, the slip control cannot slide off the anchor rod. As an example, the thrust element is a nut screwed onto the end portion of the anchor rod or otherwise secured to it. When the thrust element abuts against the sliding control element, a further definite increase in the length of the sliding anchor is not possible. In this case, the sliding anchor can be loaded to the fracture load determined by its structural implementation, and if this load is exceeded, it fails, that is, its anchor rod is destroyed.

In the initial state of the sliding anchor, the thrust element is preferably located in the through hole of the mounting adapter. In a preferred embodiment, the end surface on the outside of the thrust member in the initial position of the sliding anchor is flush with the outer edge of the mounting adapter surrounding the end surface. During rock movements, which lead to a lengthening of the sliding anchor, the thrust element moves inside the sliding anchor, or rather goes into the through hole, which is clearly visible from the outside.

According to a further development of the described embodiment, the anchor rod or its extension protrudes from the mounting adapter, and at this point it is preferably provided with one or more markers that indicate the remaining sliding course. These markers can be made in the same way as was indicated in relation to the first example of execution. Alternatively, in the region of the free end of the anchor rod, an element for determining the sliding course, in particular a tape, wire, thread or the like, can be strengthened. In this case, as the length of the sliding anchor increases due to the sliding of the sliding control element, the sliding stroke detection element is accordingly retracted into the sliding anchor, so that the already used sliding stroke can be easily determined by comparison with the originally protruding length of the sliding stroke detection element.

In the above embodiments, in which a force-transmitting protective tube extends between the anchor plate and the holder for the slide bodies, an additional protective tube can be provided which extends from the slide control element to the end of the anchor rod located on the well side and concentrically surrounds the anchor rod. As in the first mentioned embodiment, this protective tube serves to protect the anchor rod, in particular from being crushed by shifting rock formations, and is preferably made of metal, in particular steel, or plastic.

Further, in sliding anchors of this type, it is desirable that the load at which the sliding anchor is supplied in a certain way can be set as accurately as possible and as little as possible even when the sliding anchor is triggered. This is desirable in order, on the one hand, to provide the opportunity for accurate structural design of the rock anchor and, on the other hand, to obtain its predictable behavior during operation. The so-called threshold force, that is, the force above which the sliding anchor is supplied in a certain way, must also be accurately repeated so that the load on the sliding anchor does not change in an uncontrolled manner during the various time-elongated stages of its extension.

To achieve this, in all of these embodiments, it is preferable that each recess for receiving the slide body therein is located tangentially to the side surface of the anchor rod in the slide for the slide bodies. Further, the lateral surface of each recess extends into the free cross section of the through channel by a predetermined amount and each sliding body fills the cross section of the recess intended for it. The term “tangential to the lateral surface of the anchor rod” in this case does not mean the exact tangential arrangement in the mathematical sense, in which the lateral envelope surface of the recess only tangentially touches the lateral surface of the anchor rod. This refers to the essentially tangential arrangement of the recessed slide bodies relative to the lateral surface of the anchor rod, in which the central longitudinal axis of each recess is inclined to the central longitudinal axis of the through channel, and in the projection in which the central longitudinal axis of the through channel lies and the central longitudinal axis of any depression, these axes can, but need not necessarily, be perpendicular to each other. Accordingly, the central longitudinal axis of the recess for accommodating the sliding body may lie in a plane that intersects the central longitudinal axis of the anchor rod at right angles (in this case, these axes are perpendicular to each other in this projection), but it can also lie in a plane that is inclined to central longitudinal axis of the anchor rod.

This embodiment of the sliding anchor according to the invention has several advantages. Due to the fact that the lateral envelope surface of each recess intended to accommodate the sliding body protrudes by a predetermined amount into the free cross section of the through channel, the clamping force with which the sliding bodies hold the anchor rod can be very precisely set passing through the through channel. In addition, this once established clamping force after the initial feed stroke is again achieved in an accurate and repeatable way, since the sliding body, taking into account normal tolerances, completely fills the cross section of the corresponding recess, so that a predetermined amount by which each sliding body protrudes into the free cross section of the through channel, does not change during operation of the sliding anchor, even after many time-spaced steps of the sliding control slip. And finally, the transfer of forces between the slip control sliding element under certain circumstances and the anchor rod ends favorably, since since the slide bodies fill the cross-section of the recesses, this slip does not cause deformation of the material of the slide bodies and the cage for the slide bodies, but only the deformation of the anchor rod . Naturally, the precondition for this, as in the indicated solutions of the prior art, is that the hardness of the material of the sliding bodies be higher than the hardness of the material of the anchor rod.

Other factors influencing the clamping or threshold force are the shape of the body or the sliding bodies and the clips for the sliding bodies, the number of sliding bodies, the type of their outer surface in contact with the anchor rod, the selection of material pairs between the sliding bodies and the anchor rod and between the sliding bodies and holder for sliding bodies, as well as the type and outer surface of the anchor rod.

In principle, the sliding anchor according to the invention already works in the presence of one recess and a sliding body located therein. However, it is preferable that several recesses are located in the holder for the sliding bodies, in particular, evenly distributed around the circumference of the anchor rod. With the help of several recesses and, accordingly, several sliding bodies, the desired threshold force can be set even more accurately. In addition, in the presence of several depressions and sliding bodies located therein, a higher clamping or threshold force can be easily realized. The uniform distribution of the recesses and the sliding bodies around the circumferential perimeter of the anchor rod more evenly distributes the loads acting on the anchor rod.

Each of several recesses can be located in the holder for the sliding bodies at its own level, that is, in its own plane of the cross section of the holder for the sliding bodies. However, in order to obtain a compact design of the sliding control element, preferably several recesses are located in the same plane of the cross section of the holder for the sliding bodies. The possible number of recesses in one plane of the cross section depends on the size of the recesses and the size of the cage for the sliding bodies. In one embodiment of the sliding anchor according to the invention, three recesses are located in the same plane of the cross section, however, more than three recesses can be provided in a larger sliding anchor with a correspondingly large sliding control. Further, preferably, also in the aspect of obtaining a compact design and uniform load distribution, the location of several recesses in groups in different planes of the cross section of the cage for sliding bodies. This design is preferably selected in the case when the spatial conditions do not allow the location of the desired number of recesses in one plane of the cross section. For example, in another exemplary embodiment of the sliding anchor according to the invention, three recesses are arranged in two different planes of the cross-section of the holder for the sliding bodies. The recesses in different planes of the cross section are preferably offset at an angle relative to each other so that the sliding bodies located in the recesses of the same plane of the cross section are in contact with the side surface of the anchor rod in other areas than the sliding bodies located in another plane or in other planes of the cross section.

In the framework of the present invention, the shape of the sliding bodies used can be selected almost any. For example, the sliding bodies can be conical or can have an outer shape tapering along the cone, for example, in the form of conical rollers. According to a preferred embodiment, the sliding bodies are cylindrical in circular shape, i.e. in the form of rollers. Further, the lateral surface of each sliding body can be barrel-shaped, that is, convex outward, for example, like a wine barrel. Prismatic slip bodies are also possible. It goes without saying that the shape of the recesses should correspond to the slide bodies used, at least so that each slide body fits essentially without gaps in its recess. As a rule, the shape of the recess corresponds to the shape of the used sliding body, that is, the cylindrical sliding body of circular cross section is located in the cylindrical recess of circular cross section, the conical sliding body in the conical recess, etc., however, this correspondence is not required.

In preferred embodiments of the sliding anchor of the invention, a mixing and anchor element is fixed at the end of the anchor rod from the well side. When a two-component adhesive resin is used to secure the anchor in the well, the two components are usually introduced into the well in the form of cartridges of adhesive, in which the two components are placed separately from each other, for example, in two concentric chambers. In this case, when installing the anchor, the mixing and anchor element first destroys the chambers formed, for example, by polymer films, and the simultaneous or subsequent rotation of the anchor rod leads to the mixing of both components, which then quickly harden to form a finished adhesive resin.

In preferred embodiments of the sliding anchor according to the invention, the mounting adapter at its free end is adapted to be connected to the mounting device, which, when the sliding anchor is inserted into the well, rotates the mounting adapter, and with it the clip for sliding bodies, the anchor rod and the mixing and anchor element . In such exemplary embodiments, the mounting of the mounting adapter on the clip for the slide bodies and on the anchor plate must be such that rotational forces can be transmitted.

Brief List of Drawings

Next, with reference to the accompanying drawings, preferred embodiments of the invention will be described in detail. In the drawings:

figure 1 depicts a longitudinal section of a sliding anchor in the first preferred embodiment,

figure 2 depicts in the first exemplary embodiment the clip for the sliding bodies used in the sliding control element of the sliding anchor according to the invention,

figure 3 is a view in section along the line III-III in figure 2,

figure 4 depicts in a second exemplary embodiment the clip for the sliding bodies used in the sliding control element of the sliding anchor of figure 1,

figure 5 is a view in section along the line V-V in figure 4,

6 is a view in section along the line VI-VI in figure 4,

FIG. 7 is a view similar to that of FIG. 5, but with slide bodies inserted into a clip for slide bodies,

Fig. 8 is a view similar to that of Fig. 6, but also with slide bodies inserted in a clip for slide bodies,

Fig.9 depicts a top view of a sliding anchor in a second preferred embodiment.

The implementation of the invention

Figure 1 shows a sliding anchor, indicated generally by 10, which is intended to be inserted into a rock not shown in a rock, for example, to stabilize an adit or tunnel wall. The central element of this sliding anchor 10 is the anchor rod 12, which represents the load bearing structural element of the sliding anchor and whose length determines the length of the sliding anchor 10. In the shown embodiment, the anchor rod 12 is made in the form of a solid steel rod of circular cross section 12 mm in diameter passing through smooth lateral surface, and here the length of the anchor rod is two meters. However, depending on the desired load transfer capacity, the diameter of the anchor rod 12 may be less or more than 12 mm, and its length, depending on the conditions of use, may be less or more than indicated. The lateral surface of the anchor rod 12 may also be not smooth, but, for example, corrugated, grooved, etc. Although anchor rods of circular cross section are preferred, the invention is not limited to this shape and the cross section of the anchor rod may be, for example, square, polygonal, etc.

On the portion of the anchor rod 12, which is intended to be inserted into a rock not shown, a sliding control element 14 is located, the principle design of which is better seen in FIGS. 2 and 3. The sliding control element 14 serves to allow a limited relative displacement between the anchor rod 12 and the slide control element 14 so that the sliding anchor 10 can better withstand rock movements after installation and does not fail prematurely.

Sliding control element 14 comprises a hollow cylindrical sleeve 16 for sliding bodies with a central axial through channel 18 (see FIG. 2), which in the shown example is made with a small step and through which, in the assembled state of the sliding anchor 10, the anchor rod 12 passes.

As can be seen in cross section in figure 3, in the cage 16 for the sliding bodies made three recesses 20, uniformly distributed around the circumference of the casing 16 for the sliding bodies and having the form of cylindrical holes of circular cross section. These grooves 20 are positioned so that their side surfaces slightly extend into the free cross section of the through channel 18. In other words, the size X, which determines the distance between the center point M of the through channel 18 and the central longitudinal axis of each recess 20, is slightly less than the sum of the radius R the through channel 18 and the radius r of the recess 20.

The recesses 20 are located essentially tangentially to the lateral surface of the anchor rod 12, that is, their central longitudinal axes are inclined to the central longitudinal axis of the through channel 18, and in the projection in which lies the central longitudinal axis of the through channel 18 and the central longitudinal axis of the corresponding recess 20, these the axes are perpendicular to each other. Thus, the three recesses 20 are located in the same plane of the cross section of the cage 16 for sliding bodies. In the shown embodiment, the angle M ⁰ is 30 °.

4-6, the cage 16 'for the sliding bodies is shown in the second exemplary embodiment, and its basic construction corresponds to the design of the casing 16 for sliding bodies. However, in contrast to the cage 16 for the sliding bodies, the cage 16 'for the sliding bodies has two planes located one above the other, each with three recesses 20, and the recesses 20 of one plane of the cross section are offset relative to the recesses 20 of the other plane of the cross section so that all six the recesses 20 are evenly distributed around the circumference of the cage 16 'for sliding bodies.

Each recess 20 is designed to accommodate a slide body 22, which here has a cylindrical circular shape, and its outer diameter, taking into account normal tolerances, corresponds to the diameter of the recess 20, that is, the slide body 22 completely occupies the cross section of the recess 20. In FIG. 7 and 8 are views corresponding to FIGS. 5 and 6, in which a slide body 22 described above is located in each recess 20. As is particularly clearly seen in Fig. 7, due to the described arrangement of the recesses 20, each sliding body 22 projects slightly with its lateral surface into the cross section of the through channel 18. At the same time, the anchor rod 12, the outer diameter of which almost corresponds to the diameter of the through channel 18, is held by the clamped bodies 22 slip.

Returning to FIG. 1 for further description of the design of the sliding anchor 10.

To enable the stabilizing effect of the sliding anchor 10 on the walls of the adit or tunnel, a load transfer anchor plate 24 is provided, which is worn on the anchor rod 12 on the side of the wellhead. Anchor plate 24, which is usually made of steel and usually has a square shape, but may have a different shape, is provided in the center with a through hole through which the first protective tube 26 passes. The inner diameter of the protective tube 26 is larger than the outer diameter of the anchor rod 12 so that the protective tube 26 can concentrically surround the anchor rod 12. In the shown exemplary embodiment, the protective tube 26 has essentially the same outer diameter as the sleeve 16 for the sliding bodies, so that a single outer surface is created be that facilitates entry into the well. However, the outer diameter of the protective tube 26 may also be larger or smaller than the outer diameter of the slide ring 16.

At the free end protruding from the anchor plate 24, the protective tube 26 is provided with an external thread onto which a mounting adapter 28 is screwed, securing the protective tube 26 to the anchor plate 24. The mounting adapter 28 is here made in the form of a hexagonal threaded nut, but can also be made to another.

The first protective tube 26, mounted on the anchor plate 24 by means of a mounting adapter 28 made in the form of a hexagonal threaded nut, extends from the anchor plate 24 to the slide ring 16 (or 16 ') to which it is attached by a transmitting force. Such a force transmitting fastening can be carried out, for example, by welding with a cage 16 for sliding bodies. However, with the same success, the inner end of the protective tube 26 can be provided with an internal thread screwed onto the corresponding external thread on the sleeve 16 for the sliding bodies. According to a not shown embodiment, the clip 16 for the sliding bodies and the protective tube 26 can also be made in one piece. Thus, the first protective tube, preferably made of steel or plastic, forms a force-transmitting connection between the sliding body clip 16 (or 16 ') and the anchor plate 24.

A cylindrical thrust element 30 is mounted on the free end of the anchor rod 12 protruding from the anchor plate 24. Its outer diameter is selected so that, on the one hand, it is smaller than the inner diameter of the first protective tube 26, so that the thrust element enters the protective tube 26, and, on the other hand, it is larger than the diameter of the through channel 18 in the ferrule 16 or 16 'for the sliding bodies. In the embodiment shown in FIG. 1, there is an external thread at the free end of the anchor rod 12 onto which the stop member 30 is screwed with its corresponding internal thread. Further, in the illustrated embodiment, the outer end surface 32 of the abutment member 30 is flush with the outer edge surrounding the end surface of the mounting adapter 28 in the installed position of the sliding anchor 10 (i.e., in the initial position of the sliding anchor).

The tip of the sliding anchor 10 forms a mixing and anchor element 36 with several mixing blades 38, mounted on the end of the anchor rod 12 from the side of the well. Firstly, it serves to mix two-component adhesive materials commonly used for fixing rock anchors, which are introduced into the well before the installation of the anchor. For this, the anchor rod 12 is rotated after installation in the well, so that the mixing element 36 is also driven. Secondly, after the adhesive material or mortar has hardened, the mixing and anchor element 36 forms a stop for the adhesive material or mortar and prevents the anchor 10 from leaving the well.

In the illustrated embodiment, a second protective tube 40, which may be made of metal or plastic, extends from the sliding control element 14 to the mixing element 36. This second protective tube 40, on the one hand, separates the above mass from the outer surface of the anchor rod 12 ( mortar, adhesive material) by which the sliding anchor 10 is fixed in a hole not shown. On the other hand, this second protective tube 40 protects the anchor rod 12 from undesirable compression or crushing stresses that may occur, for example, due to displacement of the rock formations and cause local overload of the anchor rod 12. The outer diameter of the second protective tube 40 concentrically surrounding the anchor the rod 12, here is selected smaller than the outer diameter of the first protective tube 26 so that the adhesive material or mortar introduced into the well, which when the anchor 10 is inserted into the well, is partially displaced into the area beyond element 36, could form behind him a substantially hollow cylindrical tube. It is desirable that the end face of the plug facing the element 36 is as large as possible to create a good load bearing stop for the element 36. However, depending on the purpose of the sliding anchor 10, the outer diameter of the second protective tube 40 may be larger than that shown in the drawing.

9, the sliding anchor 10 is shown in a second embodiment, in which the slide control element 14, or rather its clip 16 (or 16 ') for the slide bodies, is directly connected to the mounting adapter 28. In this example, the slide control element 14 It is not located relatively deep in the well into which the sliding anchor 10 is inserted, but is located in the area of the wellhead. Accordingly, the through hole in the anchor plate 24 has a diameter corresponding to the outer diameter of the cage 16 or 16 'for the sliding bodies, taking into account normal tolerances. In this exemplary embodiment, the first protective tube 26 is missing or present in a significantly shortened form. Instead of a short first protective tube 26, the mounting adapter 28 may include a short sleeve for connection with a cage 16 or 16 'for sliding bodies, or may be integral with the cage.

In the second exemplary embodiment, the end portion of the anchor rod 12 protrudes outward from the mounting adapter 28 and is provided with color markers, the function of which is explained below. The first region 42 of the protruding end portion, which is closest to the mounting adapter 28, is colored green here. A second, yellow region 44 is adjacent to it, and the red third region 46 is occupied by the free end. Instead of color markers, other markers may be provided, for example, uniformly spaced divisions by the type of measuring bar or similar markers. Otherwise, the design of the sliding anchor 10 in the second exemplary embodiment basically corresponds to the first example, only there is no stop element 30. However, such a stop element can be mounted on the protruding end of the anchor rod 12.

The function of the sliding anchor 10 is explained below. After the completion of a suitable well, the sliding anchor 10 is inserted into the well and anchored using a mortar or adhesive materials known to those skilled in the art. Alternatively, for anchoring, it is possible and known to use sliding elements, for example expansion sleeves. The sliding anchor 10 shown in the drawings is held in the well by a plug, which is formed by displacing the adhesive or mortar used by the mixing and anchor element 36, i.e., into the area on the side of the wellhead, and after the material has hardened, it prevents the anchor 10 from leaving the well. After installing the anchor plate 24 and securing it using the mounting adapter 28, the sliding anchor can perform its function of load sensing and stabilization.

By means of the sliding bodies 22, a clamping action is exerted on the anchor rod 12 and thereby the so-called threshold force is established, which the sliding anchor 10 can transmit in the axial direction without relative movement between the anchor rod 12 and the sliding control element 14. However, if this threshold force is exceeded, for example, due to the movement or displacement of the rock, which causes an increasing increase in pressure on the anchor plate 24, the slide control element 14 can be moved by sliding along the anchor rod 12 and, thus, by increasing the working length of the sliding anchor 10, the pressure force decreases until it becomes lower than the structurally determined threshold force. Of course, such a displacement can be carried out in separate sections, until the axial force acting on the sliding anchor 10 decreases to a value below the threshold.

In the first embodiment of the sliding anchor 10 shown in FIG. 1, the maximum length over which the sliding anchor 10 can be supplied, called the sliding stroke, is set by the axial distance between the stop member 30 and the cage 16 or 16 'for the sliding bodies. When the sliding anchor of FIG. 1 is supplied at an increased load, the cartridge 16 or 16 'for the sliding bodies slides against the stop member 30. When the cartridge 16 or 16' for the sliding bodies abuts against the stop member 30, a further increase in the length of the sliding anchor 10 is not possible. During the sliding stroke, the stop element 30 moves from its position next to the mounting adapter 28 further into the first protective tube 26, which makes it possible at a glance to determine how far the sliding anchor has gone.

In the second exemplary embodiment of the sliding anchor 10 shown in FIG. 9, the already used sliding course is “read” even easier, since when sliding the anchor 10, the color-marked areas 42, 44 and 46 disappear one after the other in the well and only the protruding from the mounting adapter 28 is visible part of the end section. If, for example, the green region 42 has completely disappeared, it can immediately be seen from the protruding yellow region 44 that an apparently significant movement of the rock has occurred. This applies equally when only the red region 46 remains visible. In this case, this means that the sliding anchor 10 will soon reach the threshold of its sliding ability.

It goes without saying that the first exemplary embodiment of FIG. 1 can be modified so that the end portion 12 of the anchor rod 12 protrudes from the well.

Claims (19)

1. A sliding anchor (10) for entry into a well containing an anchor rod (12), on which is located a sliding control element (14) with a through channel (18) through which the anchor rod (12) passes, and the control element (14) includes a clip (16; 16 ') for the sliding bodies with at least one recess (20) for receiving the sliding body (22) in contact with the side surface of the anchor rod (12), and the anchor plate (24), which is intended to be applied to the area surrounding the wellhead when the sliding anch p (10) is inserted into the well, the anchor plate (24) being in a force-transmitting connection with the specified clip (16; 16 '), characterized in that each recess (20) for receiving the sliding body (22) passes in the specified clip ( 16; 16 ') tangentially to the lateral surface of the anchor rod (12), the lateral surface of each recess (20) projects into the free cross section of the through channel (18) by a predetermined value and each sliding body (22) fills the cross section of the recess intended for it (twenty). 2. Sliding anchor according to claim 1, characterized in that said clip (16; 16 ') is part of the mounting adapter (28) for fixing the anchor plate (24) to the area surrounding the wellhead. 3. Sliding anchor according to claim 1, characterized in that the anchor rod (12) protrudes from the well through the anchor plate (24). 4. A sliding anchor according to claim 3, characterized in that the section of the anchor rod (12) protruding from the well is provided with one or more markers that indicate the remaining sliding course. 5. A sliding anchor according to claim 4, characterized in that the markers are color markers, the region (42) of the anchor rod (12) closest to the anchor plate (24) is marked in green, the region (44) adjacent to it along the axis is marked in yellow color, and the next region (46), covering the free end of the anchor rod, is marked in red. 6. Sliding anchor according to claim 1, characterized in that a protective tube (26) concentrically surrounding the anchor rod (12) is provided, extending from the anchor plate (24) in the direction of the end of the anchor rod (12) from the well side, with one end of the protective the tube (26) is attached to the specified clip (16; 16 '), and the other end is attached to the anchor plate (24). 7. Sliding anchor according to claim 6, characterized in that the protective tube (26) is attached to the anchor plate (24) by means of a mounting adapter (28) that is screwed onto the free end of the protective tube (26). 8. Sliding anchor according to claim 6, characterized in that the mounting adapter (28) has a through hole located concentrically with the anchor rod (12), and a stop element (30) is mounted on the free end of the anchor rod (12) or in its area, diameter which is larger than the diameter of the through channel (18) and which in the initial state of the sliding anchor is in the through hole. 9. A sliding anchor according to claim 8, characterized in that the end surface (32) on the outside of the thrust element (30) in the initial position of the sliding anchor is flush with the outer edge of the mounting adapter (28) surrounding the end surface (32). 10. A sliding anchor according to claim 8, characterized in that the anchor rod (12) or its extension protrudes from the mounting adapter (28) and at this point it is preferably provided with one or more markers that indicate the remaining sliding course. 11. The sliding anchor according to claim 10, characterized in that the markers are color markers, the region (42) of the anchor rod (12) closest to the anchor plate (24) or its extension is marked in green, the region adjacent to it along the axis is marked in yellow color, and the following covering the free end of the anchor rod or its extension is marked in red. 12. A sliding anchor according to claim 6, characterized in that in the region of the free end of the anchor rod (12), an element for determining the sliding course is strengthened, in particular a tape, wire, thread or similar element. 13. A sliding anchor according to any one of claims 2-5 or 7-12, characterized in that at the end of the anchor rod (12) from the side of the well, a mixing and anchor element (36) is fixed, and the mounting adapter (28) at its free end made with the possibility of connection with the mounting device, which, when the sliding anchor is inserted into the well, rotates the mounting adapter (28) together with the specified clip (16; 16 '), the anchor rod (12) and the mixing and anchor element (36). 14. The sliding anchor according to claim 1, characterized in that several hollows (20) are made in said holder (16; 16 '), in particular, evenly distributed around the circumference of the anchor rod (12). 15. Sliding anchor according to 14, characterized in that the recesses (20) are located in the plane of the cross section of the specified clip (16). 16. A sliding anchor according to claim 14, characterized in that the recesses (20) are arranged in groups in different planes of the cross section of said clip (16 '). 17. A sliding anchor according to claim 1, characterized in that each sliding body (22) is conical, in particular in the form of a conical roller. 18. A sliding anchor according to claim 1, characterized in that the lateral surface of each sliding body (22) is convex. 19. A sliding anchor according to claim 1, characterized in that each sliding body (22) is cylindrical, in particular in the form of a roller.

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