RU2724644C1 - Method and device to prevent ingress and collapse of rock fragments into blasting well - Google Patents

Abstract

FIELD: mining.SUBSTANCE: device contains a flexible sheet having a pair of spaced apart and extending in longitudinal direction side edges and a pair of end edges located at a distance from each other and extending in the lateral direction. Sheet has curvilinear shape limiting longitudinal passage extending between holes on lengthwise opposite ends, wherein one end of curved sheet is inserted into open end of blasting hole, as a result of which the curved sheet is tightly pressed to the inner surface of the blast hole and forms a barrier preventing falling or collapse of surrounding fragments of the broken rocks into the open end of the blast hole. Present invention also proposes a method of blasting on ledges and an installation device for installation in a well of a device for preventing falling or breaking of fragments of surrounding broken rocks into an explosive well.EFFECT: present invention proposes a device and method for preventing falling or collapse of fragments of surrounding broken rocks into an explosive well.20 cl, 9 dwg

Description

FIELD OF THE INVENTION

The present invention relates to the field of blasting, in particular in the mining industry and in open cast mining.

State of the art

Minerals, such as iron ore and coal, can be extracted using a variety of methods, including open-pit mining methods. Such methods may involve the use of blasting with large quantities of explosives to loosen large quantities of ore for subsequent excavation by excavators, etc. The blasting process leads to the fragmentation of rocks containing ore in fragments of various sizes. It is desirable that the blasting process allows to obtain material with an average debris size as small as possible in order to minimize the need for further fragmentation by crushing, grinding, vibration and other processes.

Blasting over ledges is a process that involves drilling wells in rocks in depth, diameter and distance from each other and filling wells with explosive material to form an elongated charge that destroys rocks in the required manner. Blast holes can have diameters up to 270-311 millimeters or even up to 350 mm or more and depths up to 50 meters and more. These blast holes are filled with a large number of blasting materials, which, at least partially, are explosives with a low detonation velocity based on ammonium nitrate. Explosive material is in contact with the igniter and is coated or "clogged" with material such as aggregate. The fuse is driven electrically or non-electrically to detonate an explosive.

Most of the rocks that are destroyed after blasting are removed from the mining site by excavators for further processing or to remove waste. However, on the ledge of the quarry in the area of deepening of the well after reaching the relative mark (RL), significant amounts of broken rock fragments or “prepared” material may remain. It may be appropriate to use significantly increased well depths to intentionally and substantially increase the depth of the prepared layer. The depth of the prepared layer up to 4 meters or more can increase the efficiency of the crushing process by maximizing the volume of small fragments as a result of subsequent blasting.

These debris or “prepared” material remains in the place where blast holes should be drilled for subsequent blasting. After drilling blast holes, broken rock fragments or prepared material may fall into the holes of the finished blast holes and partially fill or even block the drilled well before laying explosive material. In those places where the first four or more meters in depth of the blast hole can pass through the prepared layer, there is a high risk of material collapse into blast holes. Wet environmental conditions can also contribute to the lubrication of broken rock fragments, the efforts of the collapse of broken rock fragments in blast holes.

Any description of the state of the art throughout the document should in no way be construed as an assumption that any of the documents or other materials mentioned have been published, known or form part of the publicly available information.

Disclosure of invention

According to a first aspect, the present invention provides a device for preventing the fall or collapse of fragments of surrounding broken rock into a blast hole; the device comprises: an elastic-flexible sheet having a pair of lateral edges spaced apart from each other and extending in the longitudinal direction and a pair of end edges spaced apart from each other and extending laterally, the sheet having a curved shape restricting the longitudinal passage between the holes at the opposite ends arranged in the longitudinal direction, one end of the curved sheet being inserted into the open end of the blast hole, and in a curved shape, the side edges of the sheet are free and the sheet tends to take a flat shape, as a result of which the outer surface of the curved sheet is pressed against the inner the surface of the blast hole and forms a barrier that prevents the fall or collapse of the surrounding fragments of broken rocks into the blast hole.

Preferably, the sheet is suitable for applying force to it to give the sheet a cylindrical or conical shape, and after being inserted through the open end of the blast hole, the sheet assumes a substantially cylindrical shape coaxial with the blast hole. Preferably, the sheet is suitable for manual manipulation in order to give it a cylindrical or conical shape.

According to the invention, the sheet is formed of an elastic-flexible material, which has the property to take a substantially flat shape, as a result of which, during use in a blast hole, the sheet is pressed against the inner surface of the blast hole. Advantageously, the elastic properties of the material from which the sheet is formed allows the outer surface of the sheet to be pressed against the inner surface of the blast hole, thereby providing a barrier to prevent the falling or collapse of fragments of the surrounding broken rock into the blast hole.

In embodiments, longitudinally extending lateral edges taper at the ends. When the sheet is folded onto itself, manually or otherwise, and the parallel edges opposite in the transverse direction approach each other, the narrowing of the ends of the side edges contributes to a more uniform cylindrical shape of the sheet.

In embodiments, the width of the sheet between longitudinally extending lateral edges is less than the circumference of the blast hole. Preferably, the sheet is suitable for taking a substantially cylindrical shape in a blast hole, with the side edges spaced apart. Preferably, the sheet is suitable for applying force, for example, by manual manipulation, to give it a cylindrical shape. Alternatively, the sheet may be mechanically manipulated to give it a cylindrical shape. In embodiments, the width of the sheet between longitudinally extending lateral edges is equal to the circumference of the blast hole or greater than the circumference of the blast hole. It should be noted that a width shorter than the circumference of the blast hole is preferable because it allows distortion and unevenness of the blast hole and also requires fewer holes in the sheet for use as grippers, thereby minimizing sheet weakening. However, embodiments of the sheet, in which the sheet width is equal to or greater than the circumference of the blast hole, also satisfy the general objectives of the invention, which are to form a barrier to prevent the fall or collapse of fragments of surrounding broken rocks into the blast hole.

In embodiments, longitudinally extending lateral edges taper at the ends. When the sheet is bent toward itself and the parallel edges opposite in the transverse direction approach each other, the narrowing of the ends of the side edges contributes to a more uniform cylindrical shape of the sheet.

Preferably, the longitudinally extending lateral edges have elongated flanges for abutting against each other when the sheet has a curved shape.

In embodiments, the flexible sheet is a substantially flat sheet of flexible material. The flexible sheet has a normal flat shape and is suitable for rolling to give it a curved shape. In other words, in the initial state, the sheet tends to take a substantially flat shape.

In embodiments, the sheet has at least one hole in the sheet next to each longitudinally extending side edge, suitable as a gripper, with which the user can manually roll the sheet to give it a curved shape. In embodiments, the sheet has at least one hole in the sheet near one of the end edges, suitable as a grip, with which the user can manually insert and remove the sheet relative to the open end of the blast hole.

In embodiments, the sheet has a pair of holes in the sheet that are suitable for insertion into them of an elongated element to create contact with the surface surrounding the blast hole, in order to prevent further insertion of the sheet through the hole in the blast hole. Preferably, next to each longitudinally extending lateral edge is a pair of holes that are aligned with each other along the length of the sheet to insert the longitudinal element perpendicular to the length of the sheet.

In another aspect, the present invention provides a method for preventing the fall or collapse of fragments of surrounding broken rock into a blast hole; the method includes: providing an elastic-flexible sheet having a pair of lateral edges located at a distance from each other and extending in the longitudinal direction and a pair of end edges located at a distance from each other and laterally, forming the sheet to give it a curved shape , limiting the longitudinal passage, continuing between the holes at the opposite ends located in the longitudinal direction, inserting one end of the curved sheet into the open end of the blast hole, and in the curved shape, the side edges of the sheet are free, and the sheet tends to take a flat shape, resulting in an outer surface the curved sheet is pressed against the inner surface of the blast hole and, essentially coaxially with it, forms a barrier that prevents the falling or collapse of the surrounding fragments of broken rocks into the blast hole.

Preferably, the method includes arranging a sheet in a blast hole in a debris layer of prepared broken rocks to form a barrier, protecting the inner surface of a blast hole in a prepared layer from falling and collapsing debris into a blast hole. Preferably, the method may include inserting an elongated member through openings in the sheet, whereby the elongated member contacts the surface surrounding the blast hole to prevent further insertion of the sheet through the open end of the blast hole.

In an embodiment, the method includes: applying force to the flexible sheet to make it conical, tapering axially from a larger diameter hole at one end to a smaller diameter hole at the other end, inserting a smaller diameter end through the open end of the blast hole, and releasing the sheet to give it a substantially cylindrical shape in the blast hole, thereby forming a barrier that prevents the fall or collapse of fragments of surrounding broken rocks into the blast hole.

In an embodiment, the method includes: applying force to the flexible sheet to give it a cylindrical shape and inserting the sheet through the open end of the blast hole and releasing the sheet, as a result of which the sheet is pressed against the inner surface of the blast hole, forming a barrier preventing the falling or collapsing fragments of the surrounding broken mountain rocks into a blast hole.

Preferably, the method includes applying a force to the sheet manually to give it a conical or cylindrical shape. Alternatively, the method may also include mechanically applying force to the sheet to give it a conical or cylindrical shape.

Embodiments of the device and the method are advantageous in that they provide a convenient installation of the barrier in the open end of the blast hole, which prevents the fall or collapse of the fragments of the surrounding broken rocks into the blast hole.

Embodiments of the device and the method are advantageous in that they are able to maintain an open hole for the blast hole in order to conveniently lay conventional explosive materials and other consumables in the blast hole.

In another aspect, the present invention provides a ledge blasting method, comprising: drilling blast holes through a debris layer of prepared broken rocks and below in a stable rock; forming a substantially flat elastic flexible sheet to give it a curved shape restricting the longitudinal passage and openings at the opposite ends located in the longitudinal direction, inserting one end of the curved sheet into the open end of the blast hole, and in which the lateral edges of the sheet are curved, and the elastic sheet has the ability to take a flat shape, as a result of which the outer surface of the curved sheet is pressed against the inner surface of the blast hole in the debris layer of prepared broken rocks and forms a barrier protecting the inner surface of the blast hole in the prepared layer from falling and collapsing debris into the blast hole.

Preferably, the method includes applying force to the flexible sheet to make it conical, tapering axially from a larger diameter hole at one end to a smaller diameter hole at the other end, inserting a smaller diameter end through the open end of the blast hole, and releasing the sheet to give it a substantially cylindrical shape in a blast hole. In another embodiment, the method includes applying force to the flexible sheet to make it cylindrical and inserting the sheet through the open end of the blast hole and releasing the sheet, whereby the sheet is pressed against the inner surface of the blast hole.

Preferably, the method includes applying a force to the sheet manually to give it a conical or cylindrical shape. Alternatively, the method may include applying a mechanical force to the sheet to give it a conical or cylindrical shape.

Preferably, the sheet has a longitudinal size in length that is 1 meter, 1.5 meters, 2 meters, 2.5 meters, 3 meters, 3.5 meters, 4 meters or more or any size between the indicated values, as determined by geological requirements . Preferably, the method includes inserting a curved sheet into the open end of the blast hole, whereby the curved sheet is pressed firmly against the inside of the blast hole to a depth of about 1 meter, about 1.5 meters, about 2 meters, about 2.5 meters, about 3 meters, approximately 3.5 meters, approximately 4 meters or more, or to any depth between the indicated values in the debris layer of prepared broken rocks, as determined by geological requirements.

In another aspect, the present invention provides an installation device for installing in a blast hole a device that prevents falling or collapsing fragments of surrounding broken rocks into a blast hole, the installation device comprising a forming device suitable for forming a flat flexible sheet to give it a curved shape for insertion into the open end of the blast hole, as a result of which the curved sheet is firmly pressed against the inner surface of the blast hole, forming a barrier that prevents the fall or collapse of fragments of surrounding broken rocks into the blast hole.

Preferably, the forming device comprises a shaped pipe suitable for shaping the sheet in a curved shape as the sheet moves through the pipe.

In an embodiment, the profiled pipe has a wide opening in the upper part and side walls tapering to a narrow lower outlet.

Preferably, the installation device contains a stock of a plurality of sheets stacked. The installation device preferably comprises a sheet gripper and a feed mechanism capable of gripping a single sheet from the stack and feeding the sheet through a profiled pipe.

Brief Description of the Drawings

The following is a detailed description of the present invention with reference to preferred embodiments shown in the attached drawings, in which:

FIG. 1 is a perspective view of a device for preventing debris from surrounding broken rocks from falling into a blast hole, the device comprising an elastic-flexible, substantially rectilinear sheet having a pair of opposite, substantially parallel edges;

FIG. 2 is a perspective view of the device of FIG. 1, moreover, a force is applied to the elastic-flexible sheet to give it a conical shape, tapering in the axial direction from the end of the larger diameter to the end of the smaller diameter;

FIG. 3 is a perspective view of the device of FIG. 1, where the end of the smaller diameter is inserted into the open end of the blast hole;

FIG. 4 is a perspective view of the device of FIG. 1, where after inserting the end of a smaller diameter through the open end of the blast hole, the sheet is released so that it takes on a substantially cylindrical shape coaxial with the blast hole, thereby forming a barrier to prevent debris from surrounding broken rocks from falling into the blast hole;

FIG. 4 is a perspective view of the device of FIG. 1, where the opposing substantially parallel edges of the sheet are located close to each other, and an elongated element is inserted into the cylindrical device through horizontally aligned holes in contact with the surface surrounding the blast hole to prevent further insertion of the sheet through the hole of the blast hole;

FIG. 5 is a plan view of the device of FIG. 1, where elongated shelves along opposing parallel edges are located close to each other and are suitable for abutting against each other;

FIG. 6 is a perspective view of a device according to another embodiment of the invention;

FIG. 7 is a top view of an embodiment comprising a device for preventing falling or collapsing debris of surrounding broken rocks into a blast hole, the device being a resiliently flexible, substantially straight sheet having a pair of opposing, substantially parallel edges, the edges tapering one end;

FIG. 8 is a perspective view of the device of FIG. 7, where a force is applied to the sheet to give it a cylindrical shape; and

FIG. 9 - a device for installing a sheet of any of the embodiments of FIG. 1-8 into the blast hole.

The following is a detailed description of the present invention with reference to the embodiments shown in the figures.

The implementation of the invention

In FIG. 1-5, an embodiment of the invention is shown comprising a device 10 which, during use, is suitable for preventing the entry or collapse of debris 40 of surrounding broken rock into a blast hole 30. FIG. 1 shows a frontal section through the open end of a single blast hole 30, although it will be appreciated that a large number of such blast holes may be drilled for blasting. Blast hole 30 can be drilled with a diameter of up to 270-311 millimeters or up to 350 mm or more and a depth of 50 meters or more. After drilling, the blast hole 30 is filled with explosive material suitable for soil conditions, for example, a mixture of ammonium nitrate with liquid fuel (ANFO) or an emulsion or a mixture thereof, after which a detonation ignition is installed.

Most of the rocks that are crushed after blasting are removed from the mining site by excavators for further processing or to remove waste. However, on the ledge of the quarry in the area of deepening of the well after reaching the relative mark (RL), significant amounts of fragments of broken rocks or fragments of “prepared” rocks may remain. It may be appropriate to use significantly increased well depths to intentionally and substantially increase the depth of the prepared layer. The depth of the prepared layer up to 4 meters or more can increase the efficiency of the crushing process by maximizing the volume of small fragments as a result of subsequent blasting. These fragments of prepared rocks remain in the place where blast holes should be drilled for subsequent blasting. As shown in FIG. 1, the blast hole 30 has an open upper end 33, which is surrounded by a layer of prepared rocks, consisting of fragments of 40 broken rocks. The layer of fragments of 40 prepared rocks can have a depth of 4 meters or more. Essentially, up to the first 4 or more meters of the depth of the blast hole 30 below the upper open end 33, a layer of broken rock fragments 40 may be present. A certain number of fragments of 40 broken rock may fall into the blast hole at the open upper end of the blast hole 30 or in its direction.

In FIG. 2 shows an embodiment of the device 10 of the present invention. The device 10 comprises a flexible sheet 20, preferably consisting of an elastic material, such as an elastic flexible polymer material, which can be reinforced with nylon or some other flexible reinforcing material. The material from which the flexible sheet 20 is formed is high density polyethylene (HDPE), which may or may not have antistatic properties. The sheet 20 has a pair of opposing surfaces 18, 19 and is preferably formed in a rectangular shape so that it has a first pair of parallel lateral edges 21, 23 spaced apart and extending in the longitudinal direction and a second pair spaced apart and extending in the lateral direction of the parallel end edges 22, 24. In the embodiment of FIG. 1-5, a first pair of parallel side edges 21, 23 has elongated flanges 25, 27 extending along substantially the entire length of these edges. It will be appreciated that the second pair of parallel and spaced end edges 22, 24 need not necessarily have parallel edges. The sheet 20 has a group of holes 12, 13, 14, 15, which are located in the lateral direction at a distance from each other and are aligned with pairs 12, 14 and 13, 15 in the longitudinal direction. The sheet 20 also has another hole 16 located next to one of the end edges, which serves as a handle.

In FIG. 3 and 4, sheet 20 is shown during use. As shown in FIG. 3, the sheet 20 is suitable for giving it a curved shape from the original flat shape, for example, a cylindrical or conical shape. Sheet 20 may be cylindrical or conical in shape by manually or mechanically bending sheet 20. When sheet 20 is cylindrical or, as shown in FIG. 3, conical in shape, the sheet 20 delimits a longitudinal passage that tapers axially from an end 11 of a larger diameter bounding an opening of a larger diameter to an end 12 of a smaller diameter bounding an opening of a smaller diameter. The end 11 of the larger diameter consists of one end edge 22 of the end edges closest to the hole group 12, 13, 14, 15. The end 12 of the smaller diameter consists of the other end edge 24 of the end edges farthest from the hole group 12, 13 , 14, 15. The smaller diameter end 12 has an outer diameter smaller than the diameter of the open end 33 of the blast hole 30. The smaller diameter 12 end 12, when it is conical, is first inserted into the open end 33 of the blast hole 30.

After inserting the end 12 of the smaller diameter of the sheet 20 into the open end 33 of the blast hole 30, the following is performed. The sheet 20 is released, so that the elastic properties of the material from which the sheet 20 is formed allows the sheet to unfold and, quite possibly, by some manual manipulation, to take a substantially cylindrical shape, essentially coaxial with the blast hole 30. As shown in 4 and 5, one opposing surface 18 of the opposite surfaces of the sheet forms a cylindrical outer and outward facing surface that faces the inwardly substantially cylindrical surface 32 of the blast hole 30.

Despite the fact that the figures show a sheet 20 formed in a conical shape for insertion into a blast hole 30, it should be appreciated that the sheet 20 can be formed in a substantially cylindrical shape defining a longitudinal passage extending between the longitudinal direction of the ends 11, 12. The diameters of the ends 11, 12 can be essentially the same as before inserting one of the ends 11, 12 into the open end 33 of the blast hole 30. When the sheet 20 is released, it can already be cylindrical and coaxial essentially with a cylindrical surface of the blast hole 30. The elastic properties of the material from which the sheet 20 is formed causes the outer surface 18 to be pressed against the inner surface 32 of the blast hole 30.

As shown in FIG. 4, the sheet 20 is located inside the open end 33 of the blast hole 30 and forms a barrier preventing the falling or collapsing debris 40 of the surrounding broken rock into the blast hole 30 or near the open end 33 of the blast hole 30. Since the layer of debris 40 of the prepared rocks may have a depth up to four or more meters, the sheet 20 helps to prevent the collapse of the upper portion of the inner surface 32 of the blast hole 30. The longitudinal size of the sheet 20 between the opposite opposite end ends 22, 24 can be 1 meter, 1.5 meters, 2 meters, 2 , 5 meters, 3 meters, 3.5 meters, 4 meters or more in length or may correspond to any size between the specified values. The length of the sheet 20 is selected based on geological requirements. The sheet 20 located inside the blast hole 30 provides support for the inner surface 32 over a significant portion of the prepared rock debris layer 40. Consequently, the sheet 20 forms a barrier, preventing, for example, in the prepared layer, falling or collapsing debris 40 of the surrounding broken rock into the blast hole 30.

The width of the sheet 20 between a pair of parallel side edges 21, 23 is slightly less than the circumference of the inward substantially cylindrical surface 32 of the blast hole 30. When the sheet 20 assumes a substantially cylindrical shape inside the blast hole 30, the side edges 21, 23 of the sheet are at a distance from each other and do not overlap. In the embodiment of FIG. 1-5, the elongated shelves 25, 27 are located at a small distance from each other and are suitable for abutting against each other and preventing the edges 21, 23 from sliding against each other. The elongated shelves 25, 27 prevent a reduction in the circumference of the sheet 20 in its cylindrical shape inside the blast hole 30 below a predetermined threshold value. In other words, the elongated shelves 25, 27 along the edges of the sheet 20 are suitable for abutting against each other in order to hold the outer cylindrical surface 18 of the sheet 20 near the inwardly substantially cylindrical surface 32 of the blast hole 30 and the fragments 40 of broken rock near the open end 33 blast hole 30 or near this end.

Each of the holes 12, 13, 14, 15 extends through the sheet 20 from the outer surface 18 to the inner surface 19. An elongated rod can be horizontally inserted through a pair of horizontally aligned holes 12, 14 or 13, 15. 50. Each pair of horizontally aligned holes 12, 14, 13, 15 is located in a corresponding position along the length of the sheet 20, so that the user can select the height of the sheet 20 in the blast hole 30. The opposite ends of the rod 50 are in contact with the surface 55 surrounding the open end 33 of the blast well 30. The rod 50 is engaged with a pair of horizontally aligned holes 12, 14 or 13, 15 and in contact with the surrounding surface 55 to prevent the passage of sheet 20 further into the open end 33 of the blast hole 30. As shown in FIG. 4, a small portion of the sheet protrudes from the open end 33 of the blast hole 30. An elongated rod 50 is used to fasten the sheet 20 near the open end 33 of the blast hole 30 or in the direction of this end.

In FIG. 6 shows another embodiment of the device 100, which is similar to the embodiment of FIG. 1-5 and acts in the same way. The elements of the device of FIG. 6, which are similar in design or function or are the same as the elements of the embodiment of FIG. 1-5 are denoted by like reference numerals. The device 100 comprises a flexible sheet 20, preferably consisting of an elastic material, such as an elastic flexible polymer material, which can also be reinforced. The sheet 20 has a pair of opposing surfaces 18, 19 and is preferably formed in a rectangular shape, so that it has a first pair of opposing in the transverse direction, spaced apart from each other and extending in the longitudinal direction of the parallel side edges 21, 23 and a second pair of opposing in the longitudinal the direction located at a distance from each other and extending in the transverse direction of the parallel end edges 22, 24. In contrast to the embodiment in FIG. 1-5, the embodiment of FIG. 6 does not have elongated shelves along the first pair of parallel side edges 21, 23. It should be appreciated that the pairs of edges 21, 23, 22, 24 need not be parallel. The sheet 20 has a group of holes 12, 13, 14, 15, which are located laterally at a distance from each other and aligned with pairs 12, 14 and 13, 15 in the longitudinal direction. The sheet 20 has several holes 16, which serve as handles or grips, allowing the user to manipulate the sheet to give it a conical or cylindrical shape, as shown in FIG. 3, 4 and 5, from a flat shape, as shown in FIG. 6. Holes 16, acting as a handle, allow the user to manipulate the sheet from the inner and outer sides relative to the open end 33 of the blast hole 30.

Despite the fact that in an embodiment of the device 100 in FIG. 6, the width of the sheet 20 between the longitudinally extending lateral edges 21, 23 is less than the circumference of the blast hole 30, it should be noted that in other embodiments, the width may be equal to or greater than the circumference of the blast hole 30.

In FIG. 7 and 8 show another embodiment of the device 200, which is similar to the embodiments of FIG. 1-6 and acts in the same way. The elements of the device of FIG. 7 and 8, which are similar or the same as the elements of the embodiment of FIG. 1-6 are indicated by like reference numerals. The device 200 includes a flexible sheet 20, consisting of an elastic material, such as a reinforced elastic flexible polymer material. The sheet 20 has a pair of opposing surfaces 18, 19 and is preferably formed in a rectangular shape, so that it has a first pair of opposing transversely spaced parallel side edges 21, 23 and a second pair of longitudinally opposed and spaced apart end edges 22, 24 from each other. Unlike the embodiment of FIG. 6 in the embodiment of FIG. 7 and 8, the lateral edges 21, 23 opposite in the transverse direction are tapering at the ends 21a, 23a. Narrowing the ends 21a, 23a of the transversely opposite lateral edges 21, 23 reduces the outwardly extending bell of the corners of the sheet 20 when the sheet 20 is manually or otherwise shaped into a curved shape, for example a cylindrical shape, as shown in FIG. 8. Accordingly, when the sheet 20 is folded toward itself, and the parallel lateral edges 21, 23 opposite in the transverse direction approach each other, the narrowing of the parallel lateral edges 21, 23 opposite in the transverse direction 21a, 23a contributes to a more uniform cylindrical shape of the sheet 20 The distal end of the sheet 20, having tapering ends 21a, 23a, is suitable for initial insertion into the blast hole 30. Minimizing the outwardly directed bell of the corners of the sheet 20 at its distal end, where parallel lateral edges 21, 23 are opposite and opposite in the longitudinal direction, parallel edges 22, 24 facilitate insertion of the sheet 20 into the blast hole 30.

In another aspect, the invention provides a method for preventing the fall or collapse of fragments 40 of surrounding broken rock into a blast hole 30. The method includes the step of bending by applying force manually or otherwise to an elastic-flexible sheet 20, for example sheet 20 in FIG. 2 or FIG. 6 to give it a substantially cylindrical or conical shape that tapers axially from the end of the larger diameter to the end of the smaller diameter, as shown in FIG. 3. The method includes inserting one end of the sheet 20, which may be the end of a smaller diameter, through the open end of the blast hole 30, as shown in FIG. 3. Next, the sheet is released or manipulated to give it a substantially cylindrical shape coaxial with the blast hole 30, as shown in FIG. 4. Thus, the sheet 20 forms a barrier preventing the fall or collapse of fragments of the surrounding broken rock into the blast hole 30 at or near the free end of the blast hole 30.

In another aspect, the invention provides a ledge blasting method. The method includes drilling blast holes through a layer of debris 40 prepared broken rocks and located below the stable rocks. Prepared layer 40 may have a depth of up to 4 meters or more. The method includes forming a substantially flat flexible sheet 20, for example sheet 20 in FIG. 2 or FIG. 6 to give it a curvilinear shape that delimits a longitudinal passage extending between the holes at the opposite ends located in the longitudinal direction. The method also includes inserting one end of the curved sheet 20 into the open end of the blast hole 30, as a result of which the curved sheet 20 is firmly pressed against the inner surface 32 of the blast hole 30 in the debris layer 40 of the prepared broken rock and forms a barrier protecting the inner surface 32 of the blast hole wells 30 in the prepared layer of fragments of 40 broken rocks from their fall and collapse into the blast hole 30.

The methods may include applying force to the flexible sheet 20 to make it conical, tapering axially from a larger diameter hole at one end to a smaller diameter hole at the other end, inserting a smaller diameter end through the open end of the blast hole 30 and releasing the sheet 20 to give it a substantially cylindrical shape inside the blast hole 30. Alternatively, the method may include applying force to the flexible sheet 20 to give it a substantially conical shape and inserting one end through the open end of the blast hole 30 to the desired depth. Thereafter, an elongated rod 50 can be inserted through holes 12, 13, 14, 15 in the sheet 20. The elongated rod 50 is in contact with the surface surrounding the blast hole 30, as shown in FIG. 4, to hold the sheet 20 at the hole in the blast hole.

Preferably, the sheet 20 has a longitudinal size in length that is 1 meter, 1.5 meters, 2 meters, 2.5 meters, 3 meters, 3.5 meters, 4 meters or more, or any size between the indicated values. The length of the sheet 20 is selected based on geological requirements. Preferably, the methods include inserting a curved sheet 20 into the open end of the blast hole, whereby the curved sheet 20 is pressed firmly against the inner surface 32 of the blast hole 30 to a depth of about 1 meter, about 1.5 meters, about 2 meters, about 2, 5 meters, approximately 3 meters, approximately 3.5 meters, approximately 4 meters or more, or to any depth between the indicated values in the debris layer of 40 prepared broken rocks.

The sheet 20 may remain in place inside the blast hole 30 during the next step of laying explosive materials and other consumables into the blast hole 30. In embodiments of the methods, the sheet 20 may remain in cylindrical shape or may be manipulated to make it conical, for example, by bending sheet 20 to conical shape, as shown in FIG. 3, so that the sheet 20 can act as a funnel through which explosive materials and other consumables can be loaded into the blast hole 30.

In embodiments of the methods, the user selects the desired height for the sheet 20, which is located in the blast hole 30, by installing an elongated rod 50 through the desired pair of holes 12, 14, 13, 15. After inserting the sheet 20 into the blast hole 30, the elongated rod 50 rests on the surface 55 surrounding the blast hole 30. The holes 12, 14, 13, 15 are arranged such that after an elongated rod 50 is inserted through them, the elongated rod 50 is offset from the central axis of the longitudinal passage extending through the curved sheet 20 to facilitate insertion into the blast hole 30 fasteners, loading explosive materials, setting the igniter and feeding any other consumables to the blast hole 30. Then, the sheet 20 can be partially removed and it can be shaped like a funnel for laying downhole material in the blast hole 30. The sheet 20 can be removed from the blast hole 30 to flatten it for storage.

In FIG. 9, an installation device 300 is shown for mounting a sheet 20 in a blast hole 30. The device 300 includes a forming device 310 suitable for forming a flat flexible sheet 20 to form a curved shape for insertion into the open end of the blast hole 30, whereby the curved sheet is pressed tightly to the inner surface of the blast hole 30 and forms a barrier that prevents the fall or collapse of the surrounding debris of broken rocks into the blast hole 30.

A plurality of sheets 20 of FIG. 6 in the form of a stack 315. The device 300 includes a gripper 320 sheets and a feeder 325, which serve to grab a single sheet 20 from the stack 315 and feed the sheet 20 into the vertical forming device 330. In the embodiment shown in FIG. 9, the gripper 320 and the feed mechanism 325 comprise a drive belt structure for gripping one of the sheets 20 from the stack 315 each time. However, in another embodiment, any mechanical structure suitable for gripping one sheet 20 of the stack 315 and feed the sheet can be used. 20 into a vertical forming device 330. The forming device 330 is suitable for forming the sheet 20 in order to give it a curvilinear shape restricting the longitudinal passage extending between the holes at the opposite ends located in the longitudinal direction. Forming device 330 comprises a vertically oriented profiled pipe 332 with a wide opening in the upper part 334 and side walls tapering to a narrow lower outlet 336. However, in another embodiment, any mechanical structure suitable for forming the sheet to give it a curved shape restricting a longitudinal passage extending between the holes at the opposite ends located in the longitudinal direction.

The outlet 336 of the forming device 330 is suitable for manually or automatically positioning above the open end of the blast hole 30, or to some extent at the open end of the blast hole. The gripper 320 sheets and the feeder 325 are suitable for moving a single gripped sheet 20 through the pipe 332 and through the release to feed the curved sheet 20 to the open end of the blast hole 30. The forming device is suitable to continue feeding the sheet 20 to the desired depth in the blast hole 30 and frees sheet 20 when it reaches a predetermined depth. Thus, a freed sheet having a substantially cylindrical shape coaxial with the blast hole 30, as shown in FIG. 4, forms a barrier preventing the fall or collapse of the surrounding fragments of broken rocks into the blast hole 30.

The mounting device 300 may be mounted on a vehicle (not shown) or a trailer (not shown) connected to the vehicle, or any other mobile vehicle suitable for maneuvering in a place where there are many pre-drilled blast holes 30. The vehicle or the other mobile means may be a truck, which is manually controlled by the driver, or, in an embodiment, may be configured to operate autonomously or semi-autonomously. The vehicle or other mobile vehicle may comprise a control unit that includes a GPS device for determining location and is suitable for controlling drive means and vehicle controls. The control module is suitable for obtaining or programming the location coordinates of one or more of a plurality of blast holes and autonomously maneuvering the installation device 300 into place near the first of the blast holes.

The control module, located next to the first blast hole 30, can autonomously control the installation device for installing one of the sheets 20 in the blast hole. The control module can provide the location of the release of the installation device 300 above the blast hole, using the coordinates of the blast hole or using an image from a camera mounted on the device 300 or vehicle 350, or a combination thereof. The control module autonomously or semi-autonomously actuate the capture of 320 sheets and the feed mechanism 325 for moving the sheet 20 through the forming device 330 and through the outlet 336 to feed the curved sheet 20 to the open end 20 of the blast hole 30.

The control module can provide autonomous maneuvering of the installation device 300, vehicle, trailer or other mobile means to a place near the next blast hole for subsequent autonomous or semi-autonomous installation of sheet 20. The control module can provide a system for autonomous or semi-autonomous installation of sheets in a large number of explosive wells.

Despite the fact that the invention has been described with reference to specific examples, specialists in this field should take into account that the invention can be implemented in many other forms while maintaining the general principles and essence of the description presented in this document.

Claims (28)

1. A device for preventing the fall or collapse of the debris of the surrounding broken rocks into a blast hole, containing: an elastic flexible sheet having a pair of lateral edges spaced apart from one another and extending in the longitudinal direction and a pair of end edges spaced apart from one another and extending laterally, the sheet having a curved shape limiting a longitudinal passage extending between the openings located at the longitudinal direction of the opposite ends, with one end of the curved sheet intended to be inserted into the open end of the blast hole, while in a curved shape the side edges of the sheet are free and the sheet tends to take a flat shape, as a result of which the outer surface of the curved sheet is pressed against the inner surface of the blast hole and forms a barrier that prevents the fall or collapse of the surrounding debris of broken rock into a blast hole. 2. The device according to claim 1, in which the sheet is suitable for applying force to it in order to give the sheet a cylindrical or conical shape, and after being inserted through the open end of the blast hole, the sheet assumes a substantially cylindrical shape coaxial with the blast hole. 3. The device according to claim 1 or 2, in which the width of the sheet between the longitudinally extending lateral edges is less than the circumference of the blast hole, equal to the circumference of the blast hole or greater than the circumference of the blast hole. 4. The device according to any one of paragraphs. 1-3, in which the longitudinal edges extending in the longitudinal direction taper at the ends, which contributes to a more uniform cylindrical shape of the sheet. 5. The device according to any one of paragraphs. 1-4, in which the sheet in normal condition is a flat sheet of flexible material. 6. The device according to any one of paragraphs. 1-5, in which the sheet has holes that are suitable for insertion into them of an elongated element to create contact with the surface surrounding the blast hole, in order to prevent further insertion of the sheet through the hole in the blast hole. 7. The device according to any one of paragraphs. 1-6, in which the sheet has at least one hole in the sheet next to each longitudinally extending lateral edge, suitable as a gripper, with which the user manually rolls the sheet to give it a curved shape. 8. The device according to any one of paragraphs. 1-7, in which the sheet has at least one hole in the sheet near one of the end edges, suitable as a grip, with which the user manually inserts and removes the sheet relative to the open end of the blast hole. 9. A method for preventing the fall of fragments of surrounding rocks into a blast hole, including: providing an elastic flexible sheet having a pair of lateral edges spaced apart from each other and extending in the longitudinal direction and a pair of end edges spaced apart from each other and extending in the lateral direction, forming the sheet to give it a curvilinear shape, restricting the longitudinal passage between holes at longitudinally opposite ends inserting one end of the curved sheet into the open end of the blast hole, and in a curved shape, the lateral edges of the sheet are free and the sheet tends to take a flat shape, as a result of which the outer surface of the curved sheet is pressed against the inner surface of the blast hole and forms a barrier substantially coaxially with it, preventing the fall or collapse of the surrounding debris of broken rock into a blast hole. 10. The method according to p. 9, including: applying force to the flexible sheet to give it a cylindrical shape, inserting one end through the open end of the blast hole and releasing the sheet to give it a substantially cylindrical shape, coaxial with the blast hole, to form a barrier to prevent debris from surrounding broken rocks from falling into the open end of the blast hole. 11. The method of claim 9 or 10, comprising inserting an elongated member through openings in the sheet, whereby the elongated member contacts the surface surrounding the blast hole to prevent further insertion of the sheet through the open end of the blast hole. 12. The method of blasting on ledges, including: drilling of blast holes through a layer of fragments of prepared broken rocks and below in a stable rock, applying force to a substantially flat, elastic flexible sheet to give it a curved shape restricting the longitudinal passage between the holes at the opposite ends located in the longitudinal direction; inserting one end of the curved sheet into the open end of the blast hole, and in a curved shape, the side edges of the sheet are free and the elastic sheet tends to take a flat shape, as a result of which the outer surface of the curved sheet is pressed against the inner surface of the blast hole in the debris layer of prepared broken rocks and forms a barrier that protects the inner surface of the blast hole in the prepared layer from falling and collapsing debris into the blast hole. 13. The method according to p. 12, including applying the force to the flexible sheet manually to give it a conical or cylindrical shape, inserting the sheet through the open end of the blast hole and releasing the sheet to give it a substantially cylindrical shape in the blast hole. 14. The method according to p. 12 or 13, in which the sheet has a longitudinal size in length, which is 1 meter, 1.5 meters, 2 meters, 2.5 meters or any size in length between the specified values. 15. The method according to any one of paragraphs. 12-14, in which the curved sheet is inserted into the open end of the blast hole, whereby the curved sheet is firmly pressed against the inner surface of the blast hole to a depth of approximately 1 meter, approximately 1.5 meters, approximately 2 meters, approximately 2.5 meters or any depth between the indicated values in the debris layer of prepared broken rocks. 16. An installation device for installing in a blast hole a device that prevents the falling or collapsing of debris from surrounding broken rocks into a blast hole, the installation device comprising a forming device suitable for forming a flat flexible sheet to give it a curved shape for insertion into the open end of the blast well, as a result of which the curved sheet is pressed tightly against the inner surface of the blast hole, forming a barrier that prevents the fall or collapse of fragments of surrounding broken rocks into the blast hole. 17. The device according to p. 16, in which the forming device contains a profiled pipe, suitable for giving the sheet a curved shape when the sheet moves through the pipe. 18. The device according to p. 17, in which the profiled pipe has a wide hole in the upper part and side walls, tapering to a narrow lower outlet. 19. The device according to any one of paragraphs. 16-18, in which the installation device contains a stock of many sheets stacked in a stack. 20. The device according to p. 19, containing the capture of sheets and a feed mechanism, configured to grab a separate sheet from the stack and feed the sheet through a profiled pipe.

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