SE444837B - DEVICE FOR BLASTING STONE BLOCK, MOUNTAIN, CONCRETE AND SIMILAR - Google Patents

Description

LSI-A ... -__-_ a «'f'" -n1. "/ \ __. . It is preferred here that the blasting means has walls movable in the direction transverse to the geometric longitudinal axis of the hole, which enclose a pressure chamber, and that the device comprises a pressure fluid pump connected by means of a line to the pressure chamber. for supplying pressure fluid to the pressure chamber and for expanding the explosive member by disassembling its movable walls. A particularly advantageous and easy-to-handle device is obtained according to the invention when the movable walls of the explosive member are formed of elastic material and have the shape of a rubber-thick, thick-walled hose.

In the case that the movable walls of the blasting means consist of elastic material, it is suitable that the walls are connected to a device for preventing the walls from expanding uncontrollably in the longitudinal direction of the hole. Such a device may comprise two end pieces, between which the walls are arranged and which are connected to each other by means of a connecting device, which is arranged to prevent movement of the end pieces in the direction of each other.

A difficult problem when the movable walls of the blasting member consist of elastic material is the tendency of the elastic material to creep out into the gap between the end pieces of the blasting member and the surrounding wall of the borehole when the blasting member is pressurized. The invention discloses various features and combinations of features of the explosive means by which this problem is solved. Thus, in accordance with the invention, it is possible to reduce the size of the gap by utilizing a small difference in diameter between the heel and the explosive means. Although this can lead to problems in lowering the blasting member into the borehole, since the borehole is seldom completely straight, these problems can be solved in accordance with the invention by designing the connecting device between the end pieces as a flexible element, eg a wire.

The problem of the tendency of the elastic material to creep out into the gap between the end pieces and the borehole wall is solved in accordance with the invention also in that the end pieces of the blasting member are expandable in the direction of the walls of the borehole.

In this way, it is also possible to solve the problems which arise because the borehole often has a larger diameter at the mouth than further in, and because the borehole is often orange.

The problem with the tendency of the elastic material to creep out into the gap between the end pieces of the blasting member and the surrounding wall of the borehole can in accordance with the invention also be reduced by the connecting device between the end pieces being arranged to expand slightly when the blasting member is pressurized.

In combination with the friction of the elastic material against the wall of the borehole, this feature of the explosive means leads to a marked reduction of the said problem.

In a further embodiment of the device according to the invention, the movable walls of the blasting member consist of reinforced, elastic material, whereby it is possible to obtain a suitable ratio between the expansion of the material in the axial and radial direction, when the blasting member is put under pressure.

Of course, in the device according to the invention it is possible to combine two or more of the specified features of the explosive means in the desired manner.

The invention will be described in more detail below with reference to the accompanying drawings. Fig. 1 shows an embodiment of an explosive device according to the invention, wherein the explosive means of the explosive device are illustrated in axial section, Fig. 2a shows an axial section of a modified embodiment of an explosive member included in the device according to the invention. Fig. Zb illustrates in axial section the coupling of two explosive means of the type shown in Fig. 2a with each other. Fig. 3 shows an axial section through yet another embodiment of an explosive member included in the device according to the invention. Figs. 4a-4h show different embodiments of a detail of an explosive member according to the invention. Fig. 5 shows in axial section a part of an explosive member according to the invention. Figs. 6a and 6b show in axial section an end portion of two different embodiments of an explosive member included in the device according to the invention. Figs. 7a-7c show in axial section, side view and cross section, respectively, an embodiment of an explosive member included in the device according to the invention. Fig. 8 shows a cross section through a modification of the explosive member illustrated in Fig. 7. Fig. 9 shows in axial section a further embodiment of an explosive member included in a device according to the invention. Fig. 10 shows in axial section another embodiment of an explosive member included in a device according to the invention.

Fig. 11 shows in cross section a further embodiment of an explosive member included in a device according to the invention. Fig. 1 illustrates the basic design of a device for blasting a solid material 2, which for example consists of rock. A hole 4 is accommodated in the rock, which has been made in a conventional manner by drilling. An explosive device according to the invention comprises an explosive means 6, a pressure fluid pump 8 and a hose 10 for connecting the pressure fluid pump 8 to the explosive means 6. The bursting of the solid material 2 is to be effected by widening the borehole 4 to such an extent that the hole surrounding the material cracks. The widening of the borehole 4 is effected by means of the blasting member 6 inserted into the borehole 4, which is expandable in the direction transverse to the geometric longitudinal axis of the borehole 4.

The explosive member 6 consists of a wall 12 formed of elastic material, which in the embodiment shown is in the form of a thick-walled rubber hose, an end piece 16 provided with a connecting nipple 14, an end piece 18, a connecting device 20 for connecting the end pieces 16 and 18 to each other and support and sealing means 22 and 24 for connecting the wall 12 to the end piece 16 and the end piece 18, respectively.

In the type of device for blasting solid material shown in Fig. 1, the end pieces 16 and 18 and the rod 20 consist of rigid material, preferably metal. The rod 20 is fixedly connected by threads to the end pieces 16 and 18, and thus the end pieces 16 and 18 are rigidly connected to each other. The support and sealing members 22 and 24 are fixedly connected to the wall 12 and the end pieces 16 and 18, respectively. Thus, the wall 12, although it consists of elastic material, is not expandable in the longitudinal direction of the drill heel 4, because it is clamped between the end pieces 16 and 18.

In the end piece 16 and the adjacent end of the rod 20 a channel 26 is formed, which is connected to the pressure fluid pump 8 via the hose 10.

At its inner end, the channel 26 opens radially into the boundary layer between the outer surface of the rod 20 and the inner surface of the wall 12, between which a pressure chamber 28 can be said to be formed.

When supplying pressure fluid, preferably pressure oil, to the pressure chamber 28 from the pump 8 via the hose 10 and the channel 26, a radially directed expander of the wall 12 is obtained, which is thus pressed against the walls of the hole 4. The pressure in the pressure chamber and thus the pressing pressure of the wall 12 against the walls of the hole 4 is increased until the strength of the material 2 surrounding the hole 4 is overcome and the material cracks. The required pressure can amount to, for example, 1,000 kp / cmz. It is possible without problems according to the principles of the invention to design the blasting device according to the invention to work with as high pressures as about 3,500 kp / cm. A problem with the device shown in Fig. 1 is that the elastic material of the wall 12 when supplying pressure oil to the pressure chamber 28 tends to be forced out through the gaps 29 between the support and sealing means 22 and 24 and the wall of the hole 4. This can lead to a break in the elastic material in the area of the connection between the wall 12 and the support and sealing means 22. and 24, in which case it becomes impossible to achieve the pressure required for the explosion. In accordance with the invention, this problem is solved by designing the blasting member in a certain way. Thus, the problem can be solved by designing the blasting means so that said gaps can be made small, by designing the support and sealing means radially expandable, so that when closing the blasting means they close the said gaps, or by designing the blasting means so that it the wall 12 consisting of elastic material is allowed to expand slightly even in the axial direction when the blasting means is pressurized. The latter, axial expansion can be achieved by the connecting device 20 being designed so that it undergoes a certain limited elongation when the blasting means is pressurized and / or by the support and sealing means allowing the end portions of the wall 12 to move slightly apart during the pressurization.

The design of the blasting member so that the slits 29 can be made small consists in making the blasting member flexible. This makes it possible to lower the blasting member into a drill heel, the diameter of which is only slightly larger than the diameter of the detonator, even if the borehole is not completely straight. The two embodiments shown in Figs. 2 and 3 of blasting members included in the device according to the invention are flexible in order to contribute in the manner described above to the solution of the problem of preventing the elastic material of the wall 12 from being forced out through the gaps 29 between the blasting member end pieces and the hole wall. It can also be mentioned that the flexibility of the blasting means means that the gap 29 becomes uniform around the end pieces, even when the borehole has a curved shape. It will be appreciated that the end pieces will occupy an eccentric position in the borehole if this is not completely straight when using a rigid blasting member, which leads to the gap between the end pieces and the borehole wall becoming non-uniform and thus becoming considerable at one side of the borehole. the explosive device.

The embodiment shown in Fig. 2a of a flexible explosive member included in a device according to the invention comprises a wall 30 consisting of elastic material of the same design as the wall 12 in the embodiment according to Fig. 1. The wall I12 is connected to end pieces 32 and 34 by means of support and sealing means 36 and 38, respectively. The end pieces 32 and 34 are connected to each other by means of a flexible element 40, which in the embodiment shown is constituted by a twisted steel line. The wire rope 40 is connected to the end pieces 32 and 34 by means of coupling elements 42 and 44, respectively, which have clamping portions 46 and 48, respectively, within which they are clamped to the wire rope 40. The wire rope 40 stands through a channel 50 in the coupling element 42 in connection with the end piece 32 nipple 52 and forms between its strands necessary channels for transferring the pressure fluid to a pressure chamber 54 formed between the outer surface of the steel line 40 and the inner surface of the wall 30. ll 15 20 25 ll OOIO IQ O 0 I III II o OOO! IN!!! The embodiment of the blasting member shown in Fig. 2a has in principle the same function as the blasting member according to Fig. 1. Because the element which connects the end pieces to each other is flexible in the embodiment according to Fig. 2, the special advantage is obtained. , that the gap between the end pieces 32 and 34 and the wall of the borehole can be made small, since the explosive means according to Fig. 2 can nevertheless be applied without problems in a borehole which is not completely straight. When using explosive means with a large length, it can also be advantageous to use the embodiment according to Fig. 2a, since an explosive means of this type can be rolled into a space-saving position during transport and storage.

Fig. 2b illustrates how two explosive means of the type shown in Fig. 2a can be connected. It will be appreciated that according to the principle shown it is possible to connect the desired number of blasting means to a unit of the desired length.

Fig. 3 shows in axial section an explosive member which, with the exception of the design of the rod 20a, which connects the end pieces 16 and 18 to each other, is of the same design as the explosive member according to Fig. 1. Due to this, in Fig. 3 the same reference numerals as in Fig. 1 with the exception of the rod 20a.

As can be seen from Fig. 3, the rod 20a has a smaller diameter at its central portion, which facilitates the insertion of the explosive member into a crooked hole. Thus, due to the special design of the rod 20a, the walls 12 can yield in the inward direction, which facilitates insertion.

In a further modification of the blasting member, the rod connecting the end pieces can be formed by a pipe flattened at its central portion by rolling.

Figs. 4a-4h illustrate different embodiments of the support and sealing means, by means of which the elastic wall 12 is connected to the end pieces and to the end portions of the rod or coupling elements on the steel line which constitutes the connecting device between the end pieces.

In the embodiment shown in Fig. 4a, the end piece 16 provided with the nipple 14 is connected to the element 56 and the wall 12 consisting of elastic material is connected to the element 56 and to the end piece 16 by means of support and sealing means, which consists of a support ring 58 and a sealing member 60. The wall 12 consisting of elastic material may but need not necessarily be vulcanized to the sealing member 60. The sealing member 60 seals against the element 56 by means of an O-ring 62. When the blasting member is put under pressure, so that the wall 12 comes into abutment against the wall of the borehole 4, a by means of dashed i1. '“~' i_ -». 7 8405218-2 lines indicated, radial expansion of the sealing member 60, so that the gap between the sealing member 60 and the borehole wall is closed, and the elastic material in the wall 12 is thereby prevented from penetrating into said gap. It can also be seen that the radial expansion of the sealing member 60 allows a limited axial expansion of the wall 12, which helps to prevent the elastic material from penetrating into the gap.

The embodiment shown in Fig. 4b comprises, like the embodiment according to Fig. 4a, an end piece 16 provided with a nipple 14, which is connected to the element 56, a wall 12 consisting of elastic material and a support ring 58 and a sealing member 64. The difference between the embodiments according to Figs. 4a and 4b are in the design of the sealing means 60 and 64, respectively. In the embodiment according to Fig. 4b, the sealing means thus consists of a plate consisting of sheet metal, which is fixedly connected to the support ring 58 and, although not necessary, may be vulcanized at wall l2 elastic material. As indicated by dashed lines, when the blasting member is pressurized, a radial expansion of the sealing member 60 takes place, so that the gap between the sealing member and the wall of the drill heel is closed and the elastic material is thereby prevented from penetrating through the gap.

In the embodiment according to Fig. 4c, the sealing member 66 is formed of a ring of semi-rigid material, for example hardened polyurethane, which upon pressurization of the blasting member expands in the manner indicated by broken lines to close the gap between the sealing member and the borehole wall. The seal between the wall 12 and the element 56 is obtained in that the wall 12 has at its end portion a circumferential sealing lip 68, which is pressed into sealing engagement with the outer surface of the element 56 by the pressure fluid supplied between the wall 12 and the element 56.

In the embodiment according to Fig. 4d, the sealing member 70 consists of two abutments slidably abutting one another at a conical surface and with rings 72 and 74 fixedly connected to each other by the wall 12 and the support ring 58. In this case at least the ring 72 is formed of a semi-rigid, expandable material , such as hard polyurethane. Upon pressurization of the blasting means, the ring 72, as indicated by broken lines, will, while sliding along the conical surface between the rings 72 and 74, expand to a position closing the gap against the borehole wall. Due to the conical abutment surface between the rings 72 and 74, a limited, axial expansion of the elastic material of the wall 12 is also permitted, which contributes to the elastic material being prevented from penetrating into the gap against the wall of the borehole.

As in the embodiment according to Fig. 4c, the seal is provided between the wall 125 and 9% and the element 56 in that the wall lying at its end portion is provided with a sealing lip 68.

In the embodiment according to Fig. 4e, the wall 12 consisting of elastic material is connected to a sealing member 76 consisting of semi-rigid, expandable material, such as hard polyurethane, which slidably abuts a conical surface against a conical surface of the support ring 58. When the explosive member is pressurized, the sealing member 76, as indicated by dashed lines, to expand while sliding along the said conical surfaces to a position closing the gap against the wall of the borehole. Here, too, a limited, axial expansion of the elastic material of the wall 12 is obtained by the radial expansion of the sealing member 76. The seal between the wall 12 and the outer surface of the element 56 is provided by the wall 12 being provided with a as shown in Figs. 4c and 4d. sealing lip 68.

In the embodiment according to Fig. 4f, the sealing member consists of a spring washer 78, which is vulcanized at the end surface of the elastic material of the wall 12. The spring washer 78 is designed in such a way that when the explosive means is pressurized it swings out to the position indicated by dashed lines, where it abuts against the support ring 58. To allow this movement of the spring washer, the spring washer can be shaped on such in that the movement described retains its inner diameter but increases its outer diameter to the position where the gap against the wall of the drill heel is closed. During the described movement of the spring washer, a limited, axial expansion of the elastic material of the wall 12 is also obtained, which helps to eliminate the risk that the elastic material will penetrate into the gap against the wall of the borehole.

Instead of the described, wave-shaped washer, the spring washer can consist of a conical disc spring of the standard type.

It is not necessary to vulcanize the spring washer 78 to the elastic material of the wall, since when the blasting member is pressurized, a strong pressure of the end surface of the wall 12 against the washer is obtained.

The sealing of the wall 12 against the element 56 is also achieved in this embodiment in that the wall 12 is provided with a sealing lip 68.

In the embodiment according to Fig. 49, the sealing member is formed by a coil spring 80, which is recessed in the elastic material of the wall 12 at its outer end edge.

As the detonator is pressurized, the coil spring 80 expands radially to -v _,. and .. _ Fifi -._.._- = .____ É ..._> 10 15 20 25 40 8405218-2 the position indicated by dashed lines, where the gap against the borehole wall is closed. It is most suitable here that the end surface of the wall 12 is not solidified at the support ring 58 but can slide against it during the radial expansion.

In this embodiment, the abutment surface between the wall 12 and the support ring 58 can be conical, so that the radial expansion of the coil spring 80 and the end surface of the wall 12 also entails a certain axial expansion of the end surface of the wall 12. Here, too, the seal between the wall 12 and the element 56 is constituted by a sealing lip 68.

The embodiment of the blasting member according to the invention shown in Fig. 4h has as a sealing member a folded strip 82, which upon pressurization of the blasting member expands radially to a position where the gap against the wall of the borehole is closed. The seal between the wall 12 consisting of elastic material and the element 56 is provided by a sealing lip 68 as in the above-described embodiments of the explosive member.

In most of the above-described embodiments of the support and sealing means, by means of which the elastic wall 12 is connected to the end pieces and to the element 56, the sealing takes place between the wall 12 and the element 56 by means of a sealing lip 68, which is located so that the pressure fluid, usually pressure oil used to expand the blasting means will not affect the connection between the elastic material of the wall 12 and the sealing means 60 or the support ring 58. This is advantageous in view of the fact that the pressure oil has a negative effect on this connection.

In some of the embodiments of the blasting member according to the invention shown in Figs. 4a-4h, a limited axial expansion of the wall 12 consisting of elastic material takes place when the blasting member is put under pressure. This axial expansion helps to prevent the elastic material from penetrating into the gap against the borehole wall in that increased space is formed for receiving the elastic material in the areas inside the gap, whereby also the friction between the elastic material wall 12 and the borehole wall contributes to the elastic material moving only axially in the direction of the gaps to a limited extent.

As mentioned, the axial expansion can be achieved by the design of the support and sealing means at the end portions of the blasting means, but it is also possible to provide for this axial expansion by designing the connecting device 10 between the end pieces somewhat resiliently. Thus, in the embodiment of the blasting member shown in Fig. Za, it is possible to design the steel rope 40 so that it undergoes a limited elongation when the blasting member is pressurized.

This not only achieves the axial expansion of the wall 12 which is advantageous from the point of view of a gap seal, but also a limitation of the stresses on the connecting device between the end pieces. Thus, the axial force on the connecting device is reduced by the friction of the wall 12 against the wall of the borehole.

Fig. 5 shows in axial section a suitable way of forming the wall 12 consisting of elastic material at the explosive member included in the device according to the invention. In the example shown, the wall 12 is formed by an intermediate part 84 and two end parts 86. The intermediate part 84 consists of injection-molded hose, which is cut to a suitable length. The end parts 86 are manufactured, for example, by compression molding and are glued or vulcanized to the intermediate part 84. In accordance with this basic construction, it is possible to produce in a simple manner the wall of the explosive member consisting of elastic material in different sizes.

Alternatively, it is also possible to produce both the middle part and the end parts of a continuous hose piece and to subsequently cut out the sealing lips of the end parts.

In the embodiment according to Fig. 6a, the wall 12 is prestressed by means of a clamping member 88, which is screwed onto a threaded portion of the element 56.

In the embodiment of Fig. 6b, a piston-shaped clamping member 90 is used to provide the bias of the wall 12. The clamping member 90 is arranged in a cylinder 92 and is pressed to provide the bias of the wall 12 in the direction thereof by introducing the pressure fluid used for the expansion of the wall 12 into the cylinder 92.

Figures 7 and 8 show blasting means, by means of which it is possible to achieve a directed blasting action. In the embodiment according to Figs. 7a, 7b and 7c, the explosive means comprises a metal body 94, which is formed with a through-going, elongate opening 96. Central in the opening is arranged a cross-sectional rubber part 98 with an axial hole 100. On either side of the gun part 98, a pair of pistons 102 of, for example, nylon are arranged in the opening 96.

When supplying pressure fluid to the hole 100 in the rubber part 98, the rubber part expands to move the pistons 102 in the direction of each other. In the direction in which the rubber part 98 abuts against the body 94, no expansion is obtained, so that in this embodiment it can thus be said that a directed explosive action is obtained in this embodiment of the blasting means.

According to Fig. 8, the blasting means according to Fig. 7 is modified so that the stem 94a encloses the rubber part 98a on three sides, while a piston 10a 2a is arranged at only one side of the rubber part. It will be appreciated that in the embodiment of Fig. 8 the blasting means will expand in only one direction upon application of pressure fluid to the hole 10a. In an embodiment shown in Fig. 9 an blasting means included in a device according to the invention is a rubber preferably expander part l04 arranged between two end pieces l06 and l08. The end pieces 106 and 108 are connected to each other by means of wires or rods 110, which are distributed in a suitable number around the periphery of the explosive member. The expander part 104 is provided with a central hole 111 for supply of pressure fluid for radial expansion of the expander part 104. The threads or rods 110 are flexible and accompany the expansion of the expander part 104 at the same time as they allow bending of the explosive member when it is inserted into crooked drill heels. The wires or rods can of course also be designed to achieve a limited axial expansion of the blasting member when it is pressurized in order to achieve improved gap density according to the principles stated above.

Fig. 10 shows an explosive member consisting of a body ll2 with a piston ll6 radially displaceable in a recess ll4 therein. The piston 166 has at its inner surface an attached body 118 of elastic material, preferably rubber. The piston 166 is radially displaceable for expansion of the explosive means by supplying pressure fluid between the bottom of the recess 114 and the body 111 attached to the piston 116.

In the embodiment shown in Fig. 11 of the blasting member included in the device according to the invention, the expandable wall 120 consists of relatively rigid material, for example nylon, while the expansion is allowed to take place in that the wall 120 is provided with longitudinal outer and inner grooves 222 and 124, respectively. In this case, the grooves l22 and l24 are suitably filled with rubber. In this embodiment of the invention, it is also conceivable to design the wall 120 of metal, preferably steel.

Several blasting means can be easily connected and connected to the same pressure fluid pump to simultaneously cause blasting by means of several boreholes.

In this case, suitable delay and non-return valves can be connected between the blasting means

Claims (9)

L _ .. ..._ _ -, ... _zz- ~ _ _. To achieve the desired control of the actuation of the blasting means. P A T E N T k R'A v 1. A device for blasting solid material (2), such as boulders, rock, concrete and the like, comprising a blasting member (6) which can be lowered into a hole (4) in the solid material, which has a direction transverse to the geometric longitudinal axis of the hole. movable, elastic material walls (12; 30) and end pieces (16, 18; 32, 34), which walls and end pieces together enclose a pressure chamber (28, 54), and further comprising a pressure fluid pump (8) connected to the pressure chamber ) for supplying pressure fluid to the pressure chamber for expanding the blasting means by disassembling its movable walls, characterized in that the end pieces (16, 18; 32, 34) comprise support and sealing means (22, 24; 36, 38; 58 , 60; 64; 68; 70; 72, 74; 76; 78, 80; 82), which are arranged to expand radially upon pressure fluid supply to the blasting means to close at the ends of the blasting means the gap between the blasting means and the walls of the hole in which the blasting means is lowered. Device according to claim 1, characterized in that the explosive means (6) is flexible. Device according to claim 1 or 2, characterized in that the end pieces (16, 18; 32, 34) are connected to each other by means of a connecting device (20; 40). Device according to claim 3, characterized in that the connecting device consists of a rope (40). Device according to claim 4, characterized in that the line (40) is located in the pressure chamber (54) and is provided with channels for supplying pressure fluid to the chamber. Device according to claim 4 or 5, characterized in that the rope (40) is a twisted steel rope. Device according to one of Claims 3 to 6, characterized in that the connecting device (20; 40) is arranged to allow limited axial expansion of the explosive means and thus of those between the end pieces (16, 18; 32) when the fluid is supplied to the blasting means (6). , 34) arranged walls made of elastic material (l2; 30). 10 '13 8405218-2 Device according to one of the preceding claims, characterized in that the support and sealing means of the end pieces (22, 24; 36, 38; 58, 60; 64; 68; 70; 72, 74; 76; 78; 80; 82) are arranged that in the case of pressure fluid supply to the blasting member (6) something is moved away from each other in the axial direction of the blasting member. Device according to claim 8, characterized in that the support and sealing means (22, 24; 36, 38; 58, 60; 64; 68; 70; 72, 74; 76; 78; 80; 82) comprise elements, arranged that when subjected to axially directed pressure at least at their periphery they expand radially and / or move axially in direction to increase the space for the walls arranged between the end pieces, consisting of elastic material (12; 30).