RU2656629C1 - Method of composite hardening tamping installation in the groove cavity in the form of a blast-hole or a well during drilling and blasting works and a thrust means for its implementation (variants) - Google Patents

Abstract

FIELD: drilling of soil or rocks; explosion works.

SUBSTANCE: invention relates to drilling and blasting operations. Method of the composite hardening tamping 28 installing in the groove 1 cavity 2 in the form of a blast-hole or a well during drilling and blasting operations is as follows. Composite hardening tamping 28 is placed in contact with the surface of the thrust means fixed along the tamping 28 longitudinal axis. Thereafter, exerting the external axial dynamic action on the tamping 28 from the groove 1 mouth 17 side, with the possibility of the composition structure changing, in particular mixing its components or structural compaction. By this enabling the composition hardening in the zone of the tamping 28 technologically regulated arrangement in the groove 1 cavity 2. As the thrust means fixed along the groove 1 axis with surface in contact with the said tamping 28 a technological structure is used, which is structurally performed with the possibility of its placement in the groove 1 cavity 2 at a distance set from the groove 1 mouth 17. For this, a stop-measuring element, means 19, rigidly connected to the technological structure is used, with its positioning means in the groove 1 cavity 2 relative to the mouth 17 of the later and subsequent fixation of this thrust means relative to the fixed basic structure, for example, the rock surface section 21 adjacent to the groove 1 mouth 17 in place of the thrust means specified installation in the groove 1 cavity 2. Provided are design options of the thrust means implementation.

EFFECT: invention allows to provide a fixation ensuring complete exclusion of interaction with the explosive substance.

11 cl, 7 dwg

Description

The invention relates to the field of predominantly blasting operations in strong rocks and can be used in various fields of the national economy using blasting operations at mining and non-metallic objects. Including, it can be used: when felling buildings, structures, crushing of foundations and sintered ore; blasting in underground and exploration workings; blasting during tunneling and the construction of subway tunnel lines, etc.

The main condition for drilling and blasting is to ensure safety for the surrounding production personnel.

These conditions are governed by federal regulations and rules in the field of industrial safety during blasting.

One of the conditions for ensuring safety in the implementation of the technology of loading (filling) workings in the form of holes or wells is the need to observe precautions that exclude the dynamic effect on the charge of explosives and charge initiating means located in the production cavity of the production (i.e., a hole or a well )

As a rule, an unauthorized dynamic effect on the subversive charge of an explosive and a means of initiating a charge can occur during installation and fixation of a clog (especially a spacer-wedge type - i.e., spacer shutter) in a hole (especially a hole), since fixation requires an axial dynamic effect on the corresponding stemming structure in the direction of the charge and means of its initiation (detonator). As a result, an unauthorized and uncontrolled dynamic impact can occur on the explosive charge and, accordingly, on the charge initiation means, which is unacceptable from the point of view of ensuring the safety of drilling and blasting operations. In addition, when plastic explosives are used as a subversive charge as a result of exposure to a dynamic shock load, a part of the explosive is squeezed out into the through technological cavities of mechanical jamming and through them into the area of the production mouth (hole or well), which is also unacceptable from the point of view safety of drilling and blasting operations. In addition, it reduces the efficiency (efficiency) of the explosion energy and, accordingly, reduces the performance of the corresponding technological process.

In accordance with the foregoing, the mechanical and technological means (used when installing, for example, composite hardening stemming) in the process of charging the production (hole or well) must be guaranteed to ensure the exclusion of dynamic effects on the subversive charge or detonator with conductors of the initiating impulse from the side of the stemming during fixation in the functional cavity of the output (hole or well). For this purpose, special constructions of mechanical-technological means for installing the aforementioned blockages should be used, which ensure their fixation in the functional-technological cavity of the working without direct contact of the clog with a subversive charge and associated explosive means (detonators).

In the process of installing and fixing the faces, certain technological methods for fixing them in a technologically defined spatial position are also used.

The prior art method of installing in the cavity of the hole in the form of a hole or a well a composite hardening stemming during blasting operations, according to which the said stemming is placed in contact with at least one surface of the resistant means fixed along the longitudinal axis of the working, and then on stemming is carried out by an external axial dynamic action from the side of the working mouth with the possibility of changing the structure of the composition, thereby ensuring its solidification in the zones e technologically regulated location of the aforementioned stemming in the mine.

The persistent tool is also known from the prior art for installing a composite hardening stemming device in the form of a hole or well in drilling and blasting operations, which is structurally designed with at least one end surface that is functionally a means of contact with the said blocking device,

The disadvantages of the data of technical solutions known from the prior art are that the above technical solutions use the end face of the explosive charge as a stop means to limit the movement of the composite hardening clog in the hole, which is unacceptable from the point of view of safety rules for the production of drilling and blasting works (see D.F. Zayatdinov, A.S. Pozolotin, P.V. Grechishkin, M.V. Lysenko, S.V. Abramenko. Anchor test results, us tuned onto ampoules of AMK DK with different nature of loads / http://geomar.ru/review/136-rezultaty-ispytaniy-ankerov.html / dated March 31, 2017)

The basis of the claimed invention was the task of creating such a method of installing in the cavity of the hole in the form of a hole or a well a composite hardening stemming during drilling and blasting operations, as well as a persistent tool for implementing the patented method, by which the dynamic effect of an explosive charge on the explosive would be excluded (and, accordingly, the dynamic effect on the detonator with the conductors of the initiating pulse) during installation and fixation in the working (technologically regulated distance from its mouth) of said composite hardening stemming.

The technical result is the provision of fixation of the composite hardening stemming in its working (i.e., fixed in the functional cavity of the mine) position at a technologically specified distance from the mouth of the mine, ensuring the complete exclusion of its dynamic contact with explosive of a subversive charge.

The technical result set according to the method of implementation of the claimed technical solution (see paragraphs 1-5 of the claims) is achieved by the fact that in the method of installing in the cavity of the hole in the form of a borehole or well a composite hardening stemming during drilling and blasting operations, according to which the said stemming is placed in contact with at least one surface fixed along the longitudinal axis of the working of the resistant means, then an external axial dynamic the impact from the mouth of the mine with the possibility of changing the structure of the composition, thereby ensuring its solidification in the area of technologically regulated location of said jamming in the mine, according to the invention, as mentioned above fixed means along the axis of the mining, with the surface in contact with the said jamming, use the technological structure , which is structurally performed with the possibility of its placement in the working out at the technologically specified from the mouth heel region, for which use is rigidly associated with said structure-trip-dimensional element with means for its positioning in the formulation relative to the mouth of the latter and subsequent fixation of the abutment means relative to the stationary base structure in its place, i.e. persistent means, regulated installation.

As a composite hardening stemming, it is permissible to use:

a polymer or mineral composite stemming with a two-chamber ampoule, wherein the mentioned external axial action from the side of the working mouth is carried out by means of a dynamic impact directed along the longitudinal axis of the working, whereby the ampoule shell is destroyed and, therefore, the ampoules hardened in the chambers are mixed after mixing the components and filling the working cavity with this composite mixture in the ampoule location zone before hardening, -mentioned mixture;

- pre-soaked mineral composite stemming with a single-chamber ampoule, wherein the mentioned external axial action from the side of the working mouth is carried out by means of a dynamic impact directed along the longitudinal axis of the working, whereby the ampoule shell is destroyed and, as a result, the working cavity is filled with the mineral composite mixture in the ampoule location zone before hardening said mixture;

- a pre-soaked mineral sand-cement mixture, wherein said external axial action from the side of the working mouth is carried out by means of a dynamic impact directed along the longitudinal axis of the working, whereby the structure of the said mixture is compacted until the working cavity is completely filled with this mixture in the technologically specified zone before solidification mixtures;

- a pre-soaked mineral sand-clay mixture, wherein the mentioned external axial action from the side of the working mouth is carried out by means of a thermodynamic shock directed along the longitudinal axis of the working, whereby the structure of the said mixture is compacted until the working cavity is completely filled with this mixture in the technologically defined zone before hardening of the mixture.

The technical result set by the first embodiment of the refractory means (see paragraphs 6-7 of the claims) for the implementation of the above method is achieved by the fact that the refractory means for installing in the form of a hole or borehole a composite hardening compaction during drilling and blasting, which is structurally made with at least one end surface, which is functionally a means of contact with the said clogging, according to the invention is made in the form of a disk with technical logical recesses which are operably means for placing conductors initiating pulse detonator which, i.e. technological recesses, spatially arranged with the possibility of withdrawing the free ends of the above-mentioned conductors beyond the stemming in the direction of the mouth of the mine; wherein said disk is equipped with a lock-measuring element rigidly connected to it, which is made in the form of a bar with a technologically predetermined length; moreover, this bar is equipped with a L-shaped protrusion at its end, extending beyond the mouth of the mine, which together with the said bar is functionally an element of fixing the disk in the cavity of the mine at a technologically predetermined distance relative to the mouth of the mine through the basic structure, which is mainly used as a function , a section of the surface of the rock adjacent to the mouth of the mine, while the L-shaped protrusion is equipped with a persistent surface to ensure contact with the said section rock surface.

It is advisable that the L-shaped protrusion would be mounted on the said bar with the possibility of its movement relative to the latter along the metric-scale locking and measuring means made on the bar.

The technical result set by means of the second embodiment of the refractory means (see paragraphs 8-11 of the claims) for the implementation of the patented method is achieved by the fact that the refractory means for installing in the form of a hole or borehole a composite hardening compaction during drilling and blasting, which is structurally made with at least one end surface, which is functionally a means of contact with the aforementioned stemming, according to the invention it is formed in the form of a mechanical eskoy tamping configured as a wedge type expansible shutter, constructively comprising: an outer sleeve with sliding structures and arranged in its cavity the element with an outer wedge surface which interacts with it facing the inner surfaces of the sliding sleeve structures; moreover, technological channels are functionally formed in the said spacer shutter elements, which are functionally means for placing the conductors of the initiating pulse of the detonator, which (i.e. technological channels) are spatially arranged with the possibility of outputting the free ends of the said conductors beyond the sleeve towards the mouth of the output; and the sleeve is made with the end surface facing the working mouth, which is functionally a thrust surface to provide an external dynamic impact on this thrust surface along the axis of the sleeve during the preliminary wedging of its sliding structures while ensuring the movement of this sleeve relative to the element with at least one wedge surface; wherein the element with a wedge surface is equipped with a structural and technological locking and measuring means, which is mechanically connected in the axial direction with this element; in addition, the said locking-measuring means is equipped with structural and technological reference elements and is functionally a means of determining the position of the regulated installation of the expansion bolt relative to the mouth of the output and, accordingly, a means of coupling the element with the wedge surface with a fixed base structure for fixing the said element with the wedge surface in predetermined position at the place of the regulated installation of the expansion valve in the process of said wedging Sliding sleeve structures, and as the surface contacting the tamping used, at least one end surface of the outer sleeve facing towards the mouth generation element or with at least one wedge surface.

The locking means can be made in the form of a flexible structure, for example, in the form of a cord or tape, with reference elements in the form of a metric scale, the free end of which is functionally a communication element with the fixed base structure, for example, the operator’s hand holding the free end of the flexible structure.

The stop-measuring means can also be made in the form of a strap with a technologically specified length, which is functionally a structural structure of an element with at least one wedge surface; moreover, this strap has a L-shaped protrusion at its end, extending beyond the sleeve, which is functionally a reference element of communication with a fixed base structure, for which, for example, a section of the rock surface adjacent to the mouth of the mine is functionally used, while the L-shaped the protrusion is equipped with a persistent surface to ensure contact with said portion of the rock surface.

It is advisable that the L-shaped protrusion be mounted on the bar of the stop-measuring means with the possibility of its movement relative to the latter along the metric scale made on the bar of the stop-measuring means.

The analysis of the prior art by the applicant, including a search by patent and scientific and technical sources of information and identification of sources containing information about analogues of the claimed technical solutions, allowed to establish that no analogues were found that are characterized by signs and relationships between them, identical or equivalent to all essential features of the claimed technical solutions, and the prototypes selected from the identified analogues (as the closest analogues in terms of the totality of features) made it possible to identify the totality of tween (in relation to the technical result perceived by the applicant) distinctive features in the claimed objects of the invention set forth in the formula.

Therefore, the claimed technical solutions meet the condition of patentability "novelty" under the current law.

In order to verify the conformity of the claimed technical solutions to the patentability requirements “inventive step”, the applicant conducted an additional search of similar solutions known from the prior art in order to identify features matching the distinctive features of the claimed technical solutions, the results of which show that the claimed technical solutions do not follow ( for a specialist) explicitly from the prior art, since from the prior art (as determined by the applicant) no influence was detected transformations provided for by the essential features of the claimed technical solutions to achieve the technical result perceived by the applicant.

In particular, the claimed technical solutions do not provide for the following transformations of known prototype objects:

- addition of a well-known object by any well-known sign, attached to it according to known rules, to achieve a technical result, in respect of which the influence of such additions is established;

- replacement of any sign of a known object with another well-known sign to achieve a technical result, in respect of which the influence of such a replacement is established;

- the exclusion of any sign of a known object with the simultaneous exclusion due to the presence of this sign of the function and the achievement of the usual result for this exclusion;

- an increase in the number of similar features in a known object to enhance the technical result due to the presence of just such signs in the object;

- the implementation of a known object or part of it from a known material to achieve a technical result due to the known properties of the material;

- the creation of an object that includes known features, the choice of which and the relationship between them are based on known rules and achieved, while the technical result is due only to the known properties of the features of this object and the relationships between them.

Therefore, the claimed technical solutions meet the requirements of the patentability criterion of "inventive step" under applicable law.

The claimed technical solutions are illustrated by graphic materials.

FIG. 1 is one of the possible structural schemes of the stop means in the form of an expansion bolt (which can be used for industrial implementation of the technology for charging the mine according to the patented method) according to one of the possible structural options for its implementation (paragraphs 8-11 of the claims).

FIG. 2 is a view A of FIG. one.

FIG. 3 is a flow chart of the implementation of charging a mine with the construction of a composite hardening stemming structure installed in its functional cavity using a stop means in the form of an expansion bolt according to FIG. 1 and FIG. 2.

FIG. 4 - another of the possible structural schemes of the stop means in the form of an expansion bolt (which can be used for industrial implementation of the technology for charging the workings according to the patented method) according to the second constructive variant of its implementation (not reflected in the claims).

FIG. 5 is a view B of FIG. four.

FIG. 6 is another possible structural diagram of a persistent tool in the form of a disk (which can be used for industrial implementation of the technology of charging the output according to the patented method) according to paragraphs. 6-7 claims.

FIG. 7 is a view B of FIG. 6.

In the graphic materials, the structures and elements of the corresponding design options for the resistant means for implementing the patented method and other structures installed in the functional cavity of the technological development (hole or well) are indicated by the following positions:

1 - development (technological for the installation of a subversive charge and related technological means);

2 - cavity (functional technological development 1);

3 - detonator (subversive charge 5 explosives);

4 - conductors (initiating pulse of the detonator 3);

5 - charge (explosive explosive);

6 - shutter (expansion wedge type);

7 - sleeve (outer expansion bolt 6 of Fig. 1 and Fig. 2);

8 and 9 - structure (constructive sliding sleeve 7);

10 - element (with at least one wedge surface 11 and 12, interacting with structures 8 and 9 of the sleeve 7);

11 and 12 - surface (wedge element 10);

13 and 14 - surface (internal sliding structures 8 and 9, respectively, of the sleeve 7);

15 and 16 - channels (technological for placement of conductors 4 of the initiating pulse);

17 - the mouth (technological development - hole or well);

18 - rod-hole;

19 - means (stop-dimensional structural and technological);

20 - protrusion (L-shaped locking locking means

19);

21 - plot (surface of the rock adjacent to the mouth 17 of the development 1);

22 - surface (persistent L-shaped protrusion 20);

23 and 24 - elements (mutually movable structural expansion bolt 6 in Fig. 4 and Fig. 5);

25 and 26 - surface (wedge elements 23 and 24, respectively);

27 - latch (installation elements 23 and 24);

28 - stemming (composite hardening in the form of an ampoule with a destructible shell according to claims 2 to 3 of the claims);

29 - disk (with technological recesses 30 for placement of conductors 4 of the initiating pulse);

30 - recesses (technological);

31 - surface (resistant means in contact with the stem 28).

The installation method in the cavity 2 of the development 1 in the form of a hole or a well of a composite hardening stemming 28 during blasting operations (see claims 1-5 of the claims) is as follows.

According to the patented method, the aforementioned jamming device 28 is placed in contact with at least one surface fixed along the longitudinal axis of the working of the resistant means. After that, an external axial dynamic impact from the side of the mouth 17 of the excavation 1 is carried out on the clutch 28 with the possibility of changing the structure of the composition, in particular, mixing its components or structural compaction. By means of this, the composition is solidified in the area of technologically regulated location of said stemming unit 28 in cavity 2 of mine 1.

Distinctive features of the patented method is the following.

As the mentioned fixed along the axis of the excavation 1 thrust means with a surface in contact with the aforementioned stemming 28, a technological structure is used, which is structurally performed with the possibility of its placement in the cavity 2 of the excavation 1 at a distance technologically specified from the mouth 17 of the excavation 1. For this purpose, a stop-measuring element (means 19), rigidly connected with the said structure, with means for positioning it in the working cavity 2 relative to the mouth 17 of the last and subsequent fixation of this stop means relative to the fixed base structure (for example, a section 21 of the rock surface adjacent to the mouth 17 generation 1) in place of it (i.e., persistent means) of a regulated installation in cavity 2 of generation 1.

As a composite hardening stemming, it is permissible to use:

- polymer or mineral composite stemming 28 with a two-chamber ampoule, wherein said external axial action from the side of the mouth 17 of the mine 1 is carried out by means of a dynamic impact directed along the longitudinal axis of the mine 1, whereby the ampoule shell is destroyed and, as a result, the cavities located in the chambers are mixed ampoules hardening after mixing the components and filling with this composite mixture the cavity 2 of the mine 1 in the zone where the ampoule is located before hardening using said mixture;

- pre-soaked mineral composite stemming 28 with a single-chamber ampoule, wherein said external axial action from the side of the working mouth 17 is carried out by means of a dynamic impact directed along the longitudinal axis of the working 1, whereby the ampoule shell is destroyed and, as a result, the working cavity 2 is filled with the mineral composite mixture 1 in the ampoule location zone before the said mixture solidifies;

- pre-soaked mineral sand-cement mixture, with the mentioned external axial impact from the side of the mouth 17 of the mine 1 is carried out by means of a dynamic impact directed along the longitudinal axis of the mine 1, whereby the structure of the mixture is compacted until the cavity 2 of the mine 1 is completely filled with this mixture technologically predetermined zone before mixture hardening;

- pre-soaked mineral sand-clay mixture, while the mentioned external axial impact from the side of the mouth 17 of the excavation 1 is carried out by means of a thermodynamic shock directed along the longitudinal axis of the excavation 1, due to which the structure of the mixture is compacted until the cavity 2 of the excavation 1 is completely filled with this mixture in a technologically defined zone before the mixture hardens.

The persistent means for installing in the cavity 2 of the development 1 in the form of a hole or a well a composite hardening stemming during drilling and blasting operations (according to claims 6 and 7 of the claims), which implements the above method, is structurally made with at least one end surface 31, which is functionally means of contact with the aforementioned stemming 28.

Distinctive features of this persistent tool is the following.

The stop means is made in the form of a disk 29 with technological recesses 30, which are functionally means for accommodating the conductors 4 of the initiating pulse of the detonator 3. The technological recesses 30 are spatially arranged with the possibility of outputting the free ends of the said conductors 4 beyond the clogging 28 towards the mouth 17 of the output 1. When this said disk 29 is equipped with a rigidly connected locking-measuring element (means 19), which is made in the form of a strap with a technologically predetermined length. Moreover, this bar is equipped with a L-shaped protrusion 20 at its end, extending beyond the mouth 17 of the mine 1, which, together with the said bar, is functionally an element for fixing the disk 29 in the cavity 2 of the mine 1 at a technologically predetermined distance relative to the mouth 17 of the mine 1 base structure. Preferably, the rock surface portion 21 adjacent to the mouth 17 of the mine 1 is functionally used as the basic structure. In this case, the L-shaped protrusion 20 is equipped with a thrust surface 22 to ensure contact with said rock surface section 21.

It is advisable that the L-shaped protrusion 20 would be mounted on the said bar with the possibility of its movement relative to the latter along the metric-scale locking element (means 19) made on the bar.

The persistent means for installing in the cavity 2 of the development 1 in the form of a hole or a well a composite hardening stemming device 28 during drilling and blasting operations (according to claims 8-11 of the claims), which implements the above method, is structurally made with at least one end surface 31, functionally which is a means of contact with said stemming 28.

Distinctive features of this persistent tool is the following.

The stop means is formed in the form of a mechanical stemming made in the form of a spacer shutter 6 of a wedge type, structurally including: an outer sleeve 7 with sliding structures 8 and 9 and an element 10 placed in its cavity with an outer wedge surface interacting with the inner surfaces 13 and 14 sliding structures 8 and 9 of the sleeve 7. Moreover, in the above-mentioned elements of the expansion valve 6, technological channels 15 and 16 are functionally formed, which are functionally means for accommodating 4 in detonator pulsing pulse 3. Technological channels 15 and 16 are spatially arranged with the possibility of outputting the free ends of the said conductors 4 beyond the sleeve 7 towards the mouth 17 of the output 1.

The sleeve 7 is made with the end surface turned towards the working mouth 17, which is functionally a thrust surface to provide external dynamic action on this thrust surface along the axis of the sleeve 7 in the process of preliminary wedging of its sliding structures 8 and 9 while ensuring the movement of this sleeve 7 relative to the element 10 with at least one wedge surface. Moreover, the element 10 with a wedge surface is equipped with structural and technological locking and measuring means 19, which are mechanically connected in the axial direction with this element 10. In addition, the said locking and measuring means 19 are equipped with structural and technological reference elements and is functionally a means of determining the regulated position installation of the expansion valve 6 relative to the mouth 17 of the output 1 and, accordingly, the means of communication of the element 10 with a wedge surface with a fixed base structure for fixing said element 10 with a wedge surface in a predetermined position at the place of the regulated installation of the expansion valve 6 during said wedging of the sliding structures 8 and 9 of the sleeve 7. At least one end surface 31 of the outer sleeve is used as a surface in contact with the stem 28; facing towards the mouth 17 of the mine or element 10 with at least one wedge surface.

The stop-measuring element (means 19) can be made in the form of a flexible structure, for example, in the form of a cord or tape, with reference elements in the form of a metric scale, the free end of which is functionally a communication element with the fixed base structure, for example, an operator’s hand holding a free end of flexible structure.

The stop-measuring element (means 19) can also be made in the form of a bar with a technologically predetermined length, which is functionally a structural structure of the element 10 with at least one wedge surface. Moreover, this strip has a L-shaped protrusion 20 at its end, extending beyond the sleeve 7, which is functionally a reference element of communication with a fixed base structure, for which, for example, a section 21 of the rock surface adjacent to the mouth 17 of the mine 1 is functionally used. In this case, the L-shaped protrusion 20 is equipped with a thrust surface 22 to ensure contact with said section 21 of the rock surface.

It is advisable that the L-shaped protrusion 20 would be mounted on the bar of the stop-measuring element (means 19) with the possibility of its movement relative to the latter along the metric scale made on the bar of the stop-measuring element (means 19).

It is completely obvious that the design options of the patented locking means disclosed above (in particular, in the form of a wedge type spacer or disk), particular cases of constructive execution of the locking means itself and its locking-measuring elements (see paragraphs 7-11 of the formula) are not unique possible for the implementation of the technical result indicated in the application materials, but are given only as an example of the possibility of its implementation. Other constructive options for the implementation of persistent means with stop-measuring elements are also possible, functionally implementing the method according to claim 1, which are not disclosed in the framework of this application, since they are the design and technological “know-how” of the applicant.

For example, persistent means for implementing the method of installing in the cavity 2 of the development 1 in the form of a hole or a well of a composite hardening stemming during drilling and blasting operations may include the following functional elements and structures.

Two mutually movable structural elements 23 and 24 with counter-directed wedge surfaces 25 and 26, interacting with each other in the working position of these structural elements 23 and 24 when they are wedged in the process of relative movement.

Moreover, in at least one of the said elements 23 and 24 of the expansion valve 6, technological channels 15 and 16 are functionally formed, which are functionally means for accommodating the conductors 4 of the initiating pulse of the detonator 3. These technological channels 15 and 16 are spatially arranged with the possibility of outputting the free ends the above-mentioned conductors 4 outside the spacer gate 6 and, accordingly, outside the functional cavity 2 of the output 1.

The first of the mutually movable structural elements 23 is made with the end face 1 of the excavation 1 having an end surface of a larger area, which is functionally a persistent surface to provide external dynamic action on this surface along the axis of the expansion bolt 6 (or functional cavity 2 of the excavation 1) during wedging with providing movement of this first element 23 with a wedge surface relative to the second response element 24 interacting with it.

The second mutually movable element 24 of the expansion bolt 6 is equipped with a structural and technological locking and measuring means 19, which is mechanically connected in the axial direction with this second element 24.

Moreover, the said locking-measuring means 19 is equipped with structural and technological reference elements and is functionally a means of determining the position of the regulated installation of the expansion bolt 6 from the mouth 17 of the output 1 and, accordingly, a means of coupling the second structural element 24 with a fixed base structure for fixing the said second element 24 in a predetermined position at the place of the regulated installation of the expansion valve 6 in the process of wedging of its mutually movable elements 23 and 24.

The most appropriate locking and measuring means 19 to perform in the form of strips with a technologically predetermined length, which is functionally a structural structure of the second (axially held) structural element 24 of the expansion valve 6.

Moreover, this strip has a L-shaped protrusion 20 at its end (extending beyond the spacer shutter 6 and facing the mouth 17 of the mine 1), which is functionally a reference element of communication with the said fixed base structure (which, for example, can functionally be used section 21 of the surface of the rock adjacent to the mouth 17 of the development 1).

In this case, the L-shaped protrusion 20 must be equipped with a thrust surface 22 to ensure contact with the aforementioned section 21 of the rock surface.

The functioning of the above stated persistent means is disclosed in detail on the example of a method for implementing the technology of loading a production in the form of a hole or a well during drilling and blasting operations using this clogging, which is as follows.

The method includes sequential installation in the functional cavity 2 of the pre-drilled mine 1:

- detonator 3 with conductors 4 of the initiating pulse;

- directly subversive charge 5;

- and mechanical stemming in the form of a spacer shutter 6 of a wedge type, structurally including an external sleeve 7 with sliding structures 8 and 9 and an element 10 with a wedge surface 11 and 12 located in its cavity, interacting with the internal surfaces facing it 13 and 14 sliding sleeve structures.

As a rule, the expansion valve 6 is made of an elastically deformable material (for example, plastic or other polymeric material).

Moreover, before installing the said spacer shutter 6 in the technological channels 15 and 16 formed in its structural elements, conductors 4 of the initiating pulse of the detonator 3 are placed with the output of their (conductors 4) ends beyond the functional cavity 2 of generation 1.

After entering the spacer shutter 6 at the mouth 17 of the excavation 1, it is conducted along the excavation 1 by means of the technological rod-blocker 18 at a predetermined distance and the spacer shutter 6 is fixed in this position.

To carry out the indicated fixation of the spacer shutter 6, the sliding structures 8 and 9 of the sleeve 7 are wedged by means of an external dynamic action along the arrow F on the end surface of the said sleeve 7 (located on the side of the working mouth) along the production axis by means of the aforementioned stem-block 18 in the direction of the installed blasting charge 5 to allow movement along arrow S of this sleeve 7 relative to element 10 c of at least one wedge surface 11 and 12.

In the process of the aforementioned posting operation of the spacer shutter 6, structural and technological locking and measuring means 19 are used, which are fixed in the axial direction relative to the element 10 with at least one wedge surface 11 and 12 of the shutter 6.

The distance of the regulated installation of the expansion valve 6 from the mouth 17 of the development 1 is recorded on the reference elements. As a particular embodiment of the reference element, for example, a structural and technological locking protrusion 20 formed on the locking means 19 can be used. Moreover, in the process of wedging the aforementioned sliding structures 8 and 9 of the sleeve 7 of the expansion valve 6, mechanical retention is carried out in the axial direction of the element 10 with at least one wedge surface 11 and 12, at the place of the regulated installation of the expansion bolt 6. For this, a locking-dimensional means 19 relative to the stationary base structure.

It is permissible to use a flexible structure as a stop-measuring means 19, for example, in the form of a cord or tape with reference elements in the form of a metric scale, and as an immovable base structure, it is functional to use an operator's hand holding the free end of the cord or tape.

It is optimal, as mentioned above, to use an element, for example, in the form of a strap with a technologically predetermined length, which is functionally a structural structure of an element 10 with at least one wedge surface 11 and 12, and this structure should have G -shaped protrusion 20 at its end, located in the zone of the mouth 17 of the mine 1, and in this case, it is advisable to functionally use a section 21 of the rock surface adjacent to the mouth 17 of the mine, the latter is brought into contact with the abutment surface 22 of the L-shaped protrusion 20 during the operation of posting the expansion bolt 6 along the working 1. After the above operations are carried out, the composite hardening stemmer 28 is inserted into the functional cavity of the abutment 28 against the end face of the abutment means facing it, stemming 28 external axial dynamic impact with the ability to change the structure of the composition (mixing its compositions or compaction)

It is completely obvious that in any embodiment of the method using patented structural embodiments of mechanical jamming, it is permissible to use 4 initiating pulses as conductors: electrical wires, a blasting cord with thermal combustible material, or a waveguide, mainly fiber-optic (depending on the design of the blasting detonator used) .

Thus, the above information indicates the fulfillment of the following set of conditions when using the claimed technical solutions:

- objects that embody the claimed technical solutions during their industrial implementation, are intended for use in the field of drilling and blasting in strong rocks and can be used in various industries using blasting (mainly in rock massifs of rocks, i.e. at objects mining and non-metallic industry); in particular, they can be used: when felling buildings, structures, crushing foundations and sintered ore; blasting in underground and mining operations; blasting during tunneling and the construction of subway tunnel lines, etc.

- for the declared objects as described in the independent clauses of the formula below, the possibility of their implementation using the means and methods described above or known from the prior art on the priority date is confirmed;

- objects that embody the claimed technical solutions in their implementation are able to achieve the achievement of the technical result perceived by the applicant: ensuring the fixation of the composite hardening stemming by means of a persistent means (for example, expansion bolt 6) in its working (i.e. fixed in the development 1) position on the technologically a predetermined distance from the mouth 17 of the mine 1, ensuring the complete exclusion of its dynamic contact with the explosive explosive charge 5 while simplifying the design using emogo in the method of the expansible shutter 6 due to the exclusion of its cylinder structure.

Therefore, the claimed technical solutions meet the requirements of the patentability conditions "industrial applicability" under the current law.

Claims (11)

1. The method of installation in the cavity of the hole in the form of a hole or well of a composite hardening stemming during blasting operations, according to which the aforementioned stemming is placed in contact with at least one surface fixed along the longitudinal axis of the development of the stopping means, after which the stemming is carried out external axial dynamic impact from the side of the working mouth with the ability to change the structure of the composition, whereby it provides solidification in the zone of technological regulations tied arrangement of the said stemming in the working, characterized in that as the mentioned fixed along the axis of the working of the stop means with the surface in contact with the said stinging, a technological structure is used, which is structurally performed with the possibility of its placement in the working at a distance technologically specified from the mouth of the working, which uses a lock-and-measure element rigidly connected with the said structure with a means of its positioning in the development relative to the mouth the last and subsequent fixation of this persistent means relative to the fixed base structure in place of it, i.e. persistent means, regulated installation. 2. The method according to p. 1, characterized in that as a composite hardening stemming, a polymer or mineral composite stemming with a two-chamber ampoule is used, wherein said external axial action from the side of the working mouth is carried out by means of a dynamic impact directed along the longitudinal axis of the working, whereby carry out the destruction of the ampoule shell and, as a result, provide mixing of the components hardened after mixing of the components placed in the chambers of the ampoule cavity and filling with that composite mixture of the working cavity in the ampoule location zone before the said mixture solidifies. 3. The method according to p. 1, characterized in that as the composite hardening stemming, a previously soaked mineral composite stemming with a single-chamber ampoule is used, wherein said external axial action from the side of the working mouth is carried out by means of a dynamic impact directed along the longitudinal axis of the working, whereby provide destruction of the ampoule shell and, as a result, fill the cavity of the mine in the zone of the ampoule location before hardening with the mineral composite mixture eat said mixture 4. The method according to p. 1, characterized in that as the composite hardening stemming using a pre-soaked mineral sand-cement mixture, the above-mentioned external axial action from the side of the mouth of the mine is carried out by means of a dynamic impact directed along the longitudinal axis of the mine, whereby compaction of the structure of said mixture until the production cavity is completely filled with this mixture in the technologically defined zone before the mixture hardens 5. The method according to p. 1, characterized in that as a composite hardening stemming using a pre-soaked mineral sand-clay mixture, while the mentioned external axial impact from the side of the mouth of the mine is carried out by means of thermodynamic shock directed along the longitudinal axis of the mine, due to which provide compaction of the structure of the said mixture until the mixture completely generates a cavity in the technologically predetermined zone before the mixture solidifies. 6. Resistant means for installing in the cavity of the hole in the form of a hole or a well a composite hardening stemming during drilling and blasting operations, which is structurally made with at least one end surface that is functionally a means of contact with the said stemming, characterized in that the persistent means is made: in the form of a disk with technological recesses, which are functionally means for accommodating the conductors of the initiating pulse of the detonator, which, i.e. technological recesses, spatially arranged with the possibility of withdrawing the free ends of the above-mentioned conductors beyond the stemming in the direction of the mouth of the mine; wherein said disk is equipped with a lock-measuring element rigidly connected to it, which is made in the form of a bar with a technologically predetermined length; moreover, this bar is equipped with a L-shaped protrusion at its end, extending beyond the mouth of the mine, which together with the said bar is functionally an element of fixing the disk in the cavity of the mine at a technologically predetermined distance relative to the mouth of the mine through the basic structure, which is mainly used as a function , a section of the surface of the rock adjacent to the mouth of the mine, while the L-shaped protrusion is equipped with a persistent surface to ensure contact with the said section rock surface. 7. A persistent tool according to claim 6, characterized in that the L-shaped protrusion is mounted on said bar with the possibility of its movement relative to the latter along a metric scale made on the bar of the locking-measuring means. 8. Resistant means for installing in the cavity of the hole in the form of a hole or a well a composite hardening stemming during blasting, which is structurally made with at least one end surface, which is functionally a means of contact with the said stemming, characterized in that it is formed in the form mechanical stemming, made in the form of a wedge type expansion bolt, structurally including: an external sleeve with sliding structures and an element with an external wedge placed in its cavity surface cooperating with a facing inner surfaces thereto sliding sleeve structures; moreover, technological channels are functionally formed in the said spacer gate elements, which are functionally means for accommodating the conductors of the initiating pulse of the detonator, which, i.e. technological channels, spatially arranged with the possibility of outputting the free ends of said conductors beyond the sleeve toward the mouth of the mine; and the sleeve is made with the end surface facing the working mouth, which is functionally a thrust surface to provide an external dynamic impact on this thrust surface along the axis of the sleeve during the preliminary wedging of its sliding structures while ensuring the movement of this sleeve relative to the element with at least one a wedge surface, while the element with a wedge surface is equipped with a structural and technological locking and measuring means, which is mechanically connected ano in the axial direction with this element; in addition, the said locking-measuring means is equipped with structural and technological reference elements and is functionally a means of determining the position of the regulated installation of the expansion bolt relative to the mouth of the output and, accordingly, a means of coupling the element with the wedge surface with a fixed base structure for fixing the said element with the wedge surface in predetermined position at the place of the regulated installation of the expansion valve in the process of said wedging Sliding sleeve structures, and as the surface contacting the tamping used, at least one end surface of the outer sleeve facing towards the mouth generation element or with at least one wedge surface. 9. Resistant means according to claim 8, characterized in that the locking and measuring means is made in the form of a flexible structure, for example, in the form of a cord or tape, with reference elements in the form of a metric scale, the free end of which is functionally a communication element with the fixed base structure , for example, with the hand of an operator holding the free end of a flexible structure. 10. The persistent tool according to claim 8, characterized in that the stop-measuring means is made in the form of a strap with a technologically predetermined length, which is functionally a structural structure of an element with at least one wedge surface; moreover, this strap has a L-shaped protrusion at its end, extending beyond the sleeve, which is functionally a reference element of communication with a fixed base structure, for which, for example, a section of the rock surface adjacent to the mouth of the mine is functionally used, while the L-shaped the protrusion is equipped with a persistent surface to ensure contact with said portion of the rock surface. 11. The thrust means according to claim 10, characterized in that the L-shaped protrusion is mounted on the bar of the stop-measuring means with the possibility of its movement relative to the latter along the metric scale made on the bar of the stop-measuring means.

Images