RU2203418C2 - Load-bearing member - Google Patents

Abstract

FIELD: mining industry, design of load-bearing member, in particular. SUBSTANCE: salient feature of invention lies in that peripheral parts of body of load-bearing member are linked to central part by groove- and-protrusion joint, outer surface of each part has groove made along its generating line where fixing plate with fastening holes meant for connection of plate to parts of body is placed. Spreading inserts and inner sides of central split part of body corresponding to them have variable section which angle of opening diminishes as distance from pipe union supplying working substance grows, guiding groove is cut in inner surface of body. Bosses of spreading inserts are mounted in this groove for movement along it. Slot in guiding body is cut in parallel to plane of split of body of load-bearing member and in locking yoke where pipe union supplying working substance to flexible chamber is installed. Groove intended for placement of wedge- out pick is made along generating line of flexible chamber in plane of spreading inserts. Recesses are made in faces surfaces of spreading inserts. EFFECT: more efficient distribution of pressure between working parts of load-bearing member in process of operation, prevention of premature seizure and destruction of load-bearing member, increased functional reliability and simplified design of load-bearing member. 3 cl, 5 dwg

Description

 The invention relates to the mining industry, in particular, relates to the design of the power element.

 A known power element comprising a detachable along the longitudinal axis of the housing with annular cavities at its ends, an elastic chamber inside the housing, coaxial to it, spacer inserts located between the parts of the detachable housing along the plane of the connector, interacting with the elastic chamber, locking clips located at the ends of the housing, in one of which there is a fitting for supplying the working agent to the elastic chamber, as well as ring washers and elastic chamber seals located in the annular cavities of the detachable case (see patent US 4690460 by Cl. E 21 C 37/06, 1987 YG).

 In this power element, the elastic chamber is securely fixed to the inlet of the working agent by means of washers and elastic seals located in the annular cavity at the end of the housing.

 However, this technical solution does not prevent the rupture of the elastic tubular chamber during operation of the device at the time of formation of cracks in the destructible object.

 The closest technical solution to the proposed one is a power element containing a housing consisting of interconnected central and peripheral parts, while its central part is made detachable along the longitudinal axis, an elastic chamber located inside and coaxially to the housing, spacer inserts located between the parts of the housing along the connector and interacting with the elastic chamber, and with protrusions at the ends, locking clips located at the ends of the housing, in one of which there is a fitting for supplying the agent into the elastic chamber, the elastic chamber seals located in the annular grooves of the housing, the working agent volume limiter installed in the elastic chamber, made in the form of a spring-loaded ball valve placed in the fitting for supplying the working agent, and a pusher, one end of which is connected to the valve , a two-link articulated control element connected to the pusher, the second end of the element is fixed in a guide housing located in the elastic chamber and having a gap, and the link I, the hinge element is made of different lengths, with the possibility of contact in the working position by the connecting element of the links of the elastic chamber in its middle part through a slot in the guide body (see WO 00/03120 per class E 21 C 37/10, 1998).

 The known design of the power element is equipped with washers located between the spacer inserts and the working parts of the housing. A groove is made on the washer, in which protrusions made on spacer inserts are mounted with the possibility of movement.

 However, the working parts of the housing have a larger gap than between the washer and the seal, and the washer cannot compensate for this gap, because the elongation at the ends of the working parts is greater than that of the washer. And this leads to a rupture of the elastic chamber at the point of contact with the end face of the insert.

 The known design is difficult to manufacture and it is difficult to assemble and disassemble.

 The fixation of the constituent parts of the body, namely, the peripheral parts and the central part, by means of a connection like "Dovetail" does not provide sufficient mobility of the parts of the body relative to each other.

 During operation of the power element, a circular cylindrical displacement of one part of the housing relative to the other is possible, which leads to jamming of the element and to deformation of the complex connection like "Dovetail".

 A well-known situation when creating directional splits is that the split has a wedge-shaped cross section, in which a part of the body located closer to the mouth opens much more than another part located in the depth of the well. This leads to a skew of the inserts up to 10 mm with a working length of the element of 300 mm, and hence to jamming of the power element itself.

The technical objectives of the proposed solution are:
- to develop a power element that allows a more efficient distribution of pressure between its working parts during operation; by
- to exclude premature jamming, destruction of the power element;
- increase the reliability of the structure while simplifying it.

 The technical result in the present invention is achieved by the creation of a power element containing a housing consisting of interconnected central and peripheral parts, while its central part is made detachable along the longitudinal axis, an elastic chamber located inside and coaxially of the housing, spacer inserts located between the parts of the housing along the connector and interacting with the elastic chamber, and with protrusions at the ends, locking clips located at the ends of the housing, in one of which a fitting for the supply of the working agent to the elastic chamber, the seals of the elastic chamber located in the annular grooves of the housing, the limiter of the volume of the working agent installed in the elastic chamber, made in the form of a spring-loaded ball valve, placed in the fitting for supplying the working agent, the pusher associated with the valve and the control element , the end of which is fixed in the end slit of the guide housing located in the elastic chamber, in which, according to the invention, the peripheral parts of the housing are connected to the center the flange part is a groove – protrusion connection, and a groove is made on the outer surface along the generatrix of each body part, in which a fixing plate with mounting holes is arranged for connecting the plate to the body parts, and the spacer inserts and the corresponding inner sides of the central split part of the body are made of variable section , the angle of the solution of which decreases with distance from the fitting for supplying the working agent, and a guide groove is made on the inner surface of the housing, in which the mouth the protrusions of the spacer inserts are movable along it, while the slot in the guide body is parallel to the plane of the connector of the power element housing and on the locking clip, in which a fitting is installed for supplying the working agent to the elastic chamber, a groove is made along its generatrix in the plane of installation of the spacer inserts designed to accommodate proppant peaks, and a recess is made on the outer end surface of the spacer inserts.

 The invention is also characterized in that the variable cross-section of the inserts and the corresponding inner sides of the central split part of the housing is made in the form of steps, with each step of the insert corresponding to a step made on the corresponding inner side of the central split part of the housing.

 This allows you to eliminate the misalignment of the inserts, and hence the jamming of the power element. During operation, the ends of the insert and the corresponding inner side of the central split part of the housing having a larger opening angle move slower, and those that are opened less move faster, which leads to a uniform distribution of loads.

 The implementation of the protrusions of the spacer inserts in the form of protruding bevels eliminates the wear of the elastic chamber by the sharp edges of the inserts.

 In order to reduce friction between the spacer inserts and the housing elements, an antifriction material is applied to the outer surface of the spacer inserts and to the moving parts of the housing in contact with each other.

 In the proposed design, the execution on the inner surface of the housing of the guide groove in which the protrusions of the spacer inserts are installed with the possibility of moving along it allows for the same longitudinal extension of the inserts together with the working parts of the housing. And this means that the same gap between them is guaranteed.

The proposed design allows you to:
- get the additional force of the element, because the transmission coefficient of pressure from the elastic chamber to the housing is proportionally higher (before the coefficient was 8.1, in the proposed design 18.4);
- increase the coefficient of work of the power element by increasing the depth of the crack in the rock mass;
- significantly reduce the uneven disclosure of the ends of the housing.

 Conducted patent studies have shown that technical solutions with the indicated set of essential features are not known in similar designs of power elements, i.e. the proposed solution meets the criterion of "novelty."

 In the analysis of known analogues and prototype, no proposal was found with a combination of essential features set forth in the claims, which implies that for specialists involved in power elements, it does not explicitly follow from the prior art and, therefore, meets the criterion of "inventive step".

 We believe that the information set forth in the application materials is sufficient for the practical implementation of the invention.

 The invention is illustrated by the following construction description and drawings.

 In FIG. 1 shows a longitudinal section of a power element in its original position in the absence of pressure; figure 2 is a longitudinal section of a power element in operating mode; figure 3 is a section aa of figure 1; figure 4 is a section bB in figure 1; figure 5 - section bb in figure 4.

 The power element contains a housing consisting of a central 1 and peripheral 2 and 3 parts, the central part of which is detachable along its longitudinal axis.

 The peripheral parts 2 and 3 of the housing are connected to the central part 1 by a groove-protrusion connection. For this, for example, on the peripheral parts 2 and 3, protrusions 4 are made, and on the central part 1, grooves 5 corresponding to the protrusions.

 To prevent rotation of the components of the housing on the outer surface along the generatrix of each housing part, a groove 6 is made in which the fixing plate 7 is placed with mounting holes 8 for connecting the plate to the housing parts.

 Inside the housing coaxially to it is an elastic chamber 9 of a tubular shape, as well as spacer inserts 10.

 Each spacer insert 10 has a protrusion 11 on its end surface, made in the form of protruding bevels.

 The inserts 10 are placed between the corresponding inner sides of the central split part of the housing along the plane of the connector and interact with the outer surface of the chamber 9, and a guide groove 12 is made on the inner surface of the housing, in which the protrusions 11 of the spacer inserts 10 are mounted along it.

 At each end of the housing, locking clips 13 are connected, connected to the housing by elastic elements 14. Moreover, a fitting 15 is installed in one of the clips for supplying the working agent to the elastic chamber 9. A similar fitting 16 can be installed in the second clip for bleeding the working agent after the end of the working cycle .

 The fitting 15 for supplying the working agent to the elastic chamber is connected to it by means of a flange 17 of the peripheral part 3, an elastic seal 18 of triangular section made of a material whose elasticity is greater than the elasticity of the material of the elastic chamber 9.

 The elastic elements 14 can be made in the form of a flat prestressed springs.

 In the elastic chamber 9 is installed a limiter of the volume of the working agent, made in the form of a spring-loaded ball valve 19, placed in the fitting 15 for supplying the working agent.

 On the other hand, the ball valve 19 is in contact with the pusher 20, also installed in the nozzle 15 for supplying the working agent and fastened at its other end with a two-link hinged control element 21. The second end of the control element 21 is fixed in the guide housing 22 located in the elastic chamber 9 with adjusting sleeve 23.

 In the guide body 22, a slot 24 is made parallel to the plane of the connector of the power element, through which the control element 21 interacts with the inner wall of the elastic chamber 9.

 The links of the hinge element are made of different lengths.

 At the end of the adjusting sleeve 23, opposite to the fastening of the control element, there is a place 25 for placing the adjusting tool (not shown). The location can be multifaceted and depends on the profile of the tool.

 Spacer inserts 10 and the corresponding inner sides of the central split part of the housing are made of variable cross-section, the angle of the solution of which decreases with distance from the nozzle for supplying the working agent, and antifriction material 26 is applied to their outer surfaces.

 Anti-friction material is also applied to the moving parts of the housing in contact with each other.

 On the locking clip 13, in which the fitting for supplying the working agent is installed, a groove 27 is made along its generatrix in the installation plane of the spacer inserts 10, designed to accommodate the proppant peaks (not shown), and a recess 28 is made on the outer end surface of the spacer inserts.

 The pusher 20 has on the outer surface distributed along the circumference of the longitudinal channels 29 for passing the working agent.

The power element works as follows:
The pre-assembled power element is adjusted for a predetermined movement of the detachable body elements using the adjusting sleeve 23, after which it is connected to the supply channel of the source of the working agent and placed in a pre-prepared well.

 The working agent supplied through the fitting 15 expands the elastic chamber 9, transferring forces both directly through the detachable elements of the housing and through the spacer inserts 10, which due to the geometry of the section create uniform pressure on the working parts.

 The walls of the elastic tubular chamber 9, expanding under the influence of the working agent, and also due to the execution of the side walls of the elastic seal 18 at an acute angle to each other, press the flange 17 against the fitting 15, ensuring reliable fixation of the elastic chamber on the fitting.

 Uniform distortion-free movement of the detachable elements of the power element housing during the working cycle is achieved by the presence of a guide groove 12 on the inner surface of the housing, in which during the working cycle the protrusions 11 of the spacer inserts 10 are made in the form of protruding bevels.

 The two-link hinged control element 21, moving along the inner wall of the elastic chamber 9, causes the spring-loaded pusher 20 to move towards the central part of the power element.

 When the control element 21 reaches a predetermined amount of movement, the limiter of the volume of the working agent closes the inlet channel, preventing the entry of the working agent into the inner cavity of the elastic chamber 9.

 After the formation of cracks during the working cycle, the working pressure is reset to zero, while all the moving parts of the power element, interconnected by the plate 7 and the groove-protrusion connection, under the action of the plane preloaded springs 14, as well as due to the elasticity of the elastic chamber associated with spacers 10 and detachable body elements are returned to their original position.

 Additional regulation of the power element can be carried out with an adjustment tool. To do this, open the fitting 16 for bleeding the working agent, install the adjustment tool (not shown) in its hole in place 25 of the adjustment tool on the adjusting sleeve 23 and move it to the required distance in the guide housing 22.

 When the power element is jammed, a proppant (not shown) is inserted into the groove 27 of the locking collar and moved to contact the recess 28 on the outer end surface of the spacer inserts 10, and then, continuing their joint movement, the power element is wedged.

 The proposed power element was tested in the non-explosive separation of monolithic blocks from an array of natural stone, and also tested for the destruction and hardening of objects by creating directed cracks in them.

Claims (4)

 1. A power element comprising a housing consisting of interconnected central and peripheral parts, while its central part is made detachable along the longitudinal axis, an elastic chamber located inside and coaxially of the housing, spacer inserts placed between the parts of the housing along the connector and interacting with an elastic chamber and having protrusions at the ends, locking clips located at the ends of the housing, in one of which a fitting is installed for supplying the working agent to the elastic chamber, elastic cam seals s, located in the annular grooves of the body, the limiter of the volume of the working agent installed in the elastic chamber, made in the form of a spring-loaded ball valve, placed in the fitting for supplying the working agent, a pusher associated with the valve and the control element, the end of which is fixed in the end slit of the guide body located in an elastic chamber, characterized in that the peripheral parts of the housing are connected to the central part by a groove - protrusion connection and on the outer surface along the generatrix of the second part of the housing, a groove is made in which a fixing plate with fixing holes is arranged for connecting the plate to the parts of the housing, and the spacer inserts and the corresponding inner sides of the central split part of the housing are made of variable cross section, the opening angle of which decreases with distance from the nozzle for the supply of the working agent and on the inner surface of the housing a guide groove is made, in which the protrusions of the spacer inserts are mounted with the possibility of moving along it, while In the guide case, it is made parallel to the plane of the connector of the power element housing and on the locking sleeve, in which the fitting for supplying the working agent to the elastic chamber is installed, along its generatrix in the plane of installation of the spacer inserts, a groove is designed to accommodate the wedging peaks, and on the external end surface spacer inserts made a recess.  2. The power element according to claim 1, characterized in that the variable section of the inserts and the corresponding inner sides of the central split body part is made in the form of steps, with each step of the insert corresponding to a step made on the inside of the central split body part.  3. The power element according to claim 1, characterized in that the protrusions of the spacer inserts are made in the form of protruding bevels.  4. The power element according to claim 1, characterized in that antifriction material is applied to the outer surface of the spacer inserts and to the moving parts of the housing in contact with each other.

Images