RU146845U1 - DISC TOOL DRIVING COMBINE - Google Patents

Abstract

1. A disk tool of a roadheader, containing an arrow, two axial destroying crowns, a transfer gear housing, part of which is facing the face of the face and made in the form of a sector of a cylinder with a coverage angle φ≤π / 2, to the outer surface of which according to a certain set pattern on tetrahedral prisms attached paired disc tools on fixed axes with thrust flanges, remote end washers and spigots-bushings, characterized in that the paired disc tools are made in the form of a single a collapsible structural unit with the possibility of joint free rotation relative to the fixed trunnion-bushings on a tetrahedral prism. 2. A tunneling tool according to Claim 1, characterized in that each axle sleeve consists of an end stop collar rigidly attached to the outer surface of the working face of the tetrahedral prism and a cantilever cylindrical surface located in the cylindrical through hole of the working face with access to the inner space area tetrahedral prism. 3. A tunneling tool according to claim 1, characterized in that the single collapsible structural unit includes two axes rigidly attached to each other with thrust collars, one of which contains a spline shaft and the other contains a spline sleeve. 4. A tunneling tool according to claim 3, characterized in that the axis with a thrust shoulder and a splined shank is made with a stepped through hole, inside of which there is a remote screw for fastening a single collapsible structural unit �

Description

The proposed utility model relates to the mining industry, namely, to the executive bodies of tunneling harvesters of selective action and is intended for mining of coal and mixed slaughter with strong and abrasive rock layers and individual inclusions.

A well-known executive body of a roadheader (RF patent No. 2455486, IPC E21C 25/18, E21C 27/24, publ. 10.07.2012, Bull. No. 19), including an arrow, a transfer gear and two destructive loading crowns, the axes of which are parallel to the longitudinal the axis of the arrow. The body of each of the destructive loading crowns is made in the form of a truncated conical surface, or in the form of truncated polyhedral pyramids. On the outer surfaces of the shells of the crushing and loading crowns, trihedral prisms are installed with attachment points for disk tools and axle-axles. A disc tool freely mounted on each axle axle is cantilevered to one of the faces of the trihedral prisms. The fastening part of the pivot axis is located inside the trihedral prism and is rigidly attached with bolts and a lock bar to the partition. On both sides of the disk tool, remote end rings are installed that perform the function of thrust bearings that absorb axial loads during failure.

The disadvantages of this executive body of the tunneling machine is the inability to drill radial crowns by axial telescopic extension of the boom.

Closest to the technical solution to the claimed utility model is the executive body of a tunneling machine of selective action (RF patent No. 136086, IPC E21C 25/18, E21C 27/24, publ. 12/27/2013, Bull. No. 36), including an arrow, a transfer case gear, two destructive axial crowns with cutters, as well as hydraulic jacks for turning, lifting and telescopic boom extension. Part of the housing of the transfer gearbox faces the surface of the face and is made in the form of a sector of the cylinder with a coverage angle φ≤π / 2, on the outer surface of which tetrahedral prisms with paired disk tools are installed in a checkerboard pattern, fitting into the gap space between the cutting lines formed by the extreme cutters with the sides of the large bases of the destructive axial crowns facing the end surfaces of the housing of the transfer gearbox. The radial extension of the wedge cutting edges of the paired disk tool does not exceed the radial extension of the extreme incisors on large bases of axial crowbar destructive crowns.

The disadvantages of the prototype are the separate rotation mode of each of the disks of a paired disk tool, which increases the likelihood of it jamming, stopping rotation and premature wear when notching the swept executive body of a roadheader in the rock mass.

The technical result of the claimed utility model consists in combining the rotation modes of a paired disk tool to reduce its jamming and wear when cutting an arrow-shaped executive body of a roadheader in a mountain range.

The specified technical result is achieved by the fact that, a disk tool of a roadheader containing an arrow, two axial destroying crowns, a transfer gear housing, part of which is facing the face of the face and made in the form of a sector of a cylinder with a coverage angle φ≤π / 2, to the outer surface of which according to a certain dialing pattern, tetrahedral prisms are attached paired disc tools on fixed axes with thrust collars, spacer end washers and spigots-bushings, according to the utility model, with paired disk tools are made in the form of a single collapsible structural unit with the possibility of joint free rotation relative to the fixed trunnion-bushings on a tetrahedral prism.

The indicated technical result is also achieved by the fact that each trunnion-pin consists of an end stop collar rigidly attached to the outer surface of the working face of the tetrahedral prism and a cantilever cylindrical surface located in the cylindrical through hole of the working face with access to the inner space of the tetrahedral prism.

The specified technical result is also achieved by the fact that a single collapsible structural unit is made in the form of two axes rigidly attached to each other with thrust shoulders, one of which contains a spline shank, and the other contains a spline sleeve.

The specified technical result is also achieved by the fact that the axis with a thrust shoulder and a splined shank is made with a stepped through hole, inside of which there is a remote screw for fastening a single collapsible structural unit with a lock washer on the side of the hex head, the threaded portion of which is fixed in a blind threaded socket, which is made in the end of the axis with a thrust shoulder and a spline sleeve facing the spline shank, so that between the distance end washers about espechen minimum allowable gap for the formation of bilateral thrust sliding bearing.

The specified technical result is also achieved by the fact that from the side of the free end of the axis with a thrust shoulder and a spline sleeve, a turnkey hexagonal recess is made.

The indicated technical result is also achieved by the fact that in each of the paired disc tools there are two-stage openings, the first steps of each of which have a larger diameter and the cylindrical axle collars are inscribed and completely recessed either with a splined shank or with a splined sleeve, and the second steps are made in the form of through holes with grooves for key connections of mutually mating surfaces of disk tools and axes with thrust collars.

The specified technical result is also achieved by the fact that the length of the threaded connection of the remote screw with the threaded socket in the axis with the thrust shoulder and spline sleeve exceeds the length of the mating portion of the spline connection.

The essence of the utility model is illustrated by drawings, where in Fig.1. shows a top view of the actuator with axial cutters and a disk tool on the case of the transfer gear; figure 2 shows the frontal projection of a paired disk tool on a tetrahedral prism; figure 3. shows a top view of arrow A in figure 2; figure 4. shows a side view along arrow B in figure 2; figure 5. - a section along BB in FIG. 3; in Fig.6. a scheme for processing the face of a tunneling mine with a rectangular shape by the executive body of a tunneling machine of selective action is presented; in Fig.7. shows a top view of the arrow G in Fig.6.

The disk tool of the roadheader (Figs. 1–7) contains an arrow 1, the housing of the transfer gearbox 2 and two axial destroying crowns 3 with cutters 4. A part of the housing of the transfer gearbox 2 faces the surface of the face and is made in the form of a sector of a cylinder with a coverage angle φ≤π / 2, on the outer surface of which tetrahedral prisms 5 with paired disc tools 6 are staggered, fitting into the gap space between the cutting lines formed by the extreme cutters 4 (Fig. 1) from the side of large bases, destroying their axial crowns 3, facing the end surfaces of the housing of the transfer gear 2. The radial radius of the wedge cutting edges of the paired disk tool 6 does not exceed the radial radius of the extreme cutters 4 on large bases of axial crowns destroying 3.

The tetrahedral prism 5 (Figs. 1-5) consists of two working faces 7 with through cylindrical holes 8 (Fig. 5) located parallel to the planes of rotation of the destructive axial crowns 3 (Fig. 1) and two side faces 9 (Figs. 1- 3), and inside each through cylindrical hole 8 there is a trunnion-hub 10. In this case, paired disc tools 6 are made in the form of a single collapsible structural unit with the possibility of joint free rotation relative to the fixed trunnions-bushings 10 on a tetrahedral prism 5. Each PFA-sleeve 10 comprises a mechanical thrust collar rigidly attached to the outer surface of the working faces 7 tetrahedral prisms 5 and the cylindrical surface of the cantilever, placed in a through cylindrical opening 8 Cutting Edge 7 with access to the internal space of a tetrahedral prism zone 5.

A single collapsible structural unit (figure 5) is made in the form of two axes 11, 12 rigidly attached to each other with thrust flanges, one of which contains a spline shank, and the other contains a spline sleeve.

The axis 11 with a stop collar (Fig. 5), containing a splined shank, is made with a working cylindrical surface, the diameter of which is larger than the diameter of the shank and has one of the zones, providing key connection of the disk tool 6 by means of a key-retainer 13 from the side of the stop collar and the second zone , providing the possibility of free rotation relative to the inner surface of the trunnion sleeve 10 with an end stop shoulder.

The axis 12 with a stop collar (Fig. 5), containing a spline sleeve, is made with a working cylindrical surface, the diameter of which is larger than the diameter of the outer surface of the spline sleeve and has one of the zones providing key connection of the disk tool 6 by means of a key-retainer 13 from the side of the stop collar and the second zone, providing the possibility of free rotation relative to the inner surface of the trunnion sleeve 10 with an end stop shoulder.

Two remote end washers 14 (Fig. 5) of the paired disk tool 6 are placed between the end surfaces of each of the two disk tools 6 and the end surfaces of the thrust flanges of each of the two journal pins 10 on the working faces 7 of the tetrahedral prism 5 so that one of the end spacer washers 14 are freely placed on the axis 11 with the thrust shoulder of the splined shank, and the other is freely placed on the axis 12 with the shoulder of the spline sleeve.

The axis 11 with a thrust shoulder and a splined shank (Fig. 5) is made with a stepped through hole 15 (Figs. 4, 5), inside of which there is a remote screw 16 for fastening a single collapsible structural unit with a washer-retainer 17 from the side of the hex head , the threaded portion of which is tightly fixed in a blind threaded socket, which is made in the end of the axis 12 with a stop collar and a spline sleeve facing the spline shank, so that between the end spacers 14 there is provided a minimum invertible gap to form a double thrust sliding bearing.

On the side of the free end of the axis 12 with a stop shoulder and a spline sleeve, a turnkey hexagonal recess 18 is made (Fig. 5).

In each of the paired disc tools 6, two-stage openings are made, the first steps of each of which have a larger diameter and the cylindrical flanges of the axes 11, 12 are either inscribed and completely recessed either with a splined shank or with a splined sleeve, and the second steps are made in the form of through holes 15 with slots for keyed joints of mutually mating surfaces of disk tools 6 and axles 11, 12 with thrust flanges.

The length of the threaded tensioned connection of the remote screw 16 with the threaded socket in the axis 12 with a stop shoulder and a spline sleeve exceeds the length of the mating portion of the spline connection.

From the open end of the inner space of the tetrahedral prism 5 there is a tetrahedral cover 19 (Figs. 1, 2, 3, 5) congruently inscribed in the inner tetrahedral contour of the prism 5, with a wall thickness b (Fig. 2) that overlaps the peripheral part of the inner space of the tetrahedral prism 5 from the external bottomhole workspace. In the outer surfaces of the tetrahedral cover 19, adjacent to the inner surfaces of the faces of the tetrahedral prism 5, technological chambers 20 are made (FIGS. 3, 5) for assembly and disassembly operations. On the outside of the tetrahedral cover 19, there are through cylindrical recesses 21 (FIGS. 2, 3), inside of which are placed the bolts 22 with a cylindrical head, a hexagonal recess for the key and lock washers 23, fixing the tetrahedral cover 19 on the upper surfaces of the bonks 24 with blind threaded holes (FIGS. 2, 5) fixed on the faces in height h (FIG. 2) from the surface of the housing of the transfer gear 2 on the lower base of the bonks 24 in the inner space of the tetrahedral prism 5. In the middle part of the wall, thickness b is tetrahedral constant lid 19 (2, 5) is contoured recess, wherein the contour taken by the O-ring 25 is elastically pressed against the inner surface of a tetrahedral prism 5.

The utility model at the stage of installation of paired disk tools made in the form of a single collapsible structural unit in a tetrahedral prism (Fig.1-5) is as follows.

In turn, each trunnion trunnion 10 with an end stop shoulder is rigidly fixed by welding to the outer surface of the working face 7 of the tetrahedral prism 5 so that its cantilever cylindrical surface is located in the through cylindrical hole 8 of the working face 7 with access to the inner space of the tetrahedral prism 5.

The disk tools 6 are secured by keyed connection on the axes 11 and 12 to the stop with their thrust collars respectively with a splined shank and a spline sleeve, then the distance end washers 14 are placed. After that, the axles 11 and 12 are assembled in the inner space of the tetrahedral prism 5 by hard fixing remote screw 16 with a spring washer 17 of the spline shank in the spline sleeve.

Then, in the interior of the tetrahedral prism 5, a tetrahedral cover 19 is installed (Fig. 5) until it stops with the upper bases of the bonnets 24 and is attached to the bonnets 24 with bolts 22 (Fig. 2) with cylindrical heads and spring washers 23 with a secret hex key in cylindrical recesses 21. When this contour sealing ring 25 (Fig.2, 5) of the tetrahedral cover 19 is elastically pressed against the inner surfaces of the faces of the tetrahedral prism 5, sealing the inner space of the tetrahedral prism 5.

When driving a mine work the utility model is as follows (Fig.6, 7).

The executive body of a selective-driving tunneling machine cycles through the development of a rectangular section in height H and width B. Preparation for a driving cycle begins with the notch process in the central part of the mine. In the process of notching the boom 1 of the executive body of the roadheader by the required depth in the direction of the longitudinal axis of the excavation or by the width of the transverse grip b ₃ (Fig. 7), the reciprocating movements of the boom 1 in the vertical plane (Fig. 6) from the roof to the soil are combined production, and vice versa, with a gradual telescopic extension to a given working width b ₃ with continuous rotation of two destructive axial crowns 3 with cutters 4 (Fig.6). This process is ensured by the simultaneous operation of lifting jacks and telescopic boom extension 1. The notching process is performed on the notch front width b _fr (Fig. 7), including the width of the left b _varnish and the right b _{pack of} axial destroying crowns 3, as well as the width b _{cr of the} case of the transfer gearbox 2 in the form of a sector of a cylinder with a coverage angle φ≤π / 2, on the outer surface of which with a certain set pattern tetrahedral prisms 5 are attached (Figs. 6, 7) with paired disc tools 6 operating in the plow installation mode.

After the notch (Fig.7), it is advisable to use the trajectory of the boom 1 (Fig.6) with destructive axial crowns 3, carried out in the directions of movement 1′-19 ′. In the directions of movement 1′-11 ′, the processes of destruction prevail, and in the direction of movement 1′-3 ′, 17′-19 ′, the processes of destruction and cleaning of ridges-ridges on the surfaces of the roof and soil of the mine prevail. After the final cleaning of the soil from the products of destruction along the entire width B of the excavation (Fig. 6), the roadheader is fed forward to the face, and boom 1 reduces the telescopic extension by hydraulic jacks by a value of b ₃ (Fig. 7) and the next working cycle for processing the face is repeated.

Thus, the design of the utility model allows you to combine the rotation mode of the paired disc tool, to reduce the process of jamming and wear during the notching of the swept executive body of a roadheader in the rock mass.

Claims (7)

1. A disk tool of a roadheader, containing an arrow, two axial destroying crowns, a transfer gear housing, part of which is facing the face of the face and made in the form of a sector of a cylinder with a coverage angle φ≤π / 2, to the outer surface of which according to a certain set pattern on tetrahedral prisms attached paired disc tools on fixed axes with thrust flanges, remote end washers and spigots-bushings, characterized in that the paired disc tools are made in the form of a single collapsible structural unit with the possibility of joint free rotation relative to the fixed trunnions-bushings on a tetrahedral prism. 2. The disk tool of the roadheader according to claim 1, characterized in that each axle sleeve consists of an end stop collar rigidly attached to the outer surface of the working face of the tetrahedral prism and a cantilever cylindrical surface located in a cylindrical through hole of the working face with access to the zone the inner space of the tetrahedral prism. 3. The disk tool of the roadheader according to claim 1, characterized in that the single collapsible structural unit includes two axes rigidly attached to each other with thrust shoulders, one of which contains a splined shank, and the other contains a splined sleeve. 4. The disk tool of the roadheader according to claim 3, characterized in that the axis with a thrust shoulder and a splined shank is made with a stepped through hole, inside of which there is a remote screw for fastening a single collapsible structural block with a washer-retainer on the side of the hex head, the threaded portion of which is fixed in a blind threaded socket, which is made in the end of the axis with a thrust shoulder and a spline sleeve facing the spline shank, so that between the remote end With your washers, a minimum clearance is provided for the formation of a double-sided thrust sliding bearing. 5. The disk tool of the roadheader according to claim 3, characterized in that a turnkey hexagonal recess is made from the side of the free end of the axis with a stop shoulder and a spline sleeve. 6. The disk tool of the roadheader according to claim 3, characterized in that in each of the paired disk tools there are two-stage openings, the first steps of each of which have a larger diameter and the cylindrical flanges of the axes are inscribed and completely recessed either with a splined shank or with a splined sleeve, and the second steps are made in the form of through holes with grooves for the key connections of mutually mating surfaces of disk tools and axes with thrust collars. 7. The disk tool of the roadheader according to claim 4, characterized in that the length of the threaded connection of the remote screw with the threaded socket in the axis with the thrust shoulder and the spline sleeve exceeds the length of the mating portion of the spline connection.

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