RU2006579C1 - Gear for feed of sprinkling fluid to boring bit of mining machine - Google Patents

Abstract

FIELD: mining industry. SUBSTANCE: gear for feed of sprinkling fluid to boring bit of mining machine has bit holder, boring bit with cylindrical box, annular duct for passing of sprinkling fluid, stopping element, shut-off fixture with bearing ring and resilient sealing element and duct for feed of sprinkling fluid. Bit holder is attached to body of actuating tool and has through longitudinal duct and bearing surface. Boring bit is mounted in longitudinal duct of bit holder for turning and limited axial movement. Stopping element and bearing ring are placed in annular groove in shank part of box. Shut-off fixture has insert with V-shaped ducts, annular groove and bevels. Insert is installed for limited axial movement and interaction with its side bearing surfaces with face surface of box and with bearing surface of body of actuating tool. Sealing element is located in annular groove in shank part of box. Stopping element is made fast to bit holder and is mounted for interaction with bearing ring and side wall of annular groove in shank part of box. Duct for feed of sprinkling fluid through V-shaped ducts in insert communicates with space formed with walls of longitudinal duct in bit holder, surfaces of bevels in insert, shank part of box and sealing element. EFFECT: improved operational characteristics, increased reliability. 3 cl, 5 dwg

Description

 The invention relates to the mining industry and can be used to combat dust and its explosions from frictional heating of cutters and rocks during the operation of mining machines, mainly shearers and roadheaders.

 A device [1] is known, which can be used to control dust and explosion protection during operation of mining machines, including a notch head with a sleeve and cutters, which have the possibility of limited axial movement and are connected to the cylinder-piston in the form of a valve with a pusher, a working chamber, connected to a switched source of the working medium and the nozzle by means of a channel, as well as a cutter holder with a hole for supplying water under pressure and a spring.

 This device is inherent in design complexity to provide a very high pressure of the irrigating liquid (above 20 MPa, in particular 30-75 MPa) and reduce its leakage. An increase in fluid pressure leads to an increased flow rate for irrigation. The use of sprinklers with reduced nozzle diameters (up to 0.4-0.6 mm or less) can reduce fluid flow, but at the same time leads to frequent clogging of sprinklers. All this reduces the reliability of the device in question and the effectiveness of the fight against dust and gas and dust explosions from frictional heating of the cutters and cutting furrows in destructible rock.

 The closest in technical essence is a device for supplying irrigation fluid to the cutter of a mining machine [2], including a tool holder with a longitudinal channel mounted on the body of the executive body, mounted in the longitudinal channel of the tool holder with the possibility of rotation and limited axial movement of the tool with a cylindrical holder formed by the walls of the longitudinal channel in the tool holder and the outer side surface of the holder an annular channel for the passage of irrigation fluid, placed in the annular groove e on the tail part of the holder a locking element for fixing the cutter in the longitudinal channel of the tool holder, a locking device with a support ring located in the annular groove on the tail part of the tool holder and with an elastic sealing element that is installed to interact with the support ring, and a channel located in the body of the actuator for supplying irrigation fluid.

 The disadvantage of this device is the low efficiency of its operation due to the inability to maintain a constant flow rate of the irrigation fluid supplied to the bottom when its pressure in the supply channels changes, as well as in case of fluid leaks at the welded joints of the toolholders with the body of the executive body during operation. In addition, this device has low reliability due to the complexity of structural solutions, since the device has a sleeve with an annular groove at its end to accommodate a sealing element that interacts with the ring connected to the holder by means of an elastic element.

 A positive effect of the invention is achieved in that, taking into account the above-described general features of the device closest in technical essence, the longitudinal channel in the tool holder is made through, and the body of the executive body is made with a supporting surface, which forms a working chamber with the walls of the longitudinal channel in the tool holder, the device is made with installed in the working chamber with the possibility of limited axial movement and interaction with its supporting surfaces, respectively with the end surface of the holder and with the supporting surface of the body of the executive body of the liner with V-shaped channels located symmetrically relative to its longitudinal axis, with an annular groove located on its outer surface and with bevels located on its supporting surface facing the end surface of the holder, each of which is located in a plane perpendicular to the longitudinal axis of the corresponding V-shaped channel in the liner, and with an elastic element placed in the annular groove of the liner, which The second one is installed with the possibility of interaction with one of its ends with the supporting surface of the body of the actuator, and the sealing element is located in the annular groove on the tail of the holder and installed with the possibility of interaction with the side of the working part of the cutter side wall of the annular groove on the tail of the holder and with the walls of the longitudinal channel in the tool holder, and the locking element is rigidly connected to the tool holder and installed with the possibility of interaction with the support ring and which is directed toward the end surface of the holder by the side wall of the annular groove on the tail of the holder, and the channel for supplying irrigation fluid through the V-shaped channels in the insert is in communication with the cavity, which is formed by the walls of the longitudinal channel in the tool holder, the surface of the bevels on the insert, the tail of the holder and the sealing an element. In addition, the supporting surface of the liner facing the supporting surface of the housing of the actuator is flat, and the supporting surface of the liner facing the end surface of the holder is convex. The locking element is made in the form of two U-shaped rods, and the connection of the locking element with the tool holder is made in the form of two transverse channels in the tool holder, the longitudinal axes of which are located symmetrically with respect to the longitudinal axis of symmetry of the longitudinal channel in the tool holder, with each rod placed in the corresponding transverse channel of the tool holder .

 In FIG. 1 shows a diagram of the device during the interaction of the cutter with destructible massif (position "Open"); in FIG. 2 - diagram of the locking device in the absence of interaction of the cutter with the array (position "Closed"); in FIG. 3 is a section AA in FIG. 1 (fixation scheme of the cutter in the tool holder); in FIG. 4 - insert (enlarged); in FIG. 5 - same, top view.

 A device for supplying irrigation fluid to the cutter of a mining machine comprises a tool holder 2 with a longitudinal channel 3 mounted on the housing 1 of the actuator, mounted in the longitudinal channel of the tool holder with the possibility of rotation and limited axial movement of the tool 4 with a cylindrical holder 5, formed by the walls of the longitudinal channel in the tool holder and the outer the lateral surface of the holder an annular channel 6 for the passage of irrigation fluid, placed in the annular groove 7 on the tail portion 8 of the holder retaining element 8 for fixing the cutter in the longitudinal channel of the tool holder, the locking device 10 with a support ring 11 located in the annular groove on the tail of the holder and with an elastic sealing element 12, which is installed with the possibility of interaction with the support ring, and a channel 13 for supplying irrigation fluid. The longitudinal channel in the tool holder is made through, and the body of the executive body is made with a supporting surface 14, which forms a working chamber 15 with the walls of the longitudinal channel in the tool holder, while the locking device 16 is made with a liner 17 installed in the working chamber with the possibility of limited axial movement and interaction with supporting surfaces 18 and 19, respectively, with the end surface 20 of the holder and with the supporting surface 14 of the housing of the Executive body. The insert 17 is made with V-shaped channels 21 arranged symmetrically with respect to its longitudinal axis, with an annular groove 23 located on its outer surface 22 and with bevels 5 located on its supporting surface 18 facing the end surface 20, each of which is located in a plane perpendicular to the longitudinal axis of the corresponding V-shaped channel in the liner. In the annular groove 23 of the liner is placed an elastic element 25, which is installed with the possibility of interaction with one of its ends with the supporting surface 14 of the housing 1 of the Executive body. The sealing element 12 is located in the annular groove on the tail of the tool holder and is mounted to interact with the side wall 26 of the annular groove 7 on the tail of the tool facing the working part of the cutter and with the walls of the longitudinal channel 3 in the tool holder. The locking element 9 is rigidly connected to the tool holder 2 and installed with the possibility of interaction with the support ring 11 and facing the end surface 20 of the holder 5 by the side wall 27 of the annular groove 7 on the tail of the holder. The channel 13 for supplying irrigation fluid through the V-shaped channels 21 in the liner 17 is in communication with the cavity 28, which is formed by the walls of the longitudinal channel 3 in the tool holder, the surface of the bevels 24 on the liner 17, the tail portion 8 of the holder 5 and the sealing element 12. Facing the supporting surface 14 of the housing 1 of the Executive body, the supporting surface 19 of the liner 17 has a flat shape, and facing the end surface 20 of the holder 5, the supporting surface 18 of the liner has a convex shape. The locking element 9 is made in the form of two U-shaped rods 29 and 30, and the connection of the locking element with the tool holder is made in the form of two transverse channels 31 and 32 in the tool holder, the longitudinal axes bb and cc of which are located symmetrically with respect to the longitudinal axis of symmetry longitudinal channel 3 in the tool holder, with each rod placed in the corresponding transverse channel of the tool holder.

 A device for supplying irrigation fluid to the cutter of a mining machine operates as follows.

 Irrigating fluid is supplied from the pumping unit (not shown in the drawings) through channel 13 to V-shaped channels 21 and further to cavity 28. In the absence of interaction of the cutter with the rock, that is, in the absence of load on the cutter (Fig. 2), the liquid supplied under pressure together with the action of the elastic forces of the elastic element 25 acts on the end surface 20 of the cylindrical holder 5 and shifts the cutter forward. In this case, the support ring 11 and the elastic sealing element 12 located in the annular groove 7 of the holder 5 are displaced together with the cutter until the ring interacts with the locking element 9. Further forward movement of the cutter will occur as the elastic sealing element 12 compresses and interacts with the walls the longitudinal channel 3, depending on the pressure of the supplied fluid and the elastic force of the elastic element 25. The interaction of the elastic sealing element with the walls of the longitudinal channel will block the flow paths about oshayuschey fluid from the cavity 28 into the annular channel 6 and further into the cutting zone and breaking rock.

 When the cutter interacts with the rock, the cutter is fed back (Fig. 1, 2, 4) until the abutment surface 19 of the insert 17 abuts against the abutment surface 14 of the housing 1 of the actuator, while the elastic sealing element 12 is freed from the action of compression forces and opens up the outflow paths fluid from the cavity 28 to the annular channel 6 passing along the outer surface of the cylindrical holder 5 and the inner surface of the longitudinal channel 3. From the annular channel 6, irrigation fluid is supplied to the cutting and destruction zone of the rock, n GOVERNMENTAL while reducing dust formation and dust emission as well as the heating temperature of cutters and cutting furrows. When the fluid pressure in the irrigation system changes, the elastic sealing element 12 will compress with an increase in the pressure of the supplied fluid, i.e., the cross section of the element will take the form of an elongated ellipse, and expand - with a decrease in fluid pressure, i.e. take a more rounded (oval) form. As a result of this process, the gap between the walls of the longitudinal channel 3 and the elastic sealing element 12 will correspondingly decrease or increase, thereby maintaining the flow rate of the irrigating fluid within certain limits constant with small deviations from a given value. When removing the load on the cutter, the irrigation fluid supply to the cutting and rock destruction zone is stopped. Further, the processes of supplying and terminating the fluid will alternate depending on whether or not there is a load on the cutter, while the elastic element 25 prevents fluid leakage at the places of welded or other connections of the toolholders with the body of the executive body during operation.

 A device for supplying irrigation fluid to the cutter of a mining machine provides an increase in its efficiency by maintaining a constant flow rate of irrigation fluid supplied to the bottom when its pressure in the supply channels changes, since the elastic sealing element is located in the annular groove of the cylindrical tool holder and is installed with the possibility of changing the shape of the transverse sections in the process of fluid supply, and the elastic element placed in the annular groove of the liner accelerates the return of the cutter to the closed position then "and prevents fluid leakage at the junction of the toolholders with the body of the executive body during the operation of mining machines. In addition, the device increases reliability in operation by simplifying the design and mitigating shock loads at the moment of contact of the cutter with the rock. (56) 1. USSR patent N 1269744, cl. E 21 C 25/38, 1984.

 2. USSR author's certificate N 1686156, cl. E 21 C 25/38, 1991.

Claims (3)

 1. DEVICE FOR SUBMITTING IRRIGATING LIQUID TO THE MINING MACHINE CUTTER, including a tool holder with a longitudinal channel mounted on the body of the actuator, mounted in the longitudinal channel of the tool holder with the possibility of rotation and limited axial movement of the tool with a cylindrical holder formed by the walls of the longitudinal channel in the tool holder and the outer side surface holders an annular channel for the passage of irrigation fluid, placed in the annular groove on the tail of the holder retaining element for fixing the cutter in the longitudinal channel of the tool holder, a locking device with a support ring located in the annular groove on the tail of the holder and with an elastic sealing element that is installed to interact with the support ring, and a channel for supplying irrigation fluid located in the housing of the actuator, characterized in that the longitudinal channel in the tool holder is made through, and the body of the executive body is made with a supporting surface that forms with the walls of the longitudinal channel in the tool holder, the working chamber, while the locking device is made installed in the working chamber with the possibility of limited axial movement and interaction of its supporting surfaces, respectively, with the end surface of the holder and the supporting surface of the body of the actuator insert with V-channels arranged symmetrically relative to its longitudinal axis, with located on its outer surface of the annular groove and with located on its supporting surface facing the end the surface of the holder, with bevels, each of which is located in a plane perpendicular to the longitudinal axis of the corresponding V-shaped channel in the insert, and with an elastic element located in the annular groove of the insert, which is installed with the possibility of interaction with one end face of the supporting surface of the body of the actuator, and the sealing the element is located in the annular groove on the tail of the holder and is installed with the possibility of interaction with the side wall of the annular points on the tail of the holder and with the walls of the longitudinal channel in the tool holder, and the locking element is rigidly connected to the tool holder and installed to interact with the support ring and with the side wall of the annular groove facing the end surface of the holder on the tail of the tool holder, and the channel for supplying irrigation fluid through the V-shaped channels in the liner communicates with the cavity, which is formed by the walls of the longitudinal channel in the tool holder, the surface of the bevels on the liner, the tail part Application and the sealing element.  2. The device according to claim 1, characterized in that the supporting surface of the liner facing the supporting surface of the housing of the actuator is flat, and the supporting surface of the liner facing the end surface of the holder is convex.  3. The device according to claim 1, characterized in that the locking element is made in the form of two U-shaped rods, and the connection of the locking element with the tool holder is made in the form of two transverse channels in the tool holder, the longitudinal axes of which are located symmetrically with respect to the longitudinal axis of symmetry of the longitudinal channel in tool holder, with each rod is placed in the corresponding transverse channel of the tool holder.

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