RU2003796C1 - Gear to feed spraying fluid to cutting tool of mining machine - Google Patents

Abstract

SUMMARY OF THE INVENTION A device for supplying irrigation fluid to a cutter of a mining machine comprises a tool holder, a cutter with a rectangular holder and with a support protrusion, a locking element for fixing the cutter, a channel for passing the irrigating liquid, a sealing element, a locking device with elastic elements and a protective washer. The housing is made up of a body made with a supporting surface, which forms a working chamber with the walls of the channel in the tool holder for receiving the locking device. The locking device is made in the form of a normally closed valve with locking elements, with a seat in the form of an intermediate washer and with guiding elements. The locking elgmei contains a central socket, a curved protrusion on its tail portion. The protective washer is made with radial grooves located on its end and is installed in the working chamber between the end holder and the locking element of the valve. The elastic elements are installed between the protective washer and the intermediate washer. 9 zlfs, 9 ill.

Description

The invention relates to the mining industry, mainly to the coal industry, and can be used to combat dust and its explosions from frictional heating of cutters and cutting grooves during the operation of mining machines in treatment and tunneling workings.

A device for supplying irrigation fluid to the cutter of a mining machine 1 is known, which can be used to control dust and explosion protection during operation of mining machines, including a tool holder attached to an executive body body with a hollow longitudinal channel of circular shape, a sleeve mounted in a longitudinal channel of the tool holder, mounted in the sleeve with the possibility of limited rotation and axial movement of the cutter with a cylindrical holder, a locking element for fixing the sleeve in the tool holder and the locking device is adapted a channel formed by the external lateral surface of the holder and the sleeve walls for the passage of irrigation fluid, sealing and elastic elements placed in the annular grooves of the sleeve and holder, a ring placed in the ring groove of the holder and mounted on the elastic element with the possibility of interaction with the bracket fixing the cutter and a channel for supplying irrigation fluid located in the housing of the actuator,

The disadvantages of this device are the design complexity and low reliability, since it has a sleeve with an annular groove at its end to accommodate the sealing element and an annular groove on its outer surface to accommodate the additional sealing element. The annular groove at the end face of the sleeve is made in the zone of increased load and abrasion when the cutter deviates from the longitudinal axis during contact of the cutter with destructible rock. Increased load and abrasion can lead to deformation of the annular groove and the sealing element located in it, while the ring placed in the holder’s annular groove and mounted on the elastic element when the cutter deviates from the longitudinal axis with an increase in the deformation of the annular groove at the end of the sleeve does not provide complete sealing and will lead to to leaks of irrigation fluid in the absence of load on the cutter. In addition, cutters with a cylindrical holder do not withstand the loads during the destruction of strong and especially strong rocks. When mining powerful seams, executive

shearer bodies are constructed using mixed types of cutters. Cutters with a cylindrical holder are installed in the cutting line, and from the side

Zabo - cutters with a rectangular holder, the latter withstand heavy loads and work under more severe conditions for gas and dust. From the side, gas and dust concentrations exceed the corresponding concentrations in the cutting line,

as this area is poorly ventilated and

probability of gas ignition and explosion

gas and dust under these conditions is higher.

The closest in technical essence is a device for supplying irrigation fluid to the cutter of a mining machine 2. comprising a tool holder fixed to the body of the actuator with a through longitudinal channel of a rectangular shape, mounted in the longitudinal channel of the tool holder with the possibility of limited axial movement of the tool with a rectangular holder and with supporting protrusion, which is installed with the possibility of interaction with the end surface of the tool holder, located in the recess on the holder retaining element nt for fixation in the tool holder, formed by the outer lateral surface of the holder and the walls of the longitudinal channel in the tool holder, the channel for the passage of irrigating fluid, a sealing element with an axial hole, a locking device with elastic elements,

a channel for supplying irrigation fluid and a protective washer located in the housing of the actuator.

The disadvantage of this device is

the reliability of its operation is low, due to the frequent clogging of irrigation nozzles or nozzles with mechanical impurities both from the inside and from the outside. To each sprinkler, the channel for supplying irrigation fluid, made in the tool holder, has at least two turns, which initiate the accumulation of mechanical impurities with the subsequent clogging of either the nozzle or the channel. Nozzle clogging

sprinklers impairs the cooling of cutters and cutting furrows, reduces the efficiency of dust explosion protection and dust suppression, as a result of which working conditions are worsened and the safety of miners in

sewage and preparatory workings. In addition, the channels for supplying fluid are made in the cutter, which weaken it and also reduce the reliability of the device.

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 housing of the actuator is made with a supporting surface, which forms with the walls of the longitudinal channel in the tool holder and with the end surface of the holder a working chamber for accommodating the locking device, and the locking the device is made in the form of a normally closed valve with a locking element containing a central socket, radial channels located at two sockets ala, the output of each of which is connected with the internal cavity of the socket, and a figured protrusion on its tail, with a seat in the form of an intermediate washer and with guide elements, while the valve locking element is installed with the possibility of limited axial movement along the guide elements for communication in one of the extreme positions of the valve of the inputs of the radial channels of the locking element with an axial hole in the sealing element and with the possibility of interaction with the other extreme position of the valve with its curly protrusion with an intermediate washer to block the inputs of the radial channels of the locking element, and the protective washer is made with radial grooves located at its end to communicate with the internal cavity of the socket in the valve locking element through an axial hole in the protective washer with a channel for the passage of irrigation fluid and is installed in the working chamber between the end of the holder and a locking element of the valve with the possibility of interaction with elastic elements, and the sealing element is placed in the working chamber between the supporting surface of the housing an additional body and the valve intermediate washer, and the elastic elements are installed between the protective washer and the intermediate washer in the cavity formed by the walls of the longitudinal channel in the tool holder and the valve guide elements, and the length of each elastic element along the longitudinal axis of the longitudinal channel in the tool holder exceeds the length of the valve guide elements along the same axis, while the channel for supplying irrigation fluid is in communication with the axial hole in the sealing element, and the holder is spring-loaded relative to the housing olnitelnogo body via the elastic member and the sealing member. In addition, the valve guide elements are made in the form of a cylindrical sleeve,

however, the valve has four elastic elements that are installed at the corners of the longitudinal channel in the tool holder with the possibility of interaction with the sleeve 5 to fix the latter relative to the longitudinal axis of the longitudinal channel in the tool holder, and the valve shut-off element has a circle shape in cross section. The valve guides are made in the form of two containers of a rectangular shape, and the valve has two elastic elements, each of which is installed in the inner cavity of the corresponding container, while the base of the shut-off element

5 of the valve has a cross-sectional shape in the form of a square, and the figured protrusion on the locking element of the valve has a cross-sectional shape in the form of a circle, the containers being arranged in cross-section

0 greater length to the sides of the longitudinal channel in the tool holder. At least two radial channels are made in the locking element of the valve. The protective washer is made with at least two radial

5 grooves. The base of the valve locking element is made of metal, and the figured protrusion on the valve locking element is made of elastic rubber. The hole in the intermediate washer is made with

0 laid from the base side of the locking element with a rounded chamfer. The stop element is made in the form of a bolt located on the threaded section of the bolt of the nut and rubber sealing elements, and

5, the tool holder is made with a transverse channel for accommodating a bolt, the internal cavity of which is sealed by means of rubber sealing elements, and with located at the inlet and outlet

0 of the transverse channel with recesses to accommodate, respectively, the head of the bolt and nut, the depth of which is not less than the thickness of the head of the bolt and nut, while the cutter is mounted with the possibility of interaction of its recessed wall facing the working head on the holder to accommodate the locking element with the body of the bolt, on the holder to accommodate the locking element and

0, the support protrusion on the holder is located on one face of the holder, the longitudinal axis of symmetry of the recess on the holder to place the locking element is parallel to the longitudinal axis of the transverse channel in the tool holder, and the distance between the bolt body and the recess wall on the holder with the maximum exit of the cutter from the longitudinal channel in the tool holder along the longitudinal axis of the longitudinal channel in the tool holder exceeds the distance between

supporting protrusion on the cutter and the end surface of the tool holder at the maximum exit of the tool from the longitudinal channel in the tool holder on the same axis. The recess in the holder for receiving the locking element has a rectangular cross-sectional shape, while the adjacent walls of the recess in the holder are interfaced along a cylindrical surface. The radius of the cylindrical surface is equal to the radius of the body of the bolt.

In Fig, 1 shows a diagram of a device in the absence of interaction of the cutter with destructible rock; in FIG. 2 is a diagram of a locking device in the absence of interaction of the cutter with the rock (closed position, node A enlarged); Fig. 3 is a diagram of a locking device with a load on the cutter, i.e. when the cutter interacts with the rock (open position); in FIG. A - section bB in figure 2; 5 is a diagram of a locking device in the absence of interaction of the cutter with the rock (closed position, node A is enlarged); in FIG. 6 is a diagram of a locking device under load on the cutter (open position); in FIG. 7 is a section BB in FIG. 5; in FIG. 8 is a section GG in FIG. 1; Fig. 9 shows a recess in a holder for receiving a locking element and a diagram for coupling the walls of the recess with the body of the locking element (bolt).

A device for supplying irrigation fluid to a cutter of a mining machine comprises a tool holder 2 mounted on a housing 1 (Fig. 1-9) of the actuator with a through longitudinal channel 3 of a rectangular shape, mounted in a longitudinal channel of the tool holder with the possibility of limited axial movement of the tool 4 with a rectangular holder An encore with a supporting protrusion 6, which is mounted to interact with the end surface 7 of the tool holder, is located in the recess 8 on the holder retaining element 9 for fixing the tool in the tool holder, formed by the outer lateral surface 10 of the holder and the walls 11 of the longitudinal channel in the tool holder, the channel 12 for the passage of irrigating fluid, a sealing element 13 with an axial hole 14, a locking device 15 with elastic elements 16 (Fig. 4-7) located in the body of the actuator channel 17 for supplying irrigation fluid and a protective washer 18, characterized in that the housing of the actuator is made with a supporting surface 19, which forms with the walls 11

a longitudinal channel in the tool holder and with the end surface 20 of the holder, the working chamber 21 for receiving the locking device 22, and the locking device (Fig. 2-4, 5-7) is made in the form of a normally closed valve 23 with a locking element 24 containing a central socket 25, radial channels 27 located at the bottom of the slot 26, the output of each of

0 of which are in communication with the internal cavity 28 of the nest, and a figured protrusion 29 on its tail, with a saddle 30 in the form of an intermediate washer 31 and with guide elements 32 or 33, while the locking

5, the valve element 24 is mounted with the possibility of limited axial movement along the guide elements for communication in one of the extreme positions of the inputs of the radial channels 27 of the locking element

0 with an axial hole 14 in the sealing element 13 and with the possibility of interaction with the other extreme position of the valve with its curly protrusion 29 with an intermediate washer 31 for closing

5 inputs of the radial channels of the locking element, and the protective washer 18 is made with radial grooves 34 located on its end facing the end surface 20 of the holder for communicating the internal cavity 28 of the valve in the locking element through an axial hole 35 in the protective washer with the channel 12 for the passage of the irrigation fluid and is installed in the working chamber 21 between the end face of the holder and the locking element of the valve with the possibility of interaction with the elastic elements 16, and the sealing element 13 is placed in the working chamber between the supports surface 19 of the housing 1 executive

0 body and the intermediate washer 31 of the valve, and the elastic elements 16 are installed between the protective washer 18 and the intermediate washer 31 in the cavity formed by the walls of the longitudinal channel in the tool holder and

5 by the guiding elements of the valve, and the length of each elastic element along the longitudinal axis 0-0 of the longitudinal channel in the tool holder exceeds the length of the guiding elements of the valve along

On the same axis, with the channel 17 for supplying irrigation fluid in communication with the axial hole 14 in the sealing element, and the holder 5 is spring-loaded relative to the housing of the actuator using 5 elastic element 16 and the sealing element 13. The valve guide elements 32 are made in the form of a cylindrical bushings, while the valve has four elastic elements (Fig. 2-4), which are installed at the corners of the longitudinal channel in the tool holder with the possibility of interaction with the sleeve to fix the latter relative to the longitudinal axis of the longitudinal channel in the tool holder, and the locking element 24 of the valve is in cross section in the shape of a circle. The valve guide elements 33 are made in the form of two containers of rectangular shape, and the valve has two elastic elements, each of which is installed in the internal cavity of the corresponding container (Fig. 5-7), while the base 36 of the valve shutter element has a cross-sectional shape square, and the figured protrusion 29 on the locking element of the valve has a cross-sectional shape in the form of a circle, and the containers are located on the sides of the longitudinal channel in the tool holder having a large cross-section. In the locking element 24 of the valve is made of at least two radial channels. The protective washer 18 is made with at least two radial grooves. The base 36 of the valve locking element is made of metal, and the figured protrusion 29 on the valve locking element is made of elastic rubber. The hole 37 in the intermediate washer 31 is made with a rounded chamfer 38 located on the base side of the locking element. The locking element 9 (Fig. 8) is made in the form of a bolt 39 located on the threaded section of the bolt of the nut 40 and rubber sealing elements 41 and 42, and the tool holder 2 is made with a transverse channel 43 for accommodating a bolt, the inner cavity of which is sealed with rubber sealing elements and with recesses 44 and 45 located at the inlet and outlet of the transverse channel to accommodate the heads, respectively and 46 bolts and nuts 40, the depth of which is not less than the thickness of the head of the bolt and nut, while the cutter 4 is mounted so that its wall facing the working head 47 of the recess 8 is mounted on the holder to accommodate the locking element with the body of the bolt 39, and the recess 8 is the holder for accommodating the locking element and the abutment protrusion 6 on the holder are located on the same face of the holder, the longitudinal axis of symmetry of the in-recess in the holder for placing the locking element is parallel to the longitudinal axis o-o of the transverse channel Ala in the tool holder, and the distance And (Fig. 1.9) between the body of the bolt and the wall 48 of the recess on the holder with a maximum exit of the cutter from the longitudinal channel in the tool holder along the longitudinal axis o-o of the longitudinal channel 3 in the tool holder exceeds the distance

2 between the support protrusion b on the cutter and the end surface 7 of the tool holder at the maximum exit of the tool from the longitudinal channel in the tool holder along the same 5 axis. The recess 8 on the holder for accommodating the locking element has a rectangular cross-sectional shape, while the adjacent walls of the recess on the holder are interconnected along the cylinder surface 49. The radius n of the cylindrical surface 49 is equal to the radius radius G2 of the bolt body (Fig. . 9),

Device for supplying irrigation fluid to the cutter of a mining machine

5 as follows

Irrigation fluid is supplied from the pumping unit (not shown in the diagram) through channel 17 to node A (Fig. 1).

In the absence of interaction resc with

0 rock, i.e. in the absence of a load on the cutter (FIGS. 1, 2, 5), the liquid supplied under pressure enters the hole 14 of the sealing element 13 and with its pressure from the area of the figured protrusion

5 29 feeds the locking element 24 forward along the fluid in the direction of the protective washer 18 and the cutter 4. If there is no load on the cutter, the latter is in a spring-loaded state relative to

0 building 1 of the executive body for a. the elastic forces of the elastic elements 16 and the sealing element 13 and the presence of the locking element 9. Since the elastic elements 16 are installed between the protective

5 by a washer 18 and an intermediate washer 31 and the length of each elastic element along the longitudinal axis o-o of the longitudinal kakal 3 in the tool holder exceeds the length of the guide elements 32 or 33 along the same axis

0 and the locking device 22 is made in the form of a normally closed valve 23 with a locking element 24, then in the spring-loaded state of the cutter in the absence of interaction with the rock between

5, a clearance is maintained by the protective washer 18 against the locking element 24, allowing the figured protrusion 29 to be pressed firmly against the intermediate washer 31, as a result of which the flow paths of the irrigation fluid are blocked.

When the cutter interacts with destructible rock, i.e. when the load on the cutter (Fig. 3, 6), the latter moves towards the tool holder. Since the cutter is spring-loaded under 5, it shifts to the offset shield 18 at a distance of 2 (2 (Fig. 1), while the support protrusion 6 of the cutter 4 interacts with the end surface 7 of the tool holder, End & and the surface 20 of the holder 5 pushes the protective

the washer 18, and the washer is a locking element 24 of the valve. The locking element, sliding along the guide elements 32 or 33, frees the figured protrusion 29 from interacting with the intermediate washer 31, thereby opening the flow paths of the irrigation fluid from the opening 14 of the sealing element 13 and the channel 17 of the housing 1 of the actuator to the radial channels 27 and the cavity 28 the locking element 24 and then through the axial hole 35 and the radial grooves 34 of the protective washer 18 into the channel 12 for the irrigation fluid to pass into the dust formation zone and heat the cutter and the furrow of the cut.

When the load on the cutter is removed, the supply of irrigation fluid to the above zone is stopped, since the combined action of the elastic forces of the elastic element 16 and the sealing element 13 returns the protective washer 18 and the cutter 4 to the initial spring-loaded position (Figs. 1, 2, 5). and the liquid supplied with its pressure on the area of the figured protrusion 29 tightly presses it against the intermediate washer 31, blocking the path of its expiration. Further, the processes for supplying and stopping the irrigation fluid will alternate depending on whether or not there is a load on the cutter. Limited Reciprocal

the axial movement of the cutter and its rectangular holder allows you to grind mechanical impurities that got into the channel 12 for the passage of the irrigating fluid, and

irrigation fluid leaches abrasion products. The structural arrangement of the elastic elements and the sealing element alleviates shock loads at the moment of contact

cutter with rock and largely prevents the destruction of its cutting insert.

A device for supplying irrigation fluid to the cutter of a mining machine increases

reliability of its operation, since there are no sprinklers or nozzles, nozzles of which are often clogged by mechanical impurities from the inside and from the outside. Elimination of contamination by mechanical impurities will allow

to improve the cooling of cutters and cutting grooves, to increase the efficiency of dust explosion protection and dust suppression, which will lead to improved working conditions and increased safety of miners in sewage treatment plants

and preparatory workings.

(56) 1. USSR Copyright Certificate No. 1686156, cl. F 21 C 25/38, 1991.

2. UK patent No. 2186011, CL F21 C 35/18. 1987.

Claims (9)

The formula is invented. 1. DEVICE FOR SUBMITTING IRRIGATING LIQUID TO THE MINING MACHINE CUTTER, including a tool holder attached to the body of the executive body with a through longitudinal channel of a rectangular shape, mounted in a longitudinal channel of the tool holder with the possibility of limited axial movement of the tool with a rectangular holder and a supporting protrusion, which is installed with interacting with the end surface of the tool holder, a locking element for securing the tool in the tool holder, formed in the recess on the holder, is formed The outer side of the holder and the walls of the longitudinal channel in the tool holder, the channel for the passage of irrigation fluid, a sealing element with an axial hole, a locking device with elastic elements located in the body of the actuating body, the channel for supplying the irrigation fluid and a protective washer, characterized in that the housing of the executive body is made with supports surface that forms with the walls of the longitudinal channel in the tool holder and with the end surface of the holder the working chamber for placement of the locking device, and the locking device is made in the form of a normally closed valve with a locking element containing a central socket, radial channels located at the bottom of the socket, the output of each of which communicates with the internal cavity of the socket , and a figured protrusion on its tail part with a saddle in the form of an intermediate washer and guide elements, while the valve shut-off element is installed with the possibility of limited axial movement along the guide elements for communication in one of the extreme positions of the valve of the inputs of the radial channels of the locking element with an axial hole in the sealing element and with the possibility of interacting at the other extreme position of the valve with its figured protrusion with an intermediate washer to block the inputs of the radial channels of the locking element, and the protective washer is made with radial grooves located at its end to communicate the internal cavity of the socket in the valve locking element through an axial hole in the protective a washer with a channel for the passage of irrigation fluid and is installed in the working chamber between the end face of the holder and the locking element of the valve with the possibility of interaction twi with elastic elements, the sealing element being placed in the working chamber between the supporting surface of the body of the actuator and the intermediate valve washer, and the elastic elements are installed between the protective and intermediate washers in the cavity formed by the walls of the longitudinal channel in the tool holder and the valve guides, and the length of each the elastic element along the longitudinal axis of the longitudinal channel in the tool holder exceeds the length of the valve guide elements along the same axis, while the channel for supplying irrigation th fluid is in communication with the axial hole in the sealing element, and the holder is spring-loaded relative to the housing of the actuator using elastic and sealing elements. 2. The device according to claim 1. characterized in that the valve guide elements are made in the form of a cylindrical sleeve, wherein the valve has four elastic elements that are mounted at the corners of the longitudinal channel in the tool holder with the possibility of interaction with the sleeve to fix the latter relative to the longitudinal axis of the longitudinal channel in the tool holder, and the valve shut-off element has a circle shape in cross section, 3. The device according to claim 1, characterized in that the valve guide elements are made in the form of two containers of rectangular shape, and the valve has two elastic elements, each of which is installed in the internal cavity of the corresponding container, while the base of the valve shutoff element has the cross-section is square in shape, and the figured protrusion on the valve shut-off element is in cross-section in the shape of a circle, and the containers are located on the sides of the longitudinal channel in the tool holder having a large cross-section. 4. The device according to claim 1, characterized in that in the valve element 5 0 5 0 5 0 5 0 5 at least two radial channels are filled. 5. The device according to claim 1, characterized in that the protective washer is made with at least two radial grooves. 6. The device according to claim 1, characterized in that. that the base of the locking element of the valve is made of metal, and the figured protrusion on the locking element of the valve is made of elastic rubber. 7. The device according to claim 1, characterized in that the hole in the intermediate washer is made with a rounded chamfer located on the base side of the locking element. 8. The device according to claim 1, characterized in that the locking element is made in the form of a bolt located on the threaded section of the bolt of the nut and rubber sealing elements, and the tool holder is made with a transverse channel for accommodating the bolt, the inner cavity of which is sealed by rubber sealing elements , and with recesses located at the inlet and outlet of the transverse channel for the bolt and nut heads, respectively, the depth of which is not less than the thickness of the bolt and nut heads, and the cutter is set it is shown that it can interact with its recess wall facing the working head on the holder to accommodate the locking element with the body of the bolt, and the recess on the holder to accommodate the locking element and the support protrusion are located on the same face of the holder, and the longitudinal axis of symmetry of the recess on the holder to accommodate the locking element is located parallel to the longitudinal axis of the transverse channel in the tool holder, and the distance between the body of the bolt and the recess wall on the holder at the maximum exit of the cutter from the longitudinal channel in p The tool holder along the longitudinal axis of the longitudinal channel in the tool holder exceeds the distance between the support protrusion on the tool and the end surface of the tool holder at the maximum exit of the tool from the longitudinal channel in the tool holder along the same axis. 9. The device according to claim 1 or 8, characterized in that the recess in the holder for receiving the locking element has G 19I Ush Node A 23. (increased); yu l ff 20 3S (y & magnitude) m tf & n $ & m & J2 1 39 s u o o so -4 with about W-W U   I FIG. x 39 FIG. 9