RU2713043C1 - Pneumatic impact mechanism - Google Patents

Abstract

FIELD: soil or rock drilling.

SUBSTANCE: invention relates to mining and construction – to drilling equipment, is used for drilling wells by the rotary-shock method. Pneumatic impact mechanism comprises a housing with a drill bit, in which a piston is located, forming a working and idle stroke chamber with its walls, adapter for connection with pressure main line of energy carrier, having central channel and overlapping therein, made integral with adapter and separating its central channel to rear part, interconnected with side channels in adapter wall, and front part communicated with holes in annular groove bottom made along adapter outer lateral surface, in which is installed with pre-tension elastic valve in the form of toroid, forming with housing and adapter above-valve cavity, interconnected with pressure main through said side channels in wall adapter, and rear part of its central channel, and with housing walls – channel for energy carrier inlet into working stroke chamber, wherein said elastic valve is installed with possibility of periodic opening of energy carrier inlet channel from above above-valve cavity into idle stroke chamber, which includes holes in bottom of said annular groove of adapter, front part of its central channel and axial channel of slide valve rod, directly connected with central channel of piston. Slide rod is installed in bore of adapter made at its front end face in front part of its central channel, and is fixed in adapter by cylindrical rod installed in through hole made from side surface of adapter and aligned with through hole made in slide valve rod.

EFFECT: simplified design, reduced losses of energy carrier head at filling of idle stroke chamber, increased operational reliability.

3 cl, 1 dwg

Description

The technical solution relates to mining and construction, namely to drilling equipment, and can find application in drilling wells by impact-rotational method.

Known pneumatic shock mechanism according to the patent of the Russian Federation No. 2581652, class. ЕВВ 4/14, publ. in bull. No. 11, 2016, containing a housing in which a piston is located, forming with its walls a working and idle chamber, an adapter made with a central channel and with side channels in its wall, and an annular groove is made on the outer surface of the adapter, in which an elastic valve in the form of a torus is installed with a preload, forming with the body and the adapter a valvular cavity, and with the walls of the body - a channel for the energy carrier to enter the working chamber, while closing the shutter in the central channel Lena-valve stem having an axial channel and the sleeve with the main channel and holes, which main channel communicates with supravalvular cavity through said lateral passages in the wall of the adapter. The sleeve is made with a bottom, which is blocked by its main channel, and in the adapter, in the zone of the internal supporting surface of the specified valve in the annular groove, holes are made for periodic communication of the supravalvular cavity through the central channel of the adapter with the axial channel of the spool.

Common features of the analogue and the proposed technical solution are: a housing in which the piston is located, forming with its walls the working and idling chambers, an adapter made with a central channel and side channels in its wall, and an annular groove is made on the outer surface of the adapter, in which an elastic valve in the form of a torus is installed with a preload, forming a valvular cavity with a body and an adapter, and with a body wall a channel for the energy carrier to enter the working chamber yes, at the same time, a spool-rod with an axial channel is fixed in the central channel of the adapter, and holes are made in the annular groove of the adapter in the area of the inner supporting surface of the specified valve for periodic communication of the supravalve cavity with the axial channel of the spool-rod through the central channel of the adapter, in which the bottom is formed blocking the central channel of the adapter.

The main disadvantage of this mechanism is the complexity of the design of the energy supply to the idle chamber 4 from the axial channel 14 of the spool 13, which is made not with a through axial channel, but with a plug 23. Therefore, for the energy carrier to enter the idle chamber 4 in the rod wall, the spool 13 is made of radial channels 22, and in the piston 2, the bore 25, which causes significant pressure losses of the energy carrier, reducing the efficiency of the mechanism. In addition, the bore 25 in the piston 2 reduces its strength under shock loads, which reduces its operational reliability, and hence the efficiency.

Another disadvantage of this mechanism is that the bottom 18, overlapping the Central channel 7 of the adapter 5, is made in one piece with the sleeve 15, and the rod-valve 13 is fixed in the adapter 5 by means of the locking ring 20, which significantly complicates the design of the mechanism, creating inconvenience to it assembly and disassembly, reducing the effectiveness of the mechanism.

A significant drawback of this mechanism is that in the blocking mode of operation, the entire energy source enters only into the chamber 3 of the working stroke through the radial channels 22 of the spool 13, which open into the chamber 3 of the working stroke when the piston 2 is moved forward together with the tool 29. from the chamber 3 of the working stroke, the energy carrier is removed into the annulus of the well through the exhaust windows 28, and the energy carrier is not supplied to the purge channel 30 of the tool 29 to clean the bottom and cool the drill bit, which reduces atatsionnuyu mechanism reliability and its efficiency.

 The closest in technical essence and the totality of essential features to the proposed technical solution is a pneumatic shock mechanism according to the patent of the Russian Federation No. 2652518, class. E21B 4/14, publ. in bull. No. 12, 2018, containing a housing in which the piston is located, forming with its walls the working and idle chambers, an adapter for connecting to the pressure line, having central and side channels in its wall, and an annular groove with holes is made on the outer surface of the adapter in its bottom, in which a preload is installed, an elastic valve in the form of a torus, forming with the body and the adapter a valve valve cavity in communication with the pressure line through the side channels and the central channel of the adapter and with the walls of the casing there is a channel for the energy carrier to enter the working chamber, the valve being installed with the possibility of periodically opening the path for the energy carrier to enter the idle chamber, which includes holes in the bottom of the annular groove of the adapter, its central channel, axial and radial channels a spool rod installed in the central channels of the adapter and piston, a drill bit with a purge channel and an overlap formed in the central channel of the adapter and separating the adapter from the central channel to the rear with side channels and the front with holes in the bottom of its annular groove. The overlap is made in one piece with the adapter, in the front part of which a bore is made, communicating the holes in the bottom of the annular groove of the adapter with the axial channel of the slide valve through radial grooves made in the wall of the slide valve, which is installed between the overlap and the drill bit with the possibility of axial movement together with the drill bit.

Common features of the prototype and the proposed technical solution are: a housing with a drill bit, in which a piston with a central channel is located, forming with its walls a working and idle chamber, an adapter for connecting to a pressure line, having a central channel and an overlap in it, made in one integral with the adapter and the central channel dividing it into the rear part in communication with the side channels in the wall of the adapter and the front part in communication with the holes in the bottom of the annular groove made according to the outer side surface of the adapter, in which a pre-tensioned elastic valve in the form of a torus is installed, forming with the body and the adapter a valve valve cavity in communication with the pressure line through these lateral channels in the wall of the adapter and the back of its central channel, and with the body walls - a channel for the energy carrier inlet to the working chamber, wherein said elastic valve is installed with the possibility of periodically opening the path for the energy carrier inlet from said supravalve strip tee into the idle chamber, which includes holes in the bottom of said annular groove of the adapter, the front of its central channel and the axial channel of the spool rod installed in the adapter and in the central channel of the piston.

The main disadvantage of the prototype is that the path for the energy carrier to enter the idle chamber 4 from the axial channel 14 of the spool 16 is not directly connected to the central piston channel, but includes radial channels 15 in the spool 16, a bore 21 in the piston 2 and longitudinal channels 25 in the slide valve 16. This design complicates the design of the mechanism, causing significant pressure losses of the energy carrier when filling the idle chamber 4, which reduces the efficiency of the mechanism. In addition, the bore 21 in the piston 2 reduces its strength under shock loads, which reduces the operational reliability of the mechanism.

Another disadvantage of the prototype is that during the stroke of the piston 2, the energy source does not enter the purge channel 19 of the drill bit 18 to clean the bottom and cool the drill bit 18, which increases the wear of the drill bit 18 and, as a result, reduces the efficiency of the mechanism.

The problem is to create a pneumatic impact mechanism with increased work efficiency, which is solved by simplifying the design, reducing the pressure loss of the energy carrier when filling the idling chamber and increasing operational reliability.

The problem is solved in that in a pneumatic impact mechanism containing a housing with a drill bit, in which a piston is located, forming with its walls the working and idle chambers, an adapter for connecting to the pressure carrier of the energy carrier, having a central channel and an overlap in it, made in one integral with the adapter and the central channel dividing it into the rear part in communication with the side channels in the wall of the adapter and the front part in communication with the holes in the bottom of the annular groove made on the outer the side surface of the adapter, in which a torus-shaped elastic valve is installed with a preload, forming a valve body with the body and the adapter, connected to the pressure line through the said side channels in the wall of the adapter and the back of its central channel, and with the body walls - the inlet channel the energy carrier into the chamber of the stroke, while the specified elastic valve is installed with the possibility of periodically opening the path for the intake of energy from the specified nadklapanny cavity in the chamber idle, which includes holes in the bottom of the said annular groove of the adapter, the front of its central channel and the axial channel of the spool rod installed in the adapter and in the central piston channel, according to the technical solution, the spool rod is installed in the adapter bore made from its front end in the front of its Central channel, and the axial channel of the spool rod is directly in communication with the Central channel of the piston, while the spool rod is fixed in the adapter with a cylindrical rod, set nnym in a through hole formed to the side surface of the adapter and the combined with the through hole formed in the rod-spool.

The specified set of features allows, in comparison with the prototype, to increase the efficiency of the mechanism by communicating the axial channel of the spool rod directly with the central channel of the piston, which reduces the pressure loss of the energy carrier when filling the idling chamber, while increasing the strength of the piston due to its simplification by eliminating there are bores in it. This design increases reliability, which, as a result, increases the efficiency of the mechanism.

It is advisable to perform the specified cylindrical rod with a groove located in the axial channel of the spool rod, which increases the bore in this axial channel for the energy carrier to enter the idle chamber directly through the central piston channel. This design increases the efficiency of the mechanism.

It is advisable in the specified overlap of the adapter to make a calibrated hole that communicates the rear of the Central channel of the adapter with its front. This design provides continuous blowing of the face through the central channel of the drill bit, which increases the operational reliability of the mechanism.

The essence of the technical solution is illustrated by an example of a design of a pneumatic impact mechanism and a drawing, which shows a General view of this mechanism in longitudinal section in a static state.

The pneumatic impact mechanism (hereinafter referred to as the mechanism) comprises a housing 1 with a drill bit 2, in which a piston 3 is located, forming a working chamber 4 and an idle chamber 5 with its walls, an adapter 6 for connecting to a pressure carrier of an energy carrier, having a central channel and an overlap 7 in it, made in one piece with the adapter 6 and dividing its Central channel to the rear part 8, communicated with the side channels 9 in the wall of the adapter 6, and the front part 10, communicated with holes 11 in the bottom of the annular groove 12, is made which is threaded along the outer side surface of the adapter 6, in which the elastic valve 13 in the form of a torus (hereinafter referred to as the valve 13) is installed with a preload, forming with the body 1 and adapter 6 an overvalve cavity 14 in communication with the pressure line of the energy carrier through the indicated side channels 9 and the rear part 8 of its central channel, and with the walls of the housing 1 - channel 15 for the energy carrier inlet into the working chamber 4, while the valve 13 is installed with the possibility of periodically opening the path for the energy carrier inlet from the supravalve 14 into the idle chamber 5, which includes holes 11 in the bottom of the annular groove 12 of the adapter 6, the front part 10 of its central channel and the axial channel 16 of the spool rod 17, mounted in the bore 18, made from the front end of the adapter 6 in the front part 10 its central channel, and the axial channel 16 of the spool 17 is directly connected to the central channel 19 of the piston 3. In this case, the spool 17 is fixed in the adapter 6 with a cylindrical rod 20 installed in the through hole 21 made from the side surface of the adapter 6 and fitted with a through hole 22 made in the spool 17. In this case, the end of the spool 17 mounted in the bore 18 is made with an increased wall thickness, and radial holes 23 are made in the front of the spool 17. channel 24. To limit its progress in the blocking mode, a key 25 is installed in the housing 1 and locking channels 26 are made. For the exhaust of the spent energy from the working chamber 4, the exhaust windows 27 are made in the housing 1, and the exhaust for exhaust from the idle chamber 5 window windows 28.

It is advisable to make a cylindrical rod 20 with a groove 29 located in the axial channel 16 of the spool 17.

It is advisable in the overlap 7 of the adapter 6 to make a calibrated hole 30, communicating the rear part 8 of the Central channel of the adapter 6 with its front part 10.

The mechanism works as follows. At any initial position in the static state of the piston 3, the valve 13 is compressed with preload in the annular groove 12 of the adapter 6 and the inner supporting surface closes the holes 11. In this case, the valve 13 formed an inlet channel 15 with its outer surface with the walls of the housing 1 energy carrier from the supravalvular cavity 14 to the chamber 4 of the working stroke. When the mechanism is turned on, the energy carrier from the pressure line through the back part 8 of the central channel and the side channels 9 of the adapter 6 enters the supravalve cavity 14. From the supravalve cavity 14, the energy carrier passes through the channel 15 into the working chamber 4. Under the action of the energy carrier, the piston 3 from any initial position moves to its extreme forward position and opens the exhaust windows 27. The energy carrier from the working chamber 4 is removed into the annulus of the well and the pressure of the energy carrier in the channel 15 is reduced. Under the action of the energy carrier from the side of the supravalvular cavity 14, the valve 13 is stretched, blocking the channel 15, and opens its holes on the inner supporting surface 11 in the annular groove 12 of the adapter 6, which communicate the supravalve cavity 14 with the front part 10 of the central channel separated by the overlap 7 from the rear part 8 the central channel of the adapter 6. Further, in contrast to the prototype, the energy carrier passes directly through the axial channel 16 of the spool rod 17 into the central channel 19 of the piston 3 and into the idle chamber 5. The idle stroke of the piston 3 begins. In this case, compared to the prototype, the design of the piston 3 is simplified by eliminating the bore in it, which increases the strength of the piston 3. Performing a spool 17 with an axial channel 16 directly connected to the central channel 19 of the piston 3, it became possible due to the fact that the spool 17 is installed in the bore 18 of the adapter 6, made from its front end in the front part 10 of its Central channel, while the spool 17 is fixed in the adapter 6 with a cylindrical rod 20 mounted in a through hole ii 21, taken from the side surface of the adapter 6 and a through hole 22 formed in rod-spool 17. This design simplifies the construction of the mechanism, increases reliability, which increases its efficiency. It is advisable to make a cylindrical rod 20 with a groove 29 located in the axial channel 16 of the spool 17, which increases the flow area for supplying energy from the axial channel 16 to the idle chamber 5 directly through the central channel 19 of the piston 3. This design improves the efficiency mechanism. When filling the idle chamber 5 with the energy carrier, the piston 3 is idled, which opens the exhaust windows 28 to remove the spent energy carrier from the idle chamber 5 into the annulus of the well. When the piston 3 is idle, an increased pressure buffer cushion is formed in the working chamber 4, and in the axial channel 16 of the spool 17 and in the holes 11, the energy pressure drops due to the discharge of the idling chamber 5. Under the action of the energy carrier entering the supravalve cavity 14, the valve 13 is compressed, closes the holes 11 and the energy carrier inlet to the idle chamber 5 is stopped, while the energy carrier is opened into the chamber 4 of the stroke through channel 15. The piston 3 stops and the stroke begins, in which the piston 3 opens the exhaust windows 27 to remove the spent energy from the chamber 4 of the stroke. In this case, the pressure of the energy carrier in the channel 15 is reduced. Under the action of the energy carrier entering the supravalvular cavity 14, the valve 13 is stretched, blocking the inlet channel 15 for the energy carrier to enter the working chamber 4, and opens the holes 11 for the energy carrier to enter the idle chamber 5. The piston 3 hits the drill bit 2, after which the cycles are repeated. The drill bit 2 destroys the bottom of the well, and the products of destruction are removed by the energy coming through the channel 24 into the annulus of the well.

It is advisable in this overlap 7 to make a calibrated hole 30, communicating the rear part 8 of the central channel of the adapter 6 with its front part 10, which improves the cleaning of the bottom of the well due to the constant supply of energy through the axial channel 16 of the spool 17 and the central channel 19 of the piston 3 into the channel 24 drill bit 2. This design improves the efficiency of the mechanism. In the locking mode, when lifting the mechanism from the bottom, the drill bit 2 is shifted all the way to the key 25, while the locking channels 26 are opened in the housing 1 to discharge the idle chamber 5, and the piston 3 is also moved forward to the stop in the housing 1, while the radial openings 23 of the slide valve 17 and the working chamber 4 are in communication with the idle chamber 5. The energy pressure in these chambers 4, 5 is equalized and the mechanism is turned off.

Claims (3)

1. Pneumatic impact mechanism comprising a housing with a drill bit, in which a piston is located, forming with its walls the working and idle chambers, an adapter for connecting to the pressure carrier of the energy carrier, having a central channel and an overlap in it, made in one piece with the adapter and the central channel dividing it into the rear part in communication with the side channels in the adapter wall and the front part in communication with the holes in the bottom of the annular groove made along the outer side surface of the transition a receiver in which a torus-shaped elastic valve is installed with a preload, forming with the body and adapter a valve valve cavity in communication with the pressure line through the indicated side channels in the wall of the adapter and the back of its central channel, and with the body walls - a channel for energy carrier inlet a working chamber, while the specified elastic valve is installed with the possibility of periodically opening the path for the intake of energy from the specified nadklapanny cavity into the idle chamber, which includes holes in the bottom of said annular groove of the adapter, the front part of its central channel and the axial channel of the spool rod installed in the adapter and in the central channel of the piston, characterized in that the spool rod is installed in the adapter bore made from its front end in front its central channel, and the axial channel of the spool rod is directly in communication with the central channel of the piston, while the spool rod is fixed in the adapter by a cylindrical rod installed in the through hole, om the side surface of the adapter and the combined with the through hole formed in the rod-spool. 2. The pneumatic impact mechanism according to claim 1, characterized in that said cylindrical rod is made with a groove located in the axial channel of the spool rod. 3. The pneumatic percussion mechanism according to claim 1, characterized in that a calibrated hole is made in the specified adapter overlap, communicating the rear of the central channel of the adapter with its front.

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