SU1649090A2 - Submersible air hammer - Google Patents

Abstract

The invention relates to a drilling technique and allows to increase the operational reliability and simplify the design of a submersible pneumatic impact device. For this, the stepped drummer 10 is made with a through calibrated channel (QC) 18, which constantly communicates between itself the intermediate annular chamber (K) 15 of the network I pressure and K 4 of the working stroke inside the sleeve 2, the section of the impactor Yu

Description

The invention relates to a drilling technique and can be used to create pneumatic machines of both manual and non-manual percussion machines, for example, submersible pneumatic hammers,

The purpose of the invention is to increase the operational reliability and simplify the design.

FIG. Figure 1 shows an embodiment of a submersible pneumatic impact device with a calibrated inlet closed channel that continuously communicates between an intermediate pressure chamber and a working stroke chamber, which is made in the center of a hammer, interacting with the sleeve; in fig. 2 is a section A-A in FIG. one,; in fig. 3 - the same, with a calibrated inlet channel in the form of a groove, constantly interconnecting the intermediate chamber of the network pressure and the working stroke chamber, made on the side of the striker, interacting with the sleeve; FIG. 4 is a section BB in FIG. 3; in fig. 5 - the same, with a calibrated inlet channel in the form of a flathead, which constantly interconnects between the intermediate pressure chamber and the working stroke chamber, which is made on the side surface of the impactor interacting with the sleeve; in fig. 6 shows a section B-B in FIG. five; in fig. 7 - the same 9 with a calibrated inlet closed channel in the body of the striker, constantly communicating between them the intermediate chamber pressure chamber and the working stroke chamber, made in the portion of the striker with a smaller diameter, interacting with

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Q 5

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the sleeve, while the area of smaller diameter is made in the form of a plunger; in fig. 8 - section GG in FIG. 7; in fig. 9 - the same, with a calibrated inlet channel in the form of a groove, which constantly interconnects the intermediate chamber of the network pressure and the working stroke chamber made on the plunger section of the impactor, interacting with the sleeve; figure 10 is a cross section dd in fig. 9; in fig. 11 - the same, with a calibrated inlet channel in the form of a flathead, constantly interconnecting the intermediate chamber of the network pressure and the working stroke chamber, made on the plunger section of the impactor, interacting with the sleeve; in fig. 12 is a sectional view E — E of FIG. eleven; in fig. 13 - the same, with an inlet calibrated closed channel, constantly communicating among themselves the intermediate chamber of network pressure and the working stroke chamber, made on the plunger section of the impactor and with a screw intermittent undercut on its side surface interacting with the sleeve; FIG. 14 is a cross-section of the LC section in FIG. 13; in fig. 15 - the same, with a calibrated inlet channel in the form of a groove, constantly interconnecting the intermediate chamber of the network pressure and the working stroke chamber, made on the plunger section of the impactor and with a screw intermittent undercut on its side surface interacting with the sleeve; in fig. 16 is a cross section of And-And in FIG. 15; in fig. 17 - the same, with the inlet calibrated channel in the form of a flathead, which constantly interconnects between the intermediate chamber of the network pressure and the working stroke chamber,

on the plunger section of the striker and with screw intermittent undercuts on its side surface interacting with the sleeve; FIG. 18 is a section K — K of FIG. 17

The submersible pneumatic impact device comprises a barrel 1 with an internal cavity, a sleeve 2 with an inlet channel 3 on the outer lateral surface of the sleeve and controlled by a working stroke chamber 4 with a rod 5 inside the sleeve. On the opposite side of the sleeve, the barrel 1 is provided with an interchangeable shank 6 of a working tool with an exhaust channel 7 and an exhaust axial tube 8 with a channel H, which is a continuation of channel 7. The stepped drummer 10 is made with an annular neck 11, forming on the section of the drummer of a smaller diameter along the sap 12 (Fig. 1-6), or without it, with the same cross section in the form of a plunger 13 (Fig. 7-18) and a central through channel 14 with the possibility of periodic interaction with the rod 5 and the axial tube 8, Shock 10 to its stage with a large diameter is supported on a shaft 6 yn

The device is installed in the cavity of the controlled chamber 4 of the stroke of the liner 2. A shock drum 10 separates the internal cavity of the barrel 1 into the intermediate annular chamber 15 of the network pressure (it also functions as the stroke chamber) and the controlled chamber 16 of the idler. move. On the side surface of the large-diameter drummer stage there are made through calibrated grooves 17, which constantly connect chambers 15 and 16 to each other. In Figure 12 (Fig. 1, 2) and in the plunger section (Fig. 7, 8, 13, 14) of the striker, a through-through calibrated closed channel 18 is performed. The channel 18 is closed and ensures its local resistance and flow rate does not depend from the position of the impactor, and from the pressure drop in the chambers 15 and 4. This design ensures the reliability of filling the chamber 4 with air and stable operation of the device. As variants of through-calibrated channels, which constantly communicate t between themselves an intermediate chamber

15 mains pressure and chamber 4

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working stroke, on the side surface of ska 12, calibrated through channels are made in the form of a groove 19 (Fig. 3, 4) or flat face 20 (Fig. 5.6). This design ensures reliable cleaning of the calibrated sections of the groove 19 and flat 20, which maintains the constancy of their flow sections and consumption characteristics, the quality of filling of the chamber 4 with air, as well as the stability and reliability of the device

As versions of through-calibrated channels that constantly interconnect the intermediate pressure chamber 15 and the working stroke chamber 4, calibrated pass-through channels are made on the side surface of the plunger 13 in the form of a groove 19 (Fig. 9, 10 and 15, 16) or flashing 20 (Fig. 11, 12 and 17, 18). This design provides an increase in the cross section and strength of the impactor on its smaller diameter section due to the equally equal (cross) cross section of the impactor throughout the specified section, with the bald head being preferable to the round channel and the groove, since it is less susceptible to clogging and contains almost no concentrations edge stress, which also increases the strength of the firing pin. At the same time, we also have to clean the calibrated sections of the groove 19 and flatten 20, and the closed channel 18 can be made with a large geometric cross section and, with its increased length, have less local resistance in length and be less prone to clogging. This design also improves reliability and stability operation of the device by reducing the resistance of the cleaned channels, i.e. channels with a smaller coefficient of roughness of the walls. As an embodiment of the device, on the lateral surface of the plunger 13, interacting with the sleeve 2, there are screw discontinuous screw notches 21 (Fig. 13-18) with intermediate sections 22. Such a design reduces the contact area between the interacting surfaces of the striker 10 and the sleeve 2 due to grooves 21. The presence of bridges 22 at the same time ensures the separation of chambers 4 and 15 between themselves, without violating the flow characteristic

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18, groove 19 or flats 20 and thereby increasing the reliability and stability of the workflow in chamber 4 and the device as a whole. Intermediate skins 22 allow an increase in the cross section of the impactor in the plunger section, which increases its strength and also provides a more reliable centering of the impactor when it interacts with the sleeve, which also increases the reliability of the device, eliminating possible seizures between the impactor and the sleeve. i

Submersible pneumatic impact device works as follows.

Compressed air from the network through a trigger (not shown, but can be any of those known for its design) enters the pre-cell chamber, and from there, through channel 3, into the annular chamber 15 of the network pressure. From chamber 15, air through the calibrated through grooves 17 continuously enters the idle chamber 16, and also (regardless of the position of the striker 10), into the controlled chamber 4 of the working stroke in the sleeve 2. In the positions of the striker 10 shown in FIG. 1, 3, 5, 7, 9, 11,

13,15, 17, the launch of the device is provided due to the larger area of the diametrical section of the hammer, which is under pressure, from the side of the chamber 16S than from the side of the chamber 4f communicated with the bottomhole space

14.9, 7 and chambers 15. Due to the difference in pressure impulses from the chambers 16, 15 and 4, the impactor begins an accelerated motion towards the liner 2, making idle. Part of the air from chamber 4 is forced out through channel 14 in the striker, channel 9 in the axial tube and channel 7 in the tool shank.

into the bottomhole space, thereby blowing it out. “Compressed air from chamber 15 is pushed out through the slots 17 at higher speeds due to decreasing air pressure in chamber 16. This circumstance reduces the back pressure from the side of chamber 15, increases it from the side of chamber 16, most increasing the speed of the striker and the magnitude of its progress. This is also facilitated by the flow of part of the air from the chamber 15 through the channel 18 (groove 19, lyske 20) into the chamber 4 located below

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air pressure close in magnitude to the bottom hole, i.e. lower than in chamber 15. As the striker moves 10, rod 5 begins to interact with it, enters channel 14 and closes it, and the air expelled through channels 14, 9 and 7 into the bottom hole space is expelled. From this moment in the chamber 4 begins the simultaneous compression of the air cut off in it and the air entering through channel 18 (slot 19, flat face 20),

Continuing to idle, the hammer 10 releases the tube 8. The air from the chamber 16 begins to exhaust through the channels 9 and-7 into the bottom hole space, blowing it out. Since the compressed air: from the chamber 15 of the mains pressure continuously flows through the slots 17 into the chamber 16, the air pressure in it, and therefore on the blowdown, is maintained continuously calculated and guaranteed throughput of the flow sections of the calibrated slots 17. Simultaneously with the exhaust from the chamber 16 the pressure in chamber 15 decreases. This circumstance allows the drummer to continue idling even with increasing counter-pressure in chamber 4, which guarantees the calculated value of the stroke of the drummer. The reduced contact area of the striker 10 with the sleeve 2 during the movement of the striker due to intermittent screw recesses 21 with intermediate tracks 22 reduces friction, unproductive and uncontrolled leaks and air leakage in the smaller diameter diameter striker, which increases its speed, reduces air consumption by the device, guarantees the design mode of filling the chamber 4 with air. These features appear during the whole working day). - device cycle, i.e. as when idle, and when working stroke drummer.

Having exhausted the impulse from the air pressure from the side of the chamber 16, due to the deceleration of the counter-pressure pulses from the side of the chambers 15 and 4, the striker stops in the calculated position and begins an accelerated movement to the tool 6 shank, making a working stroke ..,

As it progresses, the impactor 10 accelerates under the action of air pressure from the station chambers 4 and 15, forcing the air out of the chamber 16 through the channels

9 and 7 into the wellbore space and provide a continuous flushing process. When the striker 10 moves, the pressure in chamber 4 does not sharply decrease, since during this period of movement, due to the pressure difference in chambers 4 and 15, throttle channel 18 (groove 19, flat 20) provides more air flow, which causes a higher pressure pulse from side of chamber 4 and the high speed of the striker Simultaneously sliding the axial tube 8, the striker 10 blocks the purge

and exhausting air from chamber 16, and releasing channel 14 with rod 5 opens exhaust from chamber 4 of spent and expanding air through channels 9 and 7, thereby performing the process of blowing the bottom hole. The purge from chamber 4 will be stable and continuous for a longer time due to the constant flow of air through channel 18 (groove 199 of the track 20) from chamber 15 to chamber 4. Since chamber 16 is after, the compressor 10 of channel 9 will begin to squeeze while air from chamber 15, the firing pin will begin to slow down. However, since the chamber 16 is communicated through the grooves 17 with the chamber 15t in which the volume increases, a part of the compressed air can flow into it, therefore the pressure in the chamber 16 will increase less sharply than the pre-shock speed of the striker 10 remains.

Overcoming the backpressure of air from the side. Cameras 16, drummer

10 blows the shank 6 of the tool. The process described will be repeated with the only difference that

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in the next idle channel, the impulse of the force driving the striker is complemented by a rebound impulse. This contributes to an increase in the stroke of the striker or to a decrease in the flow of network air, which unambiguously improves the specific operating parameters of the device.

Claims (6)

1. Submersible pneumatic impact device according to ed. St. No. 1534187, characterized in that, in order to increase operational reliability and simplify the design, the impactor is made with a through-calibrated channel that constantly communicates between itself the intermediate annular chamber of network pressure and the working stroke chamber in the sleeve. 2. The device according to claim 1, which is in that the drummer of the stepped drummer of a smaller diameter is made in the form of a plunger. 3. The device according to paragraphs. 1 and 2, characterized in that discontinuous screw recesses are made on the side surface of the plunger, 4. Device on PP. 1-3, characterized in that the through gauge channels are closed in the body of the striker 5. The device according to PP „1-3, about t - characterized by the fact that through calibration channels are made in the form of grooves on the side of the drummer. 6. The device according to paragraphs. 1-3, t - characterized by the fact that through calibration channels are made in the form of bald spots on the side surface of the drummer. fyina) 0606 CSQ , Ј§ Ui  St 5 - JLL1 U. 4V4VC t S 4 XVC 4 . I s ss .NI TTXxMxX i У /////////// У /// Л //////////// 04 to -t INS Fig.12 FIG 11 Schigl FIG. 18