前苏联专利SU917704A3 Upper drill bit shock-absorber

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专利摘要:
1504918 Spring units LEE-MASON TOOLS Ltd 19 May 1975 [10 July 1974] 21144/75 Heading F2S [Also in Division E1] A drill-string vibration damper comprises a barrel section 10, Fig. 1a, for connection to the drill bit, a tubular mandrel section 12 for connection to the drill-string, a spline assembly 18 permitting relative longitudinal movement of the sections and preventing relative rotary movement, and a resiliently deformable damping element 38, Fig. lb, disposed in a bath of operating liquid in a chamber 109 defined between the telescoped sections. The lower end of the mandrel may be provided with a floating seal 84, Fig. 1c, which equalizes the operating liquid and the down-the-hole fluid pressures. The damping element comprises a series of alternate elastomeric and rigid rings (Figs. 9 to 14, not shown). Restricted operating- liquid passages 22, 37 are provided to control the telescopic movement of the sections. The sections are laterally stabilized by means of rings 45, 67 and 78.
公开号:SU917704A3
申请号:SU752150660
申请日:1975-07-04
公开日:1982-03-30
发明作者:Мейсон Леонард；Андерсон Клиффорд
申请人:Ли-Меисон Тулз Лтд (Фирма)；
IPC主号:

专利说明:

The invention relates to a device used in the composition of a Vpy6 drill string for absorbing shock loads that result from axial movement of the bit in the drilling process. When the bit rotates at the bottom of the borehole, a constant bit bounces upwards, with a subsequent return downward. Accelerations (occurring when moving from the bottom, create large cyclic loads in the string of strong pipes. Intensive cyclic loading of the drill string leads to a number of negative consequences. For example, this load is the main cause of wear and breakage of drill pipes. It creates heavy drilling rig equipment operation} with particularly heavy drilling operations, the entire structure of the drilling rig is subjected to intensive testing and the only means of reducing vibration is to reduce the speed of rotation and / or the weight load acting on the bit. However, such measures lead to a decrease in the drilling rate. A common technique for reducing vibration is to incorporate into the drill string, above the bit, a device for absorbing shock loads, known as a vibration damper. A shock absorber comprising a shaft, an upper end connected to the drill string, and a tubular body located outside, the lower end of which is connected to the drill bit. Inenny with a chisel or with rings located directly above the chisel. The shaft moves progressively or telescopically in the housing bore. These two parts are interconnected by elements such as slits and, thus, can only be rotated together.
Of course, however, they have the possibility of reciprocal longitudinal movement. Means are available that limit the amount of reciprocal longitudinal movement of these parts and thus prevent the separation of the settlement, one from the other. In one of the main types of vibration dampers considered, the shaft has a current with a reduced outer diameter, so that an annular chamber is formed between this mandrel and the sleeve. O-rings were installed at each end of the chamber between the shaft and the housing to prevent the drilling fluid from entering the chamber. The mandrel and the sleeve are provided with mutually opposite upper and lower pressure shoulders protruding radially in the annular chamber near the upper and lower ends., In the chamber between the pressure shoulders installed deformable element 112. In the process, with the accelerated movement of the bit upward pressure shoulder The liner acts on the base of the deformable element. The axial shoulder of the mandrel located at the other end prevents the axial displacement of this element. When the shoulders come closer together, the named element undergoes deformation. Theoretically, this deformable element should absorb the axial force developed by the chisel and prevent the transfer of the shock load. In practice, however, a deformable element that is soft with a small depth of drilling can become hard when drilling at a large depth. A supra-longitudinal shock absorber is known for absorbing shock loads resulting from axial displacement of a bit and containing telescopically coupled tubular parts which are a housing and a shaft mounted in a housing opening with a cavity between the housing and the shaft, with the possibility of mutual longitudinal movement of the housing. and a shaft, means connecting the housing with the shaft, ensuring their joint rotation and preserving the possibility of their mutual telescopic movement, elastically deformable
an element located in the said cavity and forming a gap with the inner surface of the housing; a pair of mutually opposite supporting elements on the shaft and the body protruding into the said cavity and intended to act on the ends of the deformable element;
the cavity, together with the deformable element, and the means practically impermeable to the fluid, the hermetic cavity called the cavity and thereby preventing the displacement of the drilling fluid with the working fluid C2. The lack of a shock absorber lies in the fact that it does not sufficiently absorb shock loads at different weight loads on the bit and pressures developed by the pump, as is the case at different depths and bore diameters. The purpose of the invention is to ensure the effectiveness of the absorption of shock loads at different depths and diameters of the well. This goal is achieved in that the under-shock absorber is provided with a floating piston installed in the lower part of the shaft between its outer surface and the inner surface of the housing, with the piston cavity hydraulically communicating with the cavity for the elastically deformable element less than 17860 kg / cm and forms a gap with the outer surface of the shaft. Preferably, the deformable element is made up of elastomeric material and steel rings arranged in order of alternation of wheels and steel rings provided with a collar located on the outer and inner ring surfaces of the steel rings. In addition, a shock absorber increases the rigidity of the shock absorber, which prevents the well from deviating from vertical, provided with stabilization rings mounted in recesses made on the inner surface of the housing. The sub-piston cavity of the under-long shock absorber can communicate with the well or through the tube cavity, or through the annulus. Figs. 1-3 show the under-shock absorber in the n, loaded or stretched state (a version of the communication of the piston casing of the shock absorber with the borehole, through the tube cavity of the drill string), partial cuts; in fig. 4-6 - the same, in the loaded and compressed state, section; in fig. 7 - the lower part of the under-bore shock absorber in the unloaded state of the SRI (a variant of communicating the sub-piston cavity of the shock absorber with the well through the annulus) section; in fig. 8 - the same, in the loaded condition, a section; in fig. 9a section AA in FIG. four; in fig. 10 is a sectional view of FIG. five; in fig. eleven - . Section B-B in FIG. five; in fig. 12 section G-Y in FIG. 6; Fig. 13 shows, from the joint part of the deformable element: used in the supra-long shock absorber, top view (variant); in fig. 14 is a section dD in FIG. in fig. 15 - a component of the deformable element, top view (variant); in fig. 16 is a section E-E of FIG. 15; in fig. 17 - the composite part of the deformable element, top view (option); in fig. 18 is a section of an LF in FIG. 17. A bore shock absorber comprises a tubular body 1 (Fig. 1-b) and a tubular shaft 2. The shaft 2 is mounted in the body 1 with the possibility of movement relative to it. The upper end of the shaft 2 is made in the form of a part 3 provided with a socket 4 for connecting to a string of drill pants (not shown). Below the nest 4 there is a section 5 of a reduced diameter, passing in its lower part and a section equipped with external slots 6 cut into the surface of the mandrel. Below the slide 6 there is a section 7 of smaller diameter, the surface of which is filled with a series of grooves or grooves 8 extending along the depressions of the outer splines named; At the lower end of the part 3 with external splines 6 there is a shank 9 (Fig. 2. Part 3 has an axial channel for supplying drilling mud (not shown) to the drilling mud. The lower end of the shaft 2 is a pipe 10, the upper part 11 of which is provided with a socket designed for connection with the shank 9, and the lower part 12 has a reduced diameter.These parts of the pipe 10 together form a pressure shoulder 13. A sealing ring 14 is installed in the nest of the upper part 11 of the pipe 10, which seals the connection of this end with the shank 9 of part 3. Ver The xn part 11 of the pipe 10 is located relative to the housing 1 with a gap forming the annular channel 15. The shoulder 13 has radial channels 16. The lower part 12 of the pipe 10 is provided with a thread 17 (Fig. H). A nut 18 is screwed on this thread. the pipes 10 are such that this part enters the package of deformable rings 19 forming the elastically deformable element 20 and supports these rings B the surface of the lower part 12 has straight grooves or grooves 21. The housing 1 contains a sealing head 22 located at its upper end, having an axial shaft the hole and the supporting surface, the diameter of which corresponds to the diameter of the supporting surface of section 5, which is included in the above-indicated axial hole with the formation of high-precision mating. On the inner surface of the sealing head four grooves 23, jB of which are installed, are made. rings 24, preventing leakage of fluid, and solid centering rings 25. There is also a dirt ring 26. At the lower end of the sealing head 22, there is a shank 27 that fits into the socket of the connecting part 28, which is at the upper end of the part 29 with inner slots 30, part of the case. The inner splines 30 (Fig. 9) contain a steel core on which a coating layer 31 consisting of a synthetic material is formed, which has a very high resistance to wear and abrasion and softens shocks during transmission of a torque to the splined joint. At the lower end of the part 29 with internal splines there is a shank 32 (FIG. 2) provided with a seal ring 33. The lower portion 34 of the part 29 has a reduced diameter and forms a bearing surface that interacts with a shaft section having a correspondingly made seating surface. In order to ensure the stability of the mutual position of the parts, several centering rings 35 are installed in the section 34. The shank 32 of the housing part 29 is included in the socket 36 of the housing element 37, which serves to accommodate the deformable element. The lower end of the shank 32 limits the longitudinal upward movement of the shaft 2 due to the interaction with the upper end of the end 11 of the pipe 10. The housing element 37 in the lower part has a hole 38 of reduced diameter, forming a pressure shoulder 39. The shoulder 39 limits the longitudinal movement of the shaft 2 downwards. Taking my shoulder I3 onto the deformable rings 19, the mandrel presses them against the shoulder 39. The diameter of the hole .38 allows the lower end of the pipe 12 to be installed with a support that ensures the stability of the position of the pipe. In the grooves made in the machine tool of the housing element 37, centering rings 40 are mounted on the fluid-tight interface between shaft 2. The lower end of the housing element 37 is provided with a shank 41 (Fig. 3), included in the socket of the connecting part 42, which is located in the upper end 43 of the lower part of the body. On the shank 41 a sealing ring 44 is installed, sealing the threaded connection. The lower body assembly 43 has an axial channel, the diameter of which bores the diameter of the lower end of the pipe 1, being the part of the shaft on which the floating piston 45 is mounted, which has sealing rings 46 and 47 creating fluid-tight mating of the piston with the surface of opening 48 and with the outer surface belonging to the pipe 10 of a part 12 of reduced diameter. The floating piston 45 is held on the pipe 10 by a nut 18. At the lower end of the lower body assembly 43 there is a shank 49 for connecting to the lower part of the drill string (not shown). A hole 50 is made in the wall of the member 37 which is intended to accommodate the deformable element and is closed by a plug 51, which can be removed 4 for insertion into the cavity of a working device, liquid or other similar medium as described below. A similar hole 52 with a plug 53 is located in the lower part of the housing part 29. In the centering surfaces of the splines (Fig. 9 and 10) through two slots, longitudinal grooves 8 are made. In addition (Fig. 10), the channels 54 passing through the shank 32 are shown. The channels 16 intersect the shoulder 13 of the end 11 of the pipe 10. Rings 23 located between the shaft and housing elements form one pair of centering surfaces, rings 35 another pair of centering surfaces, rings 40 the third centering position, in addition, the floating piston 45 is another centering element installed in the lower part between the shaft elements and shells . All these stabilizing positions of the parts of the shock absorber elements contribute to the connection between the housing 1 and the shaft 2 in the transverse direction and increase the rigidity of the device. Between the outer surface of the shaft 2 and the inner surface of the housing 1 there is an annular cavity 55. The ends of the cavity 55 are closed by liquid-tight sealing means 23, 46, 47. The centering rings 35 and 40 divide the annular cavity 55 into the part chamber with internal splines, the chamber of the deformable element and a floating piston chamber. The cavity 55 is filled with deformable rings 19 and the working fluid. The fluid can move freely between the indicated chambers through channels 8, 54, 15, 16 and 21. The piston cavity 56 of the floating piston is hydraulically connected to the well through the cavity of the shank 49 and then through the pipe cavity (not shown). FIG. 7 and 8, there is shown another embodiment of the device according to the invention, in which the structure of the lower end of the pipe 10 for supplying the drilling fluid and the unit 43 of the lower body is modified. The opening 48 of the assembly 43 communicates with the opening 57 of intermediate diameter j, this diameter is such that it is in high-precision mating with part 12
pipes 10 of reduced diameter. A pair of sealing rings 58 is installed in the upper end of the hole 57. One or more through holes 59 are made in the wall of the floating piston unit 43, which allow the lower part of the hole 48 to communicate with the outside medium with the annular space. The thread 17 and the nut mounted on the lower end of the pipe 10 are not applicable in the present embodiment; the reduced-diameter part 12 is provided with an extension section 60, which, when the device is unloaded, enters the opening 57 and is covered by sealing rings 58. In this embodiment, the piston cavity 56 is hydraulically connected to the well through the annulus. The floating piston is subjected to the pressure present in the well, and not the pressure acting in the cavity of the drill string. The result is that the fluid in the inner chambers of the super-chilled shock absorber is under pressure acting in the well, as a result of which the pressure drop across the drill crown affects only the working area of the extension portion 60 of the pipe 10. For this reason, in the described Alternatively, the force that tends to push the details of the overhead shock absorber is much less compared to the force that opens the parts in the embodiment of FIG. l-6i while the pressure equalization is maintained. This design is particularly useful for large-diameter devices used in drilling shallow wells, where the weight load on the bit may be slightly greater than the force generated by the pressure difference across the pressure ring working area.
FIG. 13 and 14 (top view and section) is represented by one of the embodiments of deformable rings 19. The deformable ring 19 contains a recessed metal washer 61 having a pair of protruding shoulders 62 and 63 forming. co: face recess 64, in which a ring 65 made of elastomer is installed, the thickness of which exceeds the height of the shoulders 62 and 63. The ring 65 made of elastomer is deformed by the force applied to it, however, being elastic, after removal the force takes on its original shape .
The deformable ring (Figs. 15 and 16) contains a flat metal washer66, with which the corresponding ring 67 is made of elastomer and has a cross section of trapezium with a large base in contact with the metal washer 66.,.
The deformable ring (figs. 17 and 18) contains metal; kie washers 68 and 69, each of which is provided with an outer collar 70 and an inner collar 71, forming annular
recesses 72 and 73. In each of the recesses there is a ring 74 made of elastomer sandwiched between adjacent washers. Side surfaces 75 made of elastomer
The rings 74 have a concave shape that objiernaeu-installation, and the retention of the rings in the recesses of the washers.
The designs of all these deformable rings are such that for small
loads the deformation of the device is greater than under heavy loads.
Various elastomers, including rubber, silicone rubber, neoprene rubber, and urethane can be used to manufacture the deformable element. It is also possible to use washers made of solid non-metallic material instead of metal washers, and the use of a single deformable body instead of a package of alternating metal and elastomeric parts. The end of the end 11 pipe 10 shaft 2
(Fig. 2), interacting with the end of the shank 32 of the housing part 29, limits the mutual telescopic movement of the mandrel and the sleeve and prevents them from disengaging.

权利要求:
Claims (2)
[1]
When using an overhead chopper, the shank 49 of the node 43 is screwed into the bit, and the socket 4 of the part 3 forms a threaded connection with the coupling or centering parts located at the lower end of the drill string. The proposed device is designed for the conditions that occur in the drilling of both shallow and deep wells and hard and soft rocks. The Nadolite shock absorber works as follows. The shock absorber, which is in a fully extended condition, is lowered into the well in the drill string until the bit touches the bottom of the bottom. The downhole pressure and the pressure created by the fluid in the well displace the floating piston upwards, as a result of which the pressure in the annular cavity 55 is equalized with the said bottomhole pressure. At that, the weight of the column is applied to the drill crown, and thus the device is loaded. In the course of the oncoming telescopic movement of the shaft 2 and the body 1 of the ring I9 of the deformable element, they are compressed by pressing shoulders 13 and 39. After that, the pump for supplying the drilling fluid, which increases the pressure, is included in the equipment of the drilling rig. At the same time, due to the pressure created by the pump on the working area of the pipe 10 and the part 3 with external splines, the load on the rings 19 of the deformable element is reduced. Said pressure tends to be attributed to the telescopically coupled device legs. As a result, the load on the rings of the deformable element will be reduced, despite the fact that the load on the bit does not change. The drill string is then rotated. In the process of vertical displacement, of bits and pieces up and down relative to the midpoint with a frequency of three cycles per second, compression and expansion of the deformable element 20 occurs with the same frequency. The urethane rings 65 are deformed, in which the working fluid is injected through the grooves 21, which are contained in the pipe 10 of the reduced-diameter part 12, into the piston cavity and tends to move the floating piston 45 downward. When compressing and expanding the device, the working fluid flows between the chambers, accompanied by the absorption of energy. Since the stiffness of the elastically deformed element is less than 17,860 kg, the over-shock absorber is perceived by the majority of the cyclic load caused by the movement of the drill crown. At the same time, the operation of the structure during drilling at all depths, with different weight loads on the bit and pressures developed by the pump is ensured by the presence of a floating piston ensuring pressure equalization in the chamber of the elastic member with pressure at the bottom of the well and thereby reducing the amount of preliminary loading elastically deformable element. The presence of a gap between the elastically elastic element and the walls of the chamber formed by the outer surface of the shaft and the inner surface of the housing prevents wear of the elastic element being deflected, which ensures its constant characteristics and uninterrupted overflow of the working fluid. Claims I. Naddolitnyi shock absorber, comprising a housing and a shaft connected by a spline connection and forming a cavity between the outer surface of the shaft and the inner surface of the housing, in which along its length there is a support resting on the shaft supporting surface at one end of the cavity and on the supporting surface of the housing on the other at the end of the cavity there is an elastically deformable element, between the outer surface of which and the inner surface of the body there is a gap, and the cavity contains working fluid and has means sealing it, so that, in order to ensure the effectiveness of absorbing shock loads at different depths and diameters of the well, it is provided with a floating piston installed in the lower part of the shaft between its outer surface and the inner surface of the body; A cavity with an elastically deformable element and a podporshneva with a well, the elastically deformable element having a stiffness less than 17860 kg / cm and forming a gap with the outer surface of the shaft. 2. The shock absorber of claim 1, in which the elastically deformable element consists of alternating elastic rings and metal washers. 3. The shock absorber of claim 1, wherein the metal washers have a collar along the outer and inner annular surfaces. 4. The shock absorber according to claim 1, characterized in that, in order to increase the rigidity of the shock absorber, it is provided with stabilizing rings mounted on the inside of the housing surface. 414 5. The shock absorber according to claim 1, about tl, and in that the piston cavity communicates with the well through the pipe cavity. 6. The shock absorber of claim 1, wherein the podpnevnevaya cavity communicates with the well through the annulus. / Sources of information taken into account in the examination 1. USSR author's certificate number 170884, cl. Е 21 В 17/06, 25.09.63.
[2]
2. USSR author's certificate number 261310, cl. Е 21 В 17/06, 10.05.67 (prototype).
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FIG. eleven
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FIG. 15
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同族专利:

公开号 | 公开日

NL7508248A|1976-01-13|

FR2277969B1|1978-04-14|

GB1504918A|1978-03-22|

NL8101939A|1981-09-01|

CA1037464A|1978-08-29|

DE2530501C3|1980-10-09|

AU499070B2|1979-04-05|

DE2530501B2|1980-02-21|

NO752074L|1976-01-13|

DE2530501A1|1976-01-29|

NO148082C|1983-08-03|

NO148082B|1983-04-25|

CA1014140A|1977-07-19|

FR2277969A1|1976-02-06|

AU8221175A|1976-12-23|

引用文献:

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CA1021966A|1975-04-01|1977-12-06|Clifford Anderson|Spline mechanism for drill tools|

US4194582B1|1978-06-28|1987-05-05|

DE2917331C3|1979-04-28|1982-02-04|Christensen, Inc., 84115 Salt Lake City, Utah|Direct drive for deep drilling bits or the like. tools working in a pipe hole|

GB2140846A|1983-04-27|1984-12-05|Webb John Thomas H|Improvements in or relating to damping means|

GB8408673D0|1984-04-04|1984-05-16|Piper Products Ltd|Transmitting torque|

US4600062A|1984-07-13|1986-07-15|501 Dailey Petroleum Services Corporation|Shock absorbing drilling tool|

CN104975815B|2015-06-24|2017-03-08|长江大学|One kind is with brill shock absorber|

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CN105840676A|2016-04-26|2016-08-10|苏州昭沃五金科技有限公司|Spline shell|

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法律状态:

优先权:

申请号 | 申请日 | 专利标题

CA204,532A|CA1014140A|1974-07-10|1974-07-10|Drilling string shock-absorbing tool|

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