Composite Shock Absorber for Polycrystalline Diamond Compact Bit

Abstract

The invention relates to a composite shock absorber for a polycrystalline diamond compact bit, comprising a drilling tool body having a water inlet, an impact body having a water outlet and forming a shock absorption cavity, a disc spring group having an annular pressing sleeve, a cylindrical torsion bar spring which has an external thread and a spline, is connected to the drilling tool body through threads and extended into an impactor and connected thereto through the spline, and the annular pressing sleeve, wherein bit vibration impact force is transmitted therebetween through a torsion transmission joint, and a bearing group is arranged between the lower end surface of the annular pressing sleeve and an annular step of the impact body. The composite shock absorber can weaken damage of the slippage effect to polycrystalline diamond compact cutting teeth, absorb axial vibration from a drill stem and prolong the service life of the bit.

Claims

1. A composite shock absorber for a polycrystalline diamond compact bit, comprising a drilling tool body (1) having a water inlet (2), an impact body (14) having a water outlet (13), which is arranged at the lower end of the drilling tool body and forms a shock absorption cavity, a disc spring group (4) which sleeves outside a torsion bar spring (5) and has an annular pressing sleeve (6) at the lower end, the torsion bar spring (5), in the shock absorption cavity, which is a cylindrical body, has an external thread and a spline (7) at upper and lower ends thereof, is connected to the drilling tool body (1) in a threaded mode, extended into an impactor and connected thereto through the spline (7) at the upper and lower ends thereof, and the annular pressing sleeve (6) at the lower end of the disc sprig group (4), wherein bit vibration impact force is transmitted between the drilling tool body (1) and the impact body (14) through a torsion transmission joint, and a bearing group (8) is arranged between the lower end surface of the annular pressing sleeve (6) and an annular step, in the drilling tool body (1), of the impact body (14); a sealing ring (10) is arranged between a sealing shaft section (11) at the lower end of the torsion bar spring (5) and the inner wall of the impact body (14), and a sealing ring (10) is also arranged between the outer wall of the impact body (14) and the drilling tool body (1).

2. The composite shock absorber for the polycrystalline diamond compact bit according to claim 1, wherein the axial vibration of the impact body is transmitted to the disc spring group (4) through the annular pressing sleeve (6) and the bearing group (8) to achieve axial vibration absorption; and at the same time, the axial and radial movement of the bit is decomposed by the bearing group (8), the vibration in the torsion direction of impact body (14) is transferred to the torsion bar spring (5) by the spline (7) on the torsion bar spring (5) to achieve vibration absorption in the torsion direction.

3. The composite shock absorber for the polycrystalline diamond compact bit according to claim 2, wherein a spline slot matched with the spline (7) is formed in the inner wall of the impact body (14).

Description

BRIEF DESCRIPTION OF THE FIGURES

[0009] FIG. 1 is a schematic diagram of the structure of the invention.

[0010] FIG. 2 is a sectional view of the connection between the torsion bar spring and the impact body key of the invention.

[0011] FIG. 3 is a schematic diagram of the drilling tool body of the invention.

[0012] FIG. 4 is a schematic diagram of the torsion bar spring of the invention.

[0013] FIG. 5 is a side view of FIG. 4.

[0014] FIG. 6 is a schematic diagram of the impact body of the invention.

[0015] In the figures: 1. drilling tool body; 2. water inlet; 3. threaded section; 4. disc spring group; 5. torsion bar spring; 6. annular pressing sleeve; 7. spline; 8. bearing group; 9. sealing slot; 10. sealing ring; 11. sealing shaft section; 12. torsion transmission joint; 13. water outlet; and 14. impact body.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0016] The invention will be further explained below in conjunction with the figures: as shown in FIG. 1, a composite shocker absorber for a polycrystalline diamond compact bit includes a drilling tool body 1, an impact body 14, a disc spring group 4, a torsion bar spring 5 and an annular pressing sleeve 6, wherein bit vibration impact force is transmitted between the drilling tool body 1 and the impact body 14 through the torsion transmission join 12; the impact body 14 is arranged at the lower end of the drilling tool body 1 and forms a shock absorption cavity; and the disc spring group 4, the torsion bar spring 5 and the annular pressing sleeve 6 are arranged in the shock absorption cavity; the drilling tool body 1 is provided with a water inlet 2; the impact body 14 is provided with a water outlet 13; the water inlet 2, the inner cavity of the torsion bar spring 5 and the water outlet 13 define a fluid channel; the bit vibration impact force is transmitted between the drilling tool body 1 and the impact body 14 through the torsion transmission join 12; axial vibration absorption of the drilling tool is realized by the impact body 14 through the disc spring group 4; and vibration absorption in the torsion direction of the drilling tool is realized by the impact body 14 through the torsion bar spring 5.

[0017] With the combination of FIG. 4 and FIG. 5, the torsion bar spring 5 is a cylindrical body, is provided with an external thread at the upper end, and is positioned in the shock absorption cavity; the upper end of the torsion bar spring 5 is in threaded connection to the drilling tool body 1; the lower part of the torsion bar spring 5 extends into an impactor; with the combination of FIG. 2, the lower part of the torsion bar spring 5 is provided with a spline 7 and a spline slot matched with the spline 7 is formed in the inner wall of the impact body 14; torsion transmission is realized through key connection between the torsion bar spring 5 and the impactor; the disc spring group 4 sleeves outside the torsion bar spring 5, and an annular pressing sleeve 6 is arranged at the lower end of the disc spring group 4; a bearing group 8 is arranged between the lower end surface of the annular pressing sleeve 6 and the annular step, in the drilling tool body 1, of the impact body 14, so that torsion is separated from movement in the axial direction; axial vibration of the impact body 14 is connected to the disc spring group 4 through the annular pressing sleeve 6 and the bearing group 8 to achieve axial vibration absorption. Meanwhile, decomposition of axial and radial motion of the bit is realized through the bearing group 8, and the vibration in the torsion direction of the impact body 14 is connected onto the torsion bar spring 5 through the spline 7 on the torsion bar spring 5 to achieve vibration absorption in the torsion direction.

[0018] A sealing ring 10 is arranged between the sealing shaft section 11 at the lower end of the torsion bar spring 5 and the inner wall of the impact body 14, and a sealing ring 10 is arranged between the outer wall of the impact body 14 and the drilling tool body 1 to achieve fluid sealing.

[0019] Refer to FIG. 3, the drilling tool body 1 is a cylindrical body, and is provided with a water inlet 2 in the upper end, a threaded section 3, threads of which are internal threads for being in threaded connection to the torsion bar spring 5, is arranged under the water inlet 2; a shock absorption section is arranged under the threaded section 3, and an annular sealing slot 9 is formed in the inner wall of the shock absorption section.

[0020] Refer to FIG. 6, the impact body 14 is a cylindrical body, a spline slot is formed in the outer wall of the upper end of the impact body 14, and a water outlet 13 is formed in the lower end of the impact body 14.

[0021] During mounting, the disc spring group 4 and the annular pressing sleeve 6 firstly sleeve the torsion bar spring 5, and the torsion bar spring 5 and the drilling tool body 1 are screwed and fixed through threads; the bearing group 8 is placed in the drilling tool body 1 for connecting the torsion bar spring 5 to the impact body 14 through the spline 7; and the bearing group 8 is arranged between the annular pressing sleeve 6 and the impact body 14.

[0022] In use, the drilling tool body 1 is connected to an upper bit, and the impact body 14 is connected to the bit, so that on one hand, axial vibration from the drill stem is absorbed, on the other hand, vibration impact in the torsion direction of the PDC bit is absorbed, and the damage of the slippage effect to PDC cutting teeth can be weakened.