The present invention relates to down-hole drill assemblies, and more specifically to bit assemblies for such down-hole drills.
Down-hole percussive drills generally include a casing connected with a source of pressurized working fluid (e.g., compressed air), a piston movably disposed within the casing and reciprocally driven by the fluid, and a bit connected with the casing and including cutting elements on an outer face. In use, the working fluid is appropriately directed to reciprocate the piston between an impact position, at which the piston strikes against the bit inner end, and an initial or drive position, from which the piston is driven to achieve an amount of momentum prior to impact with the bit. The piston is displaced toward the drive position by fluid channeled into a return chamber defined generally between the piston and bit. However, after the piston starts moving toward the drive position (i.e., away from the bit), fluid within the return chamber must be exhausted, preferably through a longitudinal bore of the bit, to prevent such fluid from slowing the piston when it moves back toward impact with the bit.
To prevent premature exhaustion of the return chamber, percussive drills are often provided with a device known as an exhaust tube or “foot” valve that extends into the return chamber from the bit contact end. The valve has a portion that is insertable into a passage of the piston to prevent evacuation of the chamber until the piston reaches a certain distance from the bit. Such a valve is inserted into the bit bore and is typically maintained in the bore by one or more annular shoulders projecting from the valve, which become disposed in annular grooves extending radially outwardly from the bore into the bit body. Although such as design for retaining the valve within the bit bore is generally effective, stress tends to concentrate at the points of contact between the valve shoulder and bit grooves, which may cause early failure of the valve.
In one aspect, the present invention is a bit assembly for a percussive drill, the drill including a casing with an interior chamber. The bit assembly comprises a bit connectable with the casing and having a longitudinal bore and an axis extending centrally through the bore. The bore has a retainer portion with at least one generally conical inner surfaces extending circumferentially about and facing generally toward the axis. Further, a generally cylindrical valve has a longitudinal passage, the passage having an inlet fluidly connectable with the return chamber and an outlet fluidly connectable with the bit central bore, an axis extending centrally through the passage, and an engagement portion. The engagement portion has at least one generally conical outer surfaces extending circumferentially about and facing generally away from the valve axis. Furthermore, the valve engagement portion is disposable within the bit bore retainer portion such that the valve conical outer surface is disposed within and against the bit conical inner surface so as to retain the valve coupled with the bit.
In another aspect, the present invention is a percussive drill assembly comprising a casing with an interior chamber and a longitudinal axis a piston movably disposed within the casing chamber. The piston is displaceable generally along the axis and has a central longitudinal axis. A bit is connected with the casing and has a longitudinal bore and an axis extending centrally through the bore. The bore has a retainer portion with one or more generally conical inner surfaces extending circumferentially about and facing generally toward the axis, the conical surfaces being spaced apart axially when the bit has at least two surfaces. Further, a generally cylindrical valve has a longitudinal passage, the passage having an inlet fluidly connected with the return chamber and an outlet fluidly connected with the bit central bore, an axis extending centrally through the passage, and an engagement portion. The valve engagement portion has one or more generally conical outer surfaces extending circumferentially about and facing generally away from the valve axis, the conical surfaces being spaced apart axially when the valve has at least two surfaces. Furthermore, the valve engagement portion is disposed within the bit bore retainer portion to thereby couple the valve with the bit, each valve conical outer surface being disposed against a separate bit conical inner surface.
In a further aspect, the present invention is again a bit assembly for a percussive drill, the drill including a casing with an interior chamber. The bit assembly comprises a bit connectable with the casing and having a longitudinal bore and an axis extending centrally through the bore. The bore has a retainer portion with at least one generally conical inner surface extending circumferentially about and facing generally toward the axis, the inner conical surface extending along a substantial portion of the bore. A generally cylindrical valve has a body with a longitudinal passage, the passage having an inlet fluidly connectable with the casing chamber and an outlet fluidly connectable with the bit central bore. An axis extends centrally through the passage, the body having a length along the axis, and an engagement portion with at least one generally conical outer surface extending circumferentially about and facing generally away from the valve axis, the at least one outer conical surface extending along a substantial portion of the body length. The valve engagement portion is disposable within the bit bore retainer portion such that the valve conical outer surface is disposed at least partially within the bit conical inner surface to retain the valve coupled with the bit, at least a substantial portion of the valve outer surface being engageable with the bit inner surface so that a generally uniform contact pressure is generated between the inner and outer conical surfaces.
In a further aspect, the present invention is an exhaust valve for a percussive drill, the drill including a casing with an interior chamber and a bit connectable with the casing. The bit has inner and outer ends and a longitudinal bore extending between the two ends and having an inner circumferential surface. The exhaust valve comprises a generally cylindrical body with first and second ends and a longitudinal passage extending between the two ends, the passage having an inlet at the first end fluidly connectable with the casing chamber and an outlet at the second end fluidly connectable with the bit central bore. The valve body includes a generally cylindrical regulator portion disposable within the casing chamber and a generally conical engagement portion spaced axially from the regulator portion and at least partially disposable within the inner end of the bit bore. The engagement portion has at least one generally conical outer surface frictionally engageable with the bit bore inner surface to retain the valve coupled with the bit. Further, the at least one conical surface has a first circumferential edge located generally proximal to the regulator portion, a second circumferential edge located generally proximal to the body second end, and an outside diameter that varies generally linearly between a first value at the surface first edge and a second value at the surface second edge, the diameter second value being greater than the diameter first value.
The foregoing summary, as well as the detailed description of the preferred embodiments of the present invention, will be better understood when read in conjunction with the appended drawings. For the purpose of illustrating the invention, there is shown in the drawings, which are diagrammatic, embodiments that are presently preferred. It should be understood, however, that the present invention is not limited to the precise arrangements and instrumentalities shown. In the drawings:
Certain terminology is used in the following description for convenience only and is not limiting. The words “lower”, “upper”, “upward”, “down” and “downward” designate directions in the drawings to which reference is made. The words “inner”, “inwardly” and “outer”, “outwardly” refer to directions toward and away from, respectively, a designated centerline or a geometric center of an element being described, the particular meaning being readily apparent from the context of the description. Further, as used herein, the word “connected” is intended to include direct connections between two members without any other members interposed therebetween and indirect connections between members in which one or more other members are interposed therebetween. The terminology includes the words specifically mentioned above, derivatives thereof, and words of similar import.
Referring now to the drawings in detail, wherein like numbers are used to indicate like elements throughout, there is shown in
Further, the exhaust valve 14 has a longitudinal axis 14a, opposing ends 14b, 14c spaced apart along the axis 14a, and a longitudinal passage 15. The valve passage 15 has a first port or inlet 15a extending through the valve first or upper end 14b and fluidly connectable with the casing chamber 3 and a second port or outlet 15b extending through the valve second or lower end 14c and fluidly connectable with the bit central bore 13, the axis 14a extending centrally through the passage 15. Preferably, the valve 14 includes a generally cylindrical body 17 with first end second ends 17a, 17b and a generally circular bore 17c extending between the two ends 17a, 17b and providing the passage 15, but may alternatively be constructed having any other appropriate shape/structure that is capable of functioning as generally described herein.
Furthermore, the valve 14 has an engagement portion 20 with at least one generally conical outer surface 22 extending circumferentially about and facing generally away from the valve axis 14a. In a first construction shown in
Referring to
Referring to
Furthermore, when the valve 14 is separate from or “non-engaged” with the bit 12, the first value vO1 of the valve outside diameter DO is greater than the first value vI1 of the bit inside diameter DI and the second value vO1 of the valve outside diameter DO is greater than the second value vO1 of the bit inside diameter DI. In other words, when the two components 12, 14 are uncoupled, the valve outer surface 22 is spaced outwardly from the valve axis 14a by a greater radial distance than the bit inner surface 18 is spaced from the bit axis 12a. As such, when the valve engagement portion 20 is inserted into the bore retainer portion 16, the valve 14 engages the bit 12 with an interference fit. Specifically, the valve engagement portion 20 must be press-fit into the bore retainer section 16, which, due to the structure described above, generates the substantially uniform contact pressure P between the mating surfaces 18, 22, and thus the frictional forces that maintain the valve 14 coupled with the bit 12.
Referring instead to
Furthermore, as with the first construction, when the valve 14 and bit 12 of the second construction are separate from or non-engaged with each other, the first value vSO1 of the outside diameter DSO of each valve surface section 23 is greater than the first value vSI1 of the inside diameter DSI, of the corresponding bit surface section 19, and each outside diameter second value vS02 is greater than each corresponding inside diameter second value vSI2. Thus, when the two components 12, 14 are uncoupled, each valve outer surface section 23 is spaced outwardly from the valve axis 14a by a greater radial distance than the corresponding bit inner surface section 19 is spaced from the bit axis 12a. Therefore, when the valve engagement portion 20 is inserted into the bore retainer portion 16, the valve 14 engages the bit 12 with an interference fit, such that the valve engagement portion 20 must be press-fit into the bore retainer section 16, which, due to the structure described above, generates the substantially uniform contact pressure P between each pair of mating surfaces 19, 23, and thus the frictional forces that maintain the valve 14 coupled with the bit 12.
Preferably, the bore retainer portion 16 has an interior end 16a located between the bit axial ends 12a, 12b, such that the bore flow portion 27 extends from the retainer end 16a to the bit outer end 12a, and the second circumferential edge 18b of the bore conical surface 18 is axially spaced from the interior end 16a (i.e., toward the bit inner end 12b). As such, the retainer portion 16 of both bit assembly constructions further has a generally cylindrical inner surface 26 and a radial shoulder surface 28, which are preferably connected by a radiused surface 31. The cylindrical inner surface 26 extends circumferentially about the bit axis 12a and axially between the retainer portion interior end 16a and the conical surface second edge 18b. The shoulder surface 28 extends generally radially between the cylindrical inner surface 26 and the bore flow portion 27. Further, the cylindrical inner surface 26 is preferably spaced radially outwardly with respect to the inner circumferential surface 27a of the bore flow portion 27, such that the shoulder surface 28 faces generally toward the bit inner end 12b.
Additionally, the second edge 22b of the valve conical outer surface 22 of the first bit assembly construction or of the “lowermost” conical outer surface section 23A (i.e., the outer surface section 23 most proximal to valve second end 14c) of the second construction is preferably spaced axially from the valve second end 14c. As such, the valve engagement portion 20 of both bit assembly constructions further has a generally cylindrical outer surface 32. Specifically, the cylindrical outer surface 32 extends circumferentially about the valve axis 14a and generally axially between the valve second end 12b and the conical outer surface second edge 22b. Further, the valve 14 also has a generally radial end surface 34 located at the valve second end 14c, which extends about the valve second port 15b and is contactable with the bore shoulder surface 28, as discussed below. Referring particularly to
With the structure described above, when the valve engagement portion 20 is disposed within the bit retainer portion 16, the valve end surface 34 is disposed generally against the bore shoulder surface 28 and the valve cylindrical outer surface 32 is disposed within the bit cylindrical inner surface 26. As such, contact between the valve shoulder surface 32 and the bit bore first shoulder surface 28 substantially prevents relative displacement between the valve 14 and the bit 12 in a first direction d1, along the bit axis 12a. Further, contact between the valve conical outer surface 22 or surface sections 23 and the bit conical inner surface 18 or surface sections 19, respectively, prevents relative displacement between the valve 14 and the bit 12 in a second, opposing direction d2 along the axis 12a during normal use of the drill 1. Preferably, the valve 14 remains coupled with the bit 12 during the productive life of the bit assembly 10, and the bit assembly 10 is discarded and replaced as a single unit. However, if it were desired to uncouple the valve 14 from the bit 12 (e.g., if newly connected valve 14 found defective/damaged), a sufficient force applied to the valve 14 in the second direction d2 along the axis 12a will enable the valve 14 to deform radially inwardly to an extent sufficient to enable the valve conical outer surface 22/surface sections 23 to slide against the bit conical inner surface 18/surface sections 19 in the second direction d2 until the valve 14 is disengaged from the bit 12, as discussed in further detail below.
Referring again to
Referring again to
Preferably, the bit 12 is substantially formed of a metallic material, and is most preferably machined from a low carbon steel forging. The valve 14 is preferably substantially formed of a polymeric material, such as being machined from extruded or molded DELRIN® (i.e., acetyl homopolymer) commercially available from the DuPont Corporation, or a lightweight metallic material, for example being cast from aluminum. However, it is within the scope of the present invention to form either the bit 12 or valve 14 of any appropriate material and/or by any appropriate process, such as for example, casting the bit 12 of an alloy steel, injection molding the valve 14 from another polymer, machining the valve 14 from a low carbon or alloy steel forging, forming the valve 14 of a composite of polymeric and metallic materials, etc.
With the structure above, the bit assembly 10 of the present invention is assembled generally in the following manner. With the bit 12 separate from the casing 2, the valve second end 14c is positioned at the bore inner end 13a, and then a force is applied in the first direction d1 along the bit axis 12a to partially collapse or deform the valve 14 to thereby enable the valve 14 to move along the bit axis 12a. The cylindrical outer surface 32, and subsequently the conical outer surface 22, slides against the bit conical inner surface 18 or surface sections 19 until the valve cylindrical outer surface 32 becomes disposed within the bore cylindrical inner surface 26, and thereafter the valve radial end 34 contacts the bit radial shoulder 28. At this point, the valve engagement portion 20 is fully disposed within the bit retainer portion 16, and then valve regulator portion 50 extends away from the bit inner end 12b. As discussed above, the coupling of the valve 14 and bit 12 is thereafter maintained by the interference fit/frictional interaction between the bit and valve conical surfaces 18, 22 or surface sections 19, 23 and cylindrical surfaces 26, 32. The bit assembly 10 may then be installed in the casing 2 such that the bit upper end 12b is contactable by the piston strike end 4b and the valve regulator portion 50 is disposable within the piston passage 4a or/and within the return chamber 3.
Comparing the first and second constructions of the bit assembly 10, as discussed above, the bit 12 and the valve 14 of the first construction each have a single conical surface 18, 22 extending axially along generally the entire axial length lR, lE of the retainer and engagement portions 16, 20. In the second bit assembly construction, the bit 12 and valve 14 each have a plurality of surface sections 19, 23 spaced apart axially along the retainer and engagement portions 16, 20 and each extending along an equal portion lRp, lEp of the overall retainer or engagement portion lengths lR, lE (see
With a steeper taper angle ASB, ASV between the engaged bit and valve surfaces 19, 23, axial displacement of the valve 14 with respect to the bit 12, which may occur once the valve 14 begins to wear, is minimized. However, by increasing the taper angles ASB, ASV, the inside and outside diameters DSI, DSO increase by a greater rate for a given distance along the bit and valve axes 12a, 14a. As such, the axial length portion lRp, lEp of each surface section 19, 23 should not exceed a predetermined value in order to avoid having a maximum valve outside diameter DSO that is so much greater than the minimum bit inside diameter DSI, that the valve material fails or becomes permanently deformed during insertion of the valve 14 within the bit 12. Therefore, to provide both an increased value of the taper angles ASB, ASV (i.e., to reduce valve axial movement), prevent failure or permanent deformation of the valve 14, and provide a sufficient axial length of the zone of contact ZC, the bit retainer portion 16 and the valve engagement portion 20 of the second bit assembly construction are each formed with a plurality of conical surface sections 19, 23.
The bit assembly 10 of the present invention has a number of advantages over previous designs of the valve 14 and bit 12. By having a zone of contact ZC (see
It will be appreciated by those skilled in the art that changes could be made to the embodiments described above without departing from the broad inventive concept thereof. It is understood, therefore, that this invention is not limited to the particular embodiments disclosed, but it is intended to cover modifications within the spirit and scope of the present invention as defined in the appended claims.
This application is a 371 of PCT/US2006/016126, filed on Apr. 27, 2006, which claims the benefit of U.S. Provisional Patent Application 60/675,215, filed on Apr. 27, 2005.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2006/016126 | 4/27/2006 | WO | 00 | 10/29/2007 |
Publishing Document | Publishing Date | Country | Kind |
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WO2006/116646 | 11/2/2006 | WO | A |
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