The present invention relates to a method and apparatus for affixing a cylindrical member in a down-the-hole drill or hammer, often referred to in the industry as a DTH drill. In a one exemplary embodiment, the present invention relates to a method and apparatus for affixing a foot valve assembly in a DTH drill.
With reference to
Referring again to
An exhaust tube 14 is mounted within the counter bore 6e and extends out the upper end 6a of the bit 6 into the return chamber 12b. As the piston 7 approaches the lower position (
Referring once again to
The exhaust tube 14 is held in the bit counter bore 6e by way of an interference fit and also by virtue of the interaction of the humps 14a and cavities 6h. The undeformed original outer diameter of the exhaust tube 14 is slightly larger than the diameter 6f of the counter bore 6e. The exhaust tube 14 is forced into the counter bore 6e, which causes the exhaust tube 14 to deform. The shape memory of the plastic material in the exhaust tube 14 causes the exhaust tube 14 to expand against the wall of the counter bore 6e. This gives rise to a gripping force between the exhaust tube 14 and the wall of the counter bore 6e. The gripping force is a function of (e.g., proportional to) the pressure exerted by the exhaust tube 14 against the wall of the counter bore 6e, and also the surface area of contact between the exhaust tube 14 and the wall of the counter bore 6e.
One aspect of the present invention is recognition that while plastic exhaust tubes offer many advantages, a persistent problem has been that such exhaust tubes tend to loosen during their service life when compared to exhaust tubes made of aluminum, steel, or other suitable materials (collectively, “other suitable materials”). The embodiments of the present invention described below are primarily focused on an apparatus and method for securing a plastic exhaust tube in counter bore of a bit to reduce the likelihood that the exhaust tube will come loose during ordinary operation of the DTH drill. The invention is applicable, however, to securing substantially any cylindrical members within a component of a DTH drill in a bore or counter bore in the component.
In one embodiment, the invention provides a retaining assembly for a cylindrical member in a DTH drill that includes a component including a component bore having a component bore diameter, the assembly comprising: a cylindrical member having a cylindrical member outer diameter larger than the component bore diameter and including a cylindrical member bore defining a cylindrical member inner diameter, the cylindrical member having a cylindrical member rigidity; and a support sleeve having an outer sleeve diameter less than the cylindrical member inner diameter and inserted into the cylindrical member bore to form a cylindrical member and sleeve assembly, at least a portion of the support sleeve having a rigidity greater than the cylindrical member rigidity; wherein the cylindrical member and sleeve assembly is inserted into the component bore such that the cylindrical member deforms against the support sleeve to fit within the component bore, such that the cylindrical member is fixedly sandwiched between the support sleeve and the component bore.
In some embodiments, the component of the DTH drill includes a bit; the cylindrical member includes an exhaust tube; the cylindrical member bore includes a through bore in the exhaust tube; and the cylindrical member and support sleeve assembly defines a foot valve assembly for the DTH drill, the foot valve assembly being adapted to be alternatingly placed into and out of communication with at least one chamber of the DTH drill for the flow of motive fluid through the exhaust tube through bore.
In some embodiments, the cylindrical member and support sleeve assembly includes a gap between the support sleeve and the cylindrical member bore prior to insertion of the cylindrical member and support sleeve assembly into the component bore; and deformation of the cylindrical member during insertion into the component bore closes the gap and causes the cylindrical member to apply pressure to the support sleeve.
In some embodiments, the cylindrical member bore extends through the cylindrical member from a first end of the cylindrical member to a second end opposite the first end; the cylindrical member bore includes a smaller diameter portion between the first end and a transition point, and a larger diameter portion between the transition point and the second end; and the support sleeve is inserted into the larger diameter portion of the cylindrical member bore to form the cylindrical member and sleeve assembly.
In some embodiments, the cylindrical member includes a retaining rim; the retaining rim defines an opening having a smaller diameter than the outer sleeve diameter, such that upon insertion of the support sleeve into the cylindrical member bore, the retaining rim engages a portion of the support sleeve to resist removal of the support sleeve from the cylindrical member bore. In some embodiments, the support sleeve includes a beveled surface to facilitate insertion of the support sleeve through the opening defined by the retaining rim. In some embodiments, the support sleeve includes a cut-out that mates with the retaining rim upon insertion of the support sleeve into the cylindrical member bore. In some embodiments, the retaining rim is included in an end of the cylindrical member; and an end of the support sleeve is engaged by the retaining rim to maintain an end of the support sleeve adjacent the end of the cylindrical member. In some embodiments, the cylindrical member includes first and second opposite ends and the support sleeve includes first and second opposite ends; and the retaining rim is positioned within the cylindrical member bore such that neither of the first and second opposite ends of the support sleeve is adjacent either of the first and second opposite ends of the cylindrical member.
In some embodiments, a wall of at least one of the cylindrical member and support sleeve is tapered. In some embodiments, the component bore includes a shoulder against which both the cylindrical member and support sleeve abut upon insertion of the cylindrical member and support sleeve assembly into the component bore.
In some embodiments, the support sleeve includes a longitudinally-extending slit defined by longitudinally-extending free ends; and deformation of the cylindrical member upon insertion of the cylindrical member and support sleeve assembly into the component bore applies pressure on the support sleeve sufficient to bring the free ends into contact and close the longitudinally-extending slit; and contact of the free ends enables the support sleeve to resist additional pressure applied by the cylindrical member on the support sleeve such that additional deformation of the cylindrical member occurs after the free ends have come into contact.
In some embodiments, the support sleeve defines a non-circular cross-section and the cylindrical bore defines a circular cross-section; and upon insertion of the cylindrical member and support sleeve assembly into the component bore the support sleeve is forced into a circular cross-section under pressure applied by the cylindrical member. In some embodiments, the non-circular cross-section of the support sleeve defines an oval having a major axis and a minor axis; the support sleeve contacts a surface of the cylindrical member bore at the major axis of the support sleeve upon insertion of the support sleeve into the cylindrical member bore; and contact of the support sleeve and surface of the cylindrical member bore creates an interference fit between the support sleeve and the surface of the cylindrical member bore sufficient to resist removal of the support sleeve from the cylindrical member and sleeve assembly.
In some embodiments, the support sleeve includes a portion of first rigidity and a portion of second rigidity lower than the first rigidity; the portion of second rigidity deforms during insertion of the cylindrical member and sleeve assembly into the component bore; and the cylindrical member is fixedly sandwiched between the portion of first rigidity and the component bore. In some embodiments, the portion of second rigidity includes rigidity-reducing features. In some embodiments, the portion of second rigidity includes at least one of a slit, a hole, and castellations.
In another embodiment, the invention provides a retaining assembly for a cylindrical member in a DTH drill that includes a component including a component bore having a component bore diameter, the assembly comprising: a generally cylindrical member including a cylindrical member outer surface defining a cylindrical member outer diameter, and a cylindrical member inner surface defining a cylindrical member inner diameter, the generally cylindrical member having a cylindrical member rigidity; and a support sleeve including an outer surface defining a support sleeve outer diameter, at least a portion of the support sleeve having a rigidity greater than the cylindrical member rigidity; wherein a larger diameter portion of the support sleeve has an outer diameter larger than the inner diameter of a smaller diameter portion of the generally cylindrical member; wherein the support sleeve is adapted for insertion into the component bore to define a gap between at least a portion of the support sleeve outer surface and the component bore; wherein the generally cylindrical member is adapted for insertion into the gap between the support sleeve outer surface and the component bore; and wherein the generally cylindrical member is adapted to deform upon the smaller diameter portion of the generally cylindrical member being forced over the larger diameter portion of the support sleeve, such deformation of the cylindrical member filling the gap and fixedly sandwiching the generally cylindrical member between the support sleeve and the component bore.
In some embodiments, the component of the DTH drill includes a bit; the generally cylindrical member includes an exhaust tube; and the generally cylindrical member and support sleeve together define a foot valve assembly for the DTH drill, the foot valve assembly being adapted to be alternatingly placed into and out of communication with at least one chamber of the DTH drill for the flow of motive fluid through the exhaust tube. In some embodiments, the support sleeve includes a beveled surface to facilitate insertion of the generally cylindrical member into the gap. In some embodiments, the component bore is tapered; the outer and inner surfaces of the generally cylindrical member are tapered; and the outer surface of the support sleeve is tapered. In some embodiments, the component bore includes a shoulder against which at least the support sleeve abuts upon fixedly sandwiching the generally cylindrical member between the support sleeve and the component bore. In some embodiments, the support sleeve includes a portion of first rigidity and a portion of second rigidity lower than the first rigidity; the portion of second rigidity deforms during insertion of the generally cylindrical member into the gap; and the generally cylindrical member is fixedly sandwiched between the portion of first rigidity and the component bore.
In another embodiment, the invention provides a method for inserting a cylindrical member into a bore of a component in a DTH drill, the bore having a component bore diameter, the method comprising: (a) providing a cylindrical member including a cylindrical member bore and having a cylindrical member rigidity; (b) providing a support sleeve having an outer surface, at least a portion of the support sleeve having a rigidity greater than the cylindrical member rigidity; and (c) deforming the cylindrical member against the component bore and the outer surface of the support sleeve to fixedly sandwiched the cylindrical member between the support sleeve and the component bore.
In some embodiments, the method further comprises the step of (b′) inserting the support sleeve into the cylindrical member bore prior to step (c) to define a cylindrical member and sleeve assembly; and step (c) includes inserting the cylindrical member and sleeve assembly into the component bore. In some embodiments, step (b′) includes defining a gap between the outer surface of the support sleeve and the cylindrical member bore; and step (c) includes deforming the cylindrical member to close the gap and apply pressure to the support sleeve. In some embodiments, step (a) includes providing a retaining rim in the cylindrical member, the retaining rim defining an opening of smaller diameter than an outer diameter of at least a portion of the outer surface of the support sleeve; and step (b′) includes resisting removal of the support sleeve from the cylindrical member bore with the retaining rim. In some embodiments, step (b) includes providing a cut-out in the support sleeve; and resisting removal of the support sleeve from the cylindrical member bore includes engaging the cut-out of the support sleeve with the retaining rim. In some embodiments, providing a retaining rim includes positioning the retaining rim in an end of the cylindrical member; and resisting removal of the support sleeve includes maintaining an end of the support sleeve adjacent the end of the cylindrical member. In some embodiments, step (a) includes providing a cylindrical member having first and second opposite ends; step (b) includes providing a support sleeve having first and second opposite ends; and resisting removal of the support sleeve includes maintaining neither of the first and second opposite ends of the support sleeve adjacent either of the first and second opposite ends of the cylindrical member. In some embodiments, step (a) includes defining a circular cross-section with the cylindrical member bore; step (b) includes defining a non-circular cross-section with the outer surface of the support sleeve; and step (c) includes forcing the support sleeve outer surface into a circular cross-section under pressure applied by the cylindrical member deforming against the support sleeve. In some embodiments, step (b) includes defining with the cross-section of the outer surface of the support sleeve an oval having a major axis and a minor axis; step (b′) includes contacting the cylindrical member bore with the support sleeve at the major axis to create an interference engagement between the support sleeve and the cylindrical member bore sufficient to resist removal of the support sleeve from the cylindrical member bore.
In some embodiments, at least one of steps (a) and (b) includes providing a tapered surface in at least one of the cylindrical member and support sleeve. In some embodiments, the component bore defines a shoulder at its bottom; and step (c) includes abutting at least one of the cylindrical member and support sleeve against the shoulder in the component bore. In some embodiments, step (b) includes providing a longitudinally-extending slit defined by longitudinally-extending free ends in the support sleeve; step (c) includes deforming the cylindrical member to apply pressure on the support sleeve sufficient to bring the free ends into contact and close the longitudinally-extending slit; and step (c) further includes continuing deformation of the cylindrical member against the support sleeve after the free ends are in contact.
In some embodiments, step (b) includes providing a support sleeve that includes a portion of first rigidity and a portion of second rigidity lower than the first rigidity; wherein step (c) includes deforming the portion of second rigidity and fixedly sandwiching the cylindrical member between the portion of first rigidity and the component bore. In some embodiments, step (b) further includes providing the portion of second rigidity with rigidity-reducing features in the support sleeve. In some embodiments, step (b) further includes providing at least one of slots, holes, and castellations in the portion of second rigidity.
In some embodiments, step (a) includes providing a cylindrical member having a generally cylindrical portion, and defining in the cylindrical member bore a smaller diameter portion; step (b) includes providing a larger diameter portion of the outer surface of the support sleeve, the larger diameter portion having a diameter larger than the smaller diameter portion; step (c) includes inserting the support sleeve into the component bore to define a gap between at least a portion of the support sleeve outer surface and the component bore, inserting the generally cylindrical portion into the gap, and deforming the generally cylindrical portion upon the smaller diameter portion of the cylindrical member bore being forced over the larger diameter portion of the support sleeve. In some embodiments, the component bore is tapered; step (a) includes providing tapered inner and outer surfaces of the generally cylindrical portion; and step (b) includes providing a tapered outer surface of the support sleeve.
Other aspects of the invention will become apparent by consideration of the detailed description and accompanying drawings.
Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways.
Certain terminology is used in the following description for convenience only and is not limiting. The words “right,” left,” “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.
We have identified that reasons for the loosening of plastic exhaust tubes in the counter bore include creep (also called “relaxation”) and contraction (collectively “material property change”) of the plastic material during the service life of the plastic exhaust tube. Creep is the tendency of a solid material to slowly move or deform permanently under the influence of stresses. Creep occurs as a result of long term exposure to levels of stress that are below the yield strength of the material. Creep increases with increased temperatures, and is more severe in materials that are subjected to heat (e.g., near the melting point of the material) for long periods. The rate of deformation arising from creep is a function of material properties, exposure time, exposure temperature, and the applied structural load. So, for a given plastic exhaust tube, the rate of creep is a function of temperature and applied structural load.
The applied structural load on an exhaust tube, once installed, arises from the interference fit with the counter bore. Paradoxically, the tighter an exhaust tube is fit into the counter bore of a bit (i.e., the tighter the interference fit and higher the resultant pressure), the faster it will loosen because of the resulting pressure-induced creep in the plastic material. With respect to temperatures, the higher the operating temperatures are within the DTH drill, the more likely that creep rate will increase in the exhaust tube.
Turning now to the several embodiments of the invention, all embodiments are illustrated and described for use in a DTH drill having the basic components of that illustrated in
In all embodiments discussed below, an exhaust tube is reinforced on an inner surface with a support sleeve and the combination of the exhaust tube and support sleeve is referred to as a “foot valve assembly.” Other embodiments may involving a cylindrical member that is not an exhaust tube, in which case the combination of the cylindrical member and the support sleeve may be referred to as a “cylindrical member and sleeve assembly” or a “sleeve-tube assembly.” While exemplary exhaust tubes are constructed of Delrin® plastic material, the exhaust tube may be constructed of other suitable polymers, copolymers, ultra high molecular weight (UHMW) materials, composite materials (e.g., having different materials for the upper portion and lower portion), metals (e.g., softer metals that would be less rigid than the material of which the support sleeve is constructed) and other materials that will meet the specifications of the invention described in this specification and that are within the scope of the appended claims. The exhaust tube may include a stiffer upper portion to facilitate insertion of the foot valve assembly into the counter bore 6e. The stiffer upper portion may be provided by thickening the wall of the upper portion or by constructing the exhaust tube of a composite material that has a higher rigidity in the upper portion than in a lower portion. The exhaust tubes can be machined, cast, or molded for example.
Other suitable materials for the support sleeve include, but are not limited to, steel, aluminum, copper, glass-filled polymers and any other materials that will meet the specifications of the invention described in this specification. Generally desirable material properties for the support sleeve are high Young's modulus, low weight, good thermal stability, and high rigidity or stiffness. In all embodiments, at least a portion of the support sleeve is more rigid than the exhaust tube such that the exhaust tube can deform in the space between the support sleeve and the counter bore wall of the bit. Variations on the illustrated and described embodiments are within the scope of the invention, including but not limited to variations on one embodiment that includes features of another embodiment.
Additionally, although the embodiments discussed in this specification relate to the invention embodied in a foot valve assembly, the invention can be applied to substantially any cylindrical part inserted into a bore in a component of a DTH drill. For example, the invention may be applied to an apparatus and method for installing the air guide, air distributor, or control rod components of a DTH drill. The term “cylindrical member” is intended to include all types of tubes and cylinders, whether they include a through-bore, counter bore, or a blind bore.
It will be understood that in this specification, terms such as upper end, lower end, upper portion, lower portion, inner surface, outer surface, inner diameter, and outer diameter when used with reference to the exhaust tube, support sleeve, and foot valve assembly refer to the ordinary meaning of such terms corresponding to portions of the components as illustrated in the accompanying drawings. For the sake of simplifying the drawings, reference numerals may not be used to identify all such terms when they are deemed apparent to one of ordinary skill in the art. Additionally, it will be understood that a component having inner and outer surfaces (such as the support sleeve and exhaust tube) defines a wall between the inner and outer surfaces even though the wall may not be explicitly called out and labeled in the drawings, and that a bore (such as counter bore 6e) is necessarily bounded by a bore wall.
A first embodiment of a foot valve assembly 100 is illustrated in
The support sleeve 125 is generally cylindrical, and includes an upper end 165 defining a beveled surface 170 that defines an angle of zero to thirty degrees (0°-30°) with respect to the centerline Ac of the sleeve 125, such that the outer diameter of the support sleeve 125 increases from the upper end 165 to a bottom end 175 of the beveled surface 170. In one representative embodiment, the angle is between zero to ten degrees (0°-10°), and in another embodiment, the angle is two-and-a-half degrees (2.5°). The beveled surface 170 facilitates insertion of the support sleeve 125 into the exhaust tube 120 through the retaining rim 155. The outer diameter 180 of the support sleeve 125 below the beveled surface 170 (referred to simply as the outer diameter of the support sleeve 125) is slightly less than the inner diameter 150 of the exhaust tube 120. At its lower end, the support sleeve 125 includes a cut-out 185 in its outer surface that has a depth and height sufficient to accommodate the retaining rim 155 of the exhaust tube 120. In other embodiments, the cut-out 185 may be between the upper and lower ends of the support sleeve 125 and the retaining rim 155 may be between the upper and lower ends of the bore of the exhaust tube 120. An inner diameter 190 of the support sleeve 125 is about equal to the inner diameter 140 of the upper portion 130 of the exhaust tube 120 and the diameter 6d of the bit bore 6c. The support sleeve 125 may be made of, for example, steel having a hardness of 20-55 HRc, and preferably 30-45 HRc. The thickness of the support sleeve in the illustrated embodiment should be 1.0-5.0 mm, and preferably 1.5-2.5 mm.
The first embodiment of the foot valve assembly 100 is assembled by inserting the support sleeve 125 into the lower portion 135 of the exhaust tube 120 through the retaining rim 155. The retaining rim 155 deflects as the support sleeve 125 is inserted, and snaps back to its original condition once the lower edge of the support sleeve 125 has cleared the retaining rim 155, such that the retaining rim 155 is received within the cut-out 185. The retaining rim 155 resists the support sleeve 125 falling out of the exhaust tube 120 during handling of the foot valve assembly 100. The foot valve assembly 100 shall be referred to as being in its undeformed state before it is installed in the counter bore 6e. In the undeformed state, a small gap 195 (see
With reference now to
As used herein, the term “deform” and its derivatives includes elastic and plastic deflection and yielding of a material, whether by mechanical, thermal, or other loading. The load (mechanical, thermal, or other) at which a material will deform is referred to herein as the threshold load. Upon application of the threshold load, the lower portion 135 of the exhaust tube 120 can only deform a limited amount before the gap 195 is filled. Once the gap 195 is filled, the exhaust tube 120 will deform elastically as well as plastically. The stress state for much of the lower portion 135 of the sleeve 120 (i.e., most of the portion sandwiched between the support sleeve 125 and the counter bore wall 6e) is hydrostatic, but the top and bottom ends of the lower portion 135 of the exhaust tube 120 can still yield plastically after the gap 195 is filled.
Deformation of the exhaust tube 120 against the support sleeve 125 and the counter bore 6e gives rise to an interference fit which includes a frictional interface on the inner and outer surfaces of the exhaust tube 120. Once the foot valve assembly 100 is fully installed, the frictional interface between the exhaust tube 120 outer surface and the counter bore 6e wall is sufficient to resist removal of the foot valve assembly 100 from the counter bore 6e during ordinary operation of the DTH drill, and the exhaust tube 120 may be said to be “fixedly sandwiched” between the support sleeve 125 and the wall of the counter bore 6e. The rigid support afforded to the inner surface of the lower portion 135 of the exhaust tube 120 by the support sleeve 125 resists creep, relaxation, and other material property changes of the exhaust tube 120.
In
It should be noted that this embodiment can also be used in a traditional bit, either having straight walls that are parallel to the centerline Ac as in
With reference to
The exhaust tube 620 used with this embodiment may be substantially similar to any of the above-identified exhaust tubes in other embodiments, and may or may not include a retaining rim (similar to retaining rim 155 in
The purpose of the fingers 810 and gaps 815 is to weaken the lower portion of the support sleeve or reduce its rigidity. In this regard, the support sleeve 825 may be said to have a portion of first rigidity (the upper portion) and a portion of second rigidity (the lower portion) that has lower rigidity or is less rigid than the portion of first rigidity. The portion of second rigidity is preferably still more rigid than the exhaust tube 820. Reducing the rigidity of the lower portion of the sleeve may facilitate insertion of the foot valve assembly 800 into the counter bore 6e, where the friction and interference fit between the exhaust tube 820 and the counter bore 6e becomes too great and causes undesired premature yielding of the exhaust tube 820, or results in the foot valve assembly 800 becoming stuck in the counter bore 6e before the foot valve assembly 800 is fully inserted. The castellations permit the lower portion of the support sleeve to deflect or even yield to reduce the interference fit and friction between the lower portion of the exhaust tube 820 and the counter bore 6e.
In other embodiments, the lower portion of the support sleeve may be weakened or made less rigid to achieve a similar result to the above-identified castellations by providing a plurality of holes or other rigidity-reducing features in the lower portion of the support sleeve. Such holes may have the additional functionality of facilitating removal of the support sleeve 825 from the exhaust tube 820 with a hook or the like.
As with the eighth embodiment, this embodiment addresses the potential occurrence of the exhaust tube 920 becoming stuck only partially inserted into the counter bore 6e due to high frictional engagement of the lower portion of the exhaust tube 920 in the counter bore 6e. This embodiment does not resist yielding of the exhaust tube 920 below the support sleeve 925. If the foot valve assembly 900 meets significant frictional resistance during insertion of the foot valve 900 into the counter bore 6e, the lower portion of the exhaust tube 920 can yield to permit continued insertion of the foot valve assembly 900. The support sleeve 925 will resist deformation of the exhaust tube wall between the support sleeve and the counter bore 6e once the foot valve assembly 900 is fully inserted.
Thus, the invention provides, among other things, a method and apparatus for securing a cylindrical member in a bore in a component of a DTH drill. Various features and advantages of the invention are set forth in the following claims.
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