The present invention relates to a down-the-hole drill (“DHD”) hammer. In particular, the present invention relates to a DHD hammer having a sliding exhaust check valve assembly and more particularly, a sliding exhaust check valve assembly that combines supply and exhaust check valves into a single unit operation.
Typical DHD hammers utilize what is known as “reactive” seals for sealing the DHD hammer's interior from its exterior environment, such as water and debris. The seals are known as “reactive” seals because they require the movement of exhaust flow to displace or open flow passageways within the DHD hammer. However, such DHD hammers also require that exhaust pressures be minimized for proper functioning of the DHD hammer. As such, the level of reactive forces/pressures for the “reactive” seals were also minimized, thereby potentially negatively impacting the “reactive” seal's effectiveness.
A DHD hammer, such as the present invention, having a sliding exhaust check valve addresses the foregoing limitations of reactive seals.
In a preferred embodiment, the present invention provides a down-the-hole drill hammer comprising a housing, a backhead and a tubular sliding check valve assembly. The backhead is positioned at a proximal end of the housing and includes a distal end, a threaded male proximal end, a supply inlet and an exhaust port. The supply inlet receives a supply of working fluid to an interior of the backhead. The exhaust port provides for communication between the interior of the backhead and an exterior of the backhead. The tubular sliding check valve assembly is within the housing proximate to the backhead. The sliding check valve assembly includes a distributor, a sliding valve, and a biasing member. The distributor has a central opening, an aperture extending through the distributor and offset from the central opening for allowing the passage of working fluid through the distributor, and an exhaust gallery for communicating between the central opening and the exhaust port. The sliding valve is slidable along the central opening and movable between a closed position and an open position. The sliding valve has a closed proximal end, an open distal end, and an opening about a midsection of the sliding valve. In the closed position, a proximal end of the sliding valve sealingly engages the supply inlet and a distal end of the sliding valve sealingly engages an inlet opening of the exhaust gallery. In the open position, the sliding valve is offset from the supply inlet, the openings of the sliding valve are in communication with the exhaust gallery, and the supply inlet is in communication with the aperture extending through the distributor. The biasing member biases the sliding valve.
In accordance with another preferred embodiment, the present invention provides a down-the-hole drill hammer comprising a housing, a backhead, and a tubular sliding check valve assembly. The backhead is positioned at a proximal end of the housing and includes a distal end, a threaded male proximal end, a supply inlet for receiving a supply of working fluid to an interior of the backhead, an exhaust port for communicating between the interior of the backhead and an exterior of the backhead, a tubular distal end, and a tapered midsection interior in communication with the supply inlet. The tapered mid section interior includes a frustroconical section adjacent the supply inlet, and a tubular section adjacent the frustroconical section. The tubular sliding check valve assembly is housed within the housing proximate to the backhead. The sliding check valve assembly includes a distributor, a sliding valve, and a biasing member. The distributor has a central opening, an aperture extending through the distributor in an axial direction and offset from the central opening for allowing the passage of working fluid through the distributor, and an exhaust gallery for communicating between the central opening and the exhaust port. The sliding valve is slidable along the central opening and movable between a closed position and an open position. The sliding valve includes a closed proximal end, an open distal end, and an opening about a midsection of the sliding valve. The biasing member biasing the sliding valve to the closed position. In the closed position, a proximal end of the sliding valve sealingly engages the supply inlet and a distal end of the sliding valve sealingly engages an inlet opening of the exhaust gallery. In the open position, the sliding valve is offset from the supply inlet, the openings of the sliding valve are in communication with the exhaust gallery, and the supply inlet is in communication with the aperture extending through the distributor.
In accordance with yet another preferred embodiment, the present invention provides a down-the-hole drill hammer that includes a housing, a backhead, a tubular sliding check valve assembly, a biasing member, a solid-core piston and a seal. The backhead is located at a proximal end of the housing and includes a supply inlet for receiving a supply of working fluid to an interior of the backhead. The tubular sliding check valve assembly is housed within the housing and located proximate the backhead. The sliding check valve assembly includes a distributor and a sliding valve slidable along the distributor. The sliding valve has a closed proximal end, an open distal end, an opening about a midsection of the sliding valve, and an inwardly extending flange, wherein the inwardly extending flange has a distally facing surface area. The biasing member biases the sliding valve to sealingly engage the closed proximal end to the supply inlet. The seal is located proximate a distal end of the housing between the solid-core piston and the housing.
In accordance with another preferred embodiment, the present invention provides a down-the-hole drill hammer that includes a housing, a backhead, a tubular sliding check valve assembly, a biasing member, a solid-core piston, a seal and a drive chamber. The backhead is located at a proximal end of the housing and includes a supply inlet for receiving a flow of supply pressure to an interior of the backhead. The tubular sliding check valve assembly is housed within the housing and located proximate the backhead. The sliding check valve assembly includes a distributor and a sliding valve slidable along the distributor. The sliding valve has a closed proximal end, an open distal end, and an opening about a midsection of the sliding valve. The biasing member biases the sliding valve to sealingly engage the closed proximal end to the supply inlet. The seal is located proximate a distal end of the housing between the solid-core piston and the housing. The driver chamber is positioned between the backhead and the solid-core piston. The closed proximal end of the sliding valve sealingly engages the supply inlet while the solid-core piston sealingly engages the seal proximate the distal end of the housing when a flow of supply pressure entering the down-the-hole drill hammer is discontinued to maintain an elevated pressure within the drive chamber.
The foregoing summary, as well as the following detailed description of the invention, will be better understood when read in conjunction with the appended drawings. For the purpose of illustrating the invention, there are shown in the drawings embodiments that are presently preferred. It should be understood, however, that the 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 “right,” “left,” “upper,” and “lower” designate directions in the drawings to which reference is made. For purposes of convenience, “distal” is generally referred to as toward the drill bit end of the DHD hammer, and “proximal” is generally referred to as toward the backhead end of the DHD hammer, as illustrated in
In accordance with a preferred embodiment of the present invention, there is shown a DHD hammer that includes a housing 12, a backhead 14 and a tubular sliding check valve assembly 46, as best shown in
The housing 12 is generally cylindrical and configured to receive a portion of the backhead 14 and a portion of a drill bit 15, as best shown in
The backhead 14 is generally configured, as shown in
The tubular sliding check valve assembly 46, is shown in
Referring to
The configuration of the tapered midsection 33 in combination with the sliding valve 62 (shown in
The overall diameter of the sliding valve 62 is sized to provide a relatively small clearance of flow around the sliding valve 62 until an upper portion 62a (i.e., a frustroconical portion) of the sliding valve 62 (
In general, the inlet passageway 41 is in communication between the supply inlet 26 and the apertures 52 of the distributor 48 when the sliding valve 62 is in the open position. The inlet passageway 41 is formed between the surfaces of the chamfered proximal end of the sliding valve 62 and at least the frustroconical wall 34 and tubular wall 36 of the interior 28 of the backhead 14.
The expandable inlet passageway 41 advantageously ensures that the supply of working fluid volumes into the backhead 14 adequately compresses or forces the biasing member 108 to move the sliding valve 62 to the fully open position (
The tubular distal end 44 of the backhead 14 is configured, as best shown in
The backhead 14 also includes a flange 45 that extends radially inwardly from an outside surface of the mid portion 35 to the distal end 20 of the backhead 14. As best shown in
The distributor 48, is best shown in
The distributor 48 further includes an aperture 52 that extends through the distributor 48 in an axial direction. The aperture 52 is radially offset from the central opening 50, as shown in
The distributor 48 also includes an exhaust gallery 54, as shown in
The distributor 48 preferably includes glands 57a-d that each receives a respective seal, as further described below. Gland 57a receives a seal 94 (
The sliding valve 62, is best shown in FIGS. 2 and 11-14. The sliding valve 62 is assembled within the interior 51 of the distributor 48, as best shown in
The sliding valve 62 includes a closed proximal end 64 (
In general, the sliding valve 62 includes an upper portion 62a and a main body portion 62b. The upper portion 62a is generally configured as a frustroconical portion or as a chamfered proximal end. The main body portion 62b is generally configured as a tubular portion extending distally from the upper portion 62a. The sliding valve 62 is configured with a hollow interior 62c and a through hole 70 that extends through a proximal end of the main body portion 62b. The through hole 70 is configured to receive a dowel 76 (
The assembly of the sliding valve 62 within the DHD hammer 10, owing to the openings 68 of the sliding valve 62 being in communication with the exhaust ports 30, advantageously ensures that the interior 62c is substantially at exhaust pressure or the pressure external to DHD hammer 10, which is significantly less (e.g., at about atmospheric pressure or about 0-50 p.s.i.) than the supply pressure (e.g., about 300-350 p.s.i. or about 150 to 450 p.s.i.) being fed to the DHD hammer 10 via the supply inlet 26. Thus, because the pressure within the sliding valve 62 is maintained at lower pressures, relative to the supply pressure of working fluid volumes fed to the DHD hammer 10, the tubular sliding check valve assembly 46 advantageously ensures that the supply pressure functions as a bias pressure to urge the tubular sliding check valve assembly 46 to the open position.
The biasing member 108 is assembled to the tubular sliding check valve assembly 46 so as to be positioned between the sliding valve 62 and the distributor 48, as best shown in
Preferably, the biasing member 108 is configured to provide an overall restoring force to the sliding valve 62 sufficient to retain an elevated pressure of at least 35 p.s.i. within the DHD hammer 10. This can be accomplished with a biasing member 108 the provides a net restoring force in lbs. that is about 90% to 125% of the numerical valve of the DHD hammer's internal diameter squared. The term “net restoring force” means the overall force applied to the sliding valve 62 by the biasing member 108 minus any counterforces acting on the sliding valve 62, such as frictional forces generated by seals on the sliding valve 62. Configuring the biasing member 108 to have a net restoring force of about 90% to 125% of the numerical valve of the DHD hammer's internal diameter squared advantageously allows the biasing member 108 to move the sliding valve 62 to the closed position (
Thus, for example, Table 1 illustrates the preferred net restoring force ranges for the biasing member 108 over a range of DHD hammer 10 bore sizes.
During operation of the DHD hammer 10, the flow of working fluid or supply pressure pressurizes the internal areas of the DHD hammer 10 to elevated pressures above 35 p.s.i., and typically operates the DHD hammer 10 at pressures from about 150 p.s.i. to 450 p.s.i. Thus, with a biasing member 108 having a sufficient net restoring force, the biasing member 108 allows the DHD hammer 10 to partially retain the elevated pressures within the DHD hammer's internal areas, such as the drive chamber 18 at elevated pressures. Preferably, the internal areas of the DHD hammer 10 are maintained at a pressure of at least 35 p.s.i. by the proper balancing of the net restoring force of the biasing member 108 on the sliding valve 62.
The internal areas of the DHD hammer 10, such as the drive chamber 18, are sealed off, and preferably hermetically sealed, owing to the combination of the solid-core piston 16 and the seal 17, when the DHD hammer 10 is in a drop-down position. The DHD hammer 10 is sealed off and moved to the drop-down position upon the flow of supply pressure feed to the DHD hammer 10 being discontinued i.e., stopped or reduced to a non-actuating level, such as 35 p.s.i.
The seal 17 is best shown in
The distally facing surface area 63c′ is preferably about 2-4% of the numerical valve of the DHD hammer's internal diameter squared. Table 2, illustrates the preferred distally facing surface area 63c′ over a range of DHD hammer bore sizes.
The combination of the distally facing surface area 63c′ of the sliding valve 62′ and the net restoring force of the biasing member 108 advantageously allows the DHD hammer 10 to retain elevated pressures within its internal areas at or above 35 p.s.i. upon an intermittent stop of the DHD hammer 10. This is accomplished by the proper balancing of the net restoring force of the biasing member 108 on the sliding valve 62′ and the bias area 63c′ of the sliding valve 62′ in combination with the expandable inlet passageway 41 of the backhead 14.
Referring to
The DHD hammer 10 also includes a belleville washer 80 for facilitating the mounting of the tubular sliding check valve assembly 46 within the housing 12 and the backhead 14. The belleville washer 80 is configured, as best shown in
The inner housing 12c is preferably a separate component from the rest of the housing 12. The structure, operation and assembly of the inner housing 12c is known in the art and therefore a detailed description of the inner housing 12c is not necessary for complete understanding of the present invention. However, as best shown in
A plurality of splines 15a are formed about the outer surface of the inner housing 12c that each connect a through hole 13 of the first row 13a to a through hole 13 of the second row 13b. Each spline 15 provides fluid communication for the flow of fluid between the through holes 13 of the first and second rows 13a, 13b. A plurality of splines 15b are also formed about the outer surface of the inner housing 12c that are each in fluid communication with the through holes 13 of the third row 13c. Each spline 15b allows for fluid to flow around the exterior of the inner housing 12c. As such, the splines 15b allow for the flow of working fluid volumes to flow from the drive chamber 18 though the through holes 13 of either the first, second or third row 13a-c to a reservoir chamber 18a (
Such features of the through holes 13 and splines 15a,15b of the inner housing 12c form part of the DHD hammer's porting system. The porting features of a DHD hammer function to move working fluid volumes between the DHD hammer's drive chamber 18, reservoir chamber 18a and return chamber 18b to reciprocatively move the DHD hammer's piston 16. In other words, the flow of working fluid volumes from the supply inlet 26, check valve assembly 46, drive chamber 18, reservoir chamber 18b and return chamber 18b, all function to drive the operation of the DHD hammer 10.
The biasing member 108 biases the sliding valve 62 to the closed position in the absence of a supply of working fluid volumes being fed through the supply inlet 26. The closed position is illustrated in
The open position of the tubular sliding check valve assembly 46, is best shown in
Referring back to
The DHD hammer 10, as discussed above has been described and shown as including a solid-core piston 16. That is, the solid-core piston 16 lacks any through hole or central opening that extends completely through the piston, such as in the axial direction. However, the sliding check valve assembly 46 of the DHD hammer 10 can alternatively be used with any conventional piston having a central through hole that extends axially through the piston to allow exhaust through the piston and drill bit.
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 by the appended claims.
The present application is a continuation-in-part of pending U.S. patent application Ser. No. 12/361,263, filed Jan. 28, 2009, entitled “Down-the-Hole Drill Reverse Exhaust System,” the entire disclosure of which is hereby incorporated herein by reference.
Number | Date | Country | |
---|---|---|---|
Parent | 12361263 | Jan 2009 | US |
Child | 12909495 | US |