This invention relates to portable driving devices and in particular portable driving devices adapted for permanently driving stakes, survey flags, or posts, or the like, of varying sizes and shapes, into the ground, that are powered by a pressurized fluid. This invention also relates to a valve control assembly adapted for a portable driving device wherein a spool valve is controlled by a rod that runs through the middle of the spool valve. The invention also relates to a handle assembly adapted for a portable driving device wherein safety switches in series control delivery of pressurized fluid to the driving device valve control assembly.
The invention may be related to subject matter disclosed in the following U.S. Pat. Nos. 2,703,479; 3,712,389; 4,665,994; 4,984,640; 5,819,857; 6,182,772; 6,571,885; 6,776,242; 6,889,777; 6,932,166; 7,152,694; and 7,252,158, and U.S. Patent Application Publication 2002/0195273, which are hereby expressly incorporated by reference in their entireties.
The present invention provides a portable reciprocating driving device which may include a valve control assembly and a pressurized fluid control assembly. Understanding the driving device from the reading of this document, may be facilitated by reference to the “Parts List” toward the end of this document. The improved driving device preferably comprises an inner rectangular sleeve (IRS) open at its lower end and closed at its upper end adapted to receive, for example, the upper vertical end of a reflective roadside post, which enable vehicle operators to track the location of the road relative to the reflective post with intention, typically, to drive the post permanently into the ground in the vicinity of the road's shoulder or thereabout. The IRS lower end opening and inner sleeve cross-sectional shape are adapted to receive such a sign or post or similar objects, including signs or posts or similar objects that are reflective (hereinafter inclusively referred to as “post”) with a cross-sectional shape that is typically and in this case as well is preferably rectangular, which allows the post to be fully inserted into the IRS such that the top end of the post engages the inside top of the IRS. The device also includes an outer rectangular sleeve (ORS) open at its lower end and closed at its upper end adapted to receive and securely and slidably engage the IRS—ergo the rectangular cross-sectional shape.
Cross-sectional shapes of the inner and outer sleeves need to be compatible with each other and the inner sleeve has a cross-sectional shape compatible with the top end of the object to be driven by the device. Therefore, it must be understood that the shape of the sleeves could be of varying cross-sectional shape. As long as the inner sleeve can receive the top of the object to be driven such that it can be effectively driven by the outer sleeve impacting the inner sleeve and the portion of the respective sleeves that are slidably engaged—the subject invention, and its alternative embodiments, will be functional within the scope of this specification.
The device also includes: a fluid power cylinder (FPC) releasably affixed to the ORS; and a base block (BB) releasably affixed to the IRS with a valve control rod (VCR) releasably affixed thereto. The device also includes a fluid power cylinder connecting rod (FPCCR) releasably affixed to the BB at the lower end of the FPCCR and affixed to fluid power cylinder piston (FPCP) (not illustrated) at its upper end, wherein FPCP resides and reciprocates within the FPC.
The device also includes a valve box (VB) adapted to sealably permit the VCR and FPCCR to pass therethrough wherein the VCR controls a spool valve mechanism, and extends through the spool valve (which is disposed in the VB), which alternately directs pressurized fluid, from an external source into opposite sides of the FPCP (which is disposed in the FPC), thereby creating reciprocating motion between the ORS and IRS 30. The VB is adapted to be self cleaning in that it expels the pressurized fluid, preferably air (or a functional equivalent thereof), from alternating sides of the VB cylindrical chamber which houses the spool valve mechanism therein without the need for a designated exit port or ports. The device also includes a nut, spring, and washer which are preferably respectively located at the upper end of the VCR and preferably a spring and washer are respectively located at the lower end of the VCR—intermediate to the VB and BB.
The device may also include, fixed to the lower end of the IRS, a handle assembly (HA). The upper end of the post, which is intended to be hammered so that the lower end of the post may be driven into the ground, is inserted into the open lower end of the IRS until it engages the upper inner closed end of the IRS, the HA may control the delivery of fluid to the VB, which is in effect an ON/OFF switch for the portable driving device. Each handle of the HA includes a switch which opens a valve which is biased closed when pressurized. When each handle switch is activated pressurized fluid is delivered from an external source to the VB.
The HA may also include a fluid actuated means for engaging and securing the IRS to the upper portion of the post (not shown in Figures). For example the second handle switch may deliver pressurized fluid to both the VB and a means for securing the IRS to the post, such means being known and which may include providing a pin which is biased in a retracted position and which, when pressurized, presses the top of the post to an inner surface of the IRS. However, alternatively the weight of the device, and the operator's ability to hold the device on the post, which in turn may stabilize the driving device IRS in relationship to the post (and the ORS during operation) and which may keep the inner closed end of the IRS sufficiently engaged with the top of the post during operation—that is, when the device is pounding the post into the earth as the reciprocating motion of the ORS relative to the IRS.
The present invention is accordingly adapted and calibrated to drive the post into the ground by generally keeping the inner closed end of the IRS engaged with the top of the post wherein the VB control of pressurized fluid creates reciprocating motion between the IRS and the ORS wherein the top closed end of the IRS receives repetitive reciprocating impact blows from the inner closed end of the ORS thereby driving the post into the earth.
A preferred embodiment of a device for power driving objects will now be illustrated and disclosed. The following description will also include alternative embodiments of the preferred embodiment. The portable driving device 10 is illustrated in the Figures and Drawings (listed above) and is comprised of the parts listed in “Parts List.” The device is adapted to drive a post, or generally any elongated article, into the ground or other medium as desired. The preferred embodiment, however, is adapted to drive a post with substantially rectangular cross-sectional shape which substantially fits within such a rectangular space defined by the driving device—specifically IRS 30. The preferred embodiment disclosed and illustrated is specifically adapted to drive road-side posts (which are typically used to support “road-signs”) common along the soft shoulders, or similar features, of rural roads. Notwithstanding, the inventive embodiments disclosed herein are equally applicable to a portable driving device adapted to drive a post or an object with a substantially round cross-sectional shape, square cross-sectional shape or for that matter may be adapted for any shape. IRS 30 and ORS 20 merely need to be adapted to this cross-sectional shape—the inventive embodiments disclosed herein as they pertain to the mechanisms that generate reciprocating movement between the ORS 20 and the IRS 30 may be applied to a variety of sizes and shapes of the post and the energy required to drive them into a medium such as soil.
The portable power portable power driving device 10 may utilize an innovative valve control mechanism which is particularly useful for reciprocating devices powered by fluids including pneumatic devices powered by compressed air.
The innovative portable power portable power driving device 10 may utilize an innovative switch control mechanism which when properly utilized may provide for a safe power driving device.
Referring to
As noted above, ORS 20 includes an open lower end 17 and a closed upper end 18 wherein IRS 30 and ORS 20 are adapted to be slidably engaged. Such an engagement can be achieved by many means known in the art including matching the respective cross-sectional shapes, material specifications and dimensional tolerances, of IRS 30 and ORS 20 illustrated and described herein.
The elongated cylindrical FPC 41, with a round cross-sectional shape, may be vertically aligned with ORS 20 and fixed to an upper end 11 (referencing “UP” in
VB 54 is illustrated in detail in
VB 54 includes a fluid connector, preferably a pneumatic connector 55, which can be sealably connected to a portable air, or fluid, source such as a small portable air compressor of the type that is well-known in the art. The lower end 23 of FPC 41 is fixed to the approximate middle of the outside top surface 20a of ORS 20 at VB 54. VB 54 includes means for alternately directing, via the spool valve, fluid to the interior volume 24 of the upper end of FPC 41. Fluid is directly delivered to the interior volume of the lower end 23 of FPC 41 from VB 54.
VB 54 may also include four threaded chambers (or holes) 502 which provide means by which VB 54 may be releasably affixed to ORS 20. One means therefore would be with four threaded bolts which may extend through the four chambers 502 (
FPCCR 42 is releasably affixed to FPCP 43, the latter component illustrated in
Both FPCCR 42 and the VCR 51 pass through the body of VB 54. The means for sealing this interface is well-known in the art.
With reference to
The portable power driving device 10 is calibrated so that the impact load is delivered prior to FPCP 43 hitting the ceiling of the interior volume 24 of the upper end of FPC 41 and prior to VB 54 hitting BB 52. The device is calibrated so the impact load is delivered whereupon VCR 51 engages the spool valve 57 in VB 54 and fluid is directed back to the interior volume 24 of the upper end of FPC 41 and the cycle is repeated.
When the portable power driving device 10 is vertically oriented and a vertically oriented post has been engaged at its upper end by the inner closed end of IRS 30, and the vertically oriented post has been engaged into the soil or a similar medium at its lower end—then the post is driven downward into the soil or similar medium.
Notably, the portable power driving device 10 does not require IRS 30 to be fixed to the post. Although the driving device is small and light-weight, its weight, in combination with the strength of an average user, enable the secure installation of a post without the need for means for removable fixing IRS 30 to the post. In one embodiment of the subject invention components are made of aluminum, with the exception of impact surfaces or components, wherein the device will weigh approximately 12 pounds, whereas an all steel unit will weigh approximately 20 pounds. The portable driving device 10 economically allows for such low weights vis-à-vis the prior art.
Preferably, fixed to the lower end 17 of IRS 30 is a handle assembly HA 60, shown in
Preferably, the HA 60 includes two handle bars 61a and 61b to be gripped firmly by the user—a 0.75 inch O.D. is preferred. Sponge handle grips are also preferably provided on the handle bars, for ergonomically absorbing the shock associated with the reciprocating motion and impact loads delivered. For example, bicycle handle bar grips or handle bar tape, known in the art, are designed for such approximate handle O.D. sizing. At the upper ends of the handles are the switches 62a and 62b, referred to herein as “hand switches,” which are easily thumb activated. Preferably the portable power driving device 10 is not activated, i.e. air is not delivered to VB 54, until both hand switches are engaged. Thus when either hand switch is disengaged, air delivery to VB 54 is terminated. Means for providing for fluid communication between the hand switches and the supply of air to VB 54 are well-known in the art.
Alternatively, the hand switches of HA 60 may obtain the compressed air from an external source, in which case they function as simple pneumatic switches which are well-known in the art. Moderate pressure and volumes of air are necessary for such safety switch functions—and little if any pressurized fluid.
Alternatively, one of the HA hand switches 62a or 62b may activate a pneumatic clamp for releasably securing IRS 30 to a post. The necessary compressive force ultimately securing IRS 30 to the post will be commensurate with the forces necessary to drive the post. Only upon activation of both switches is air delivered to the FPC 41 and hammering of the post commenced.
As shown in
Alternatively, IRS 30 may be secured to the post by manual means known in the art such as a simple set screw and threaded aperture in the lower portion of the top of IRS 30. Disengaging either switch, which is easily achieved by releasing a thumb, which the user may do voluntarily or involuntarily, serves a valuable safety purpose. It is critical and desirable that both hands remain on the HA hand grips as this insures safer operation of the portable driving device 10 as even a hand that slides down a hand grip may not have optimal control of the device.
The portable power driving device 10 utilizes approximately 5.5 inches to 7 inches of travel at 50 to 150 psi (compressed air). The overall length of the device is approximately 20 inches—notably shorter than, for example, prior art units employing dual power cylinders. The device is approximately 6 inches wide and 0.75 inches deep. The device requires approximately 2 cubic feet of air, which is notably less than prior art units, including those with dual power cylinders. As noted previously, if the device is formed of steel, the approximate weight is 20 pounds. The device delivers an impact load approximately every 0.75 seconds. However, the impact frequency may be affected by the source of fluid. For example, 50 psi (air pressure) will produce an impact frequency of approximately 60 impacts per minute, whereas 120 psi may produce an impact frequency of 130 impacts per minute. Regulators are well-known in the art as a means of controlling the pressure of fluid delivered to VB 54.
The device 10 is scalable for different impact loads, different cross-sectional shapes of posts, and different fluids used to power the device.
The subject invention is versatile. It can be made proportionally larger, while still utilizing the innovative valve control box and hand switch valve control assembly disclosed herein even though the preferred embodiment is disclosed is for use with a relatively small post, having a rectangular sleeve design, with rectangular impact surfaces in the sleeves.
Preferably, each end of VCR 51 is threaded with a nut, and proximate the nuts are springs and washers. So, with reference to
With reference to
Calibration of the drive stroke, that is when VB 54 directs fluid into the interior volume of the lower end 23 of FPC 41, may be in part effectuated according to the spring rate of the lower spring 34b on the lower end of VCR 51. The spring rate may be varied to absorb varying amounts of energy per unit of displacement to impact when fluid directed to the interior volume of the lower end 23 of FPC 41 is terminated. Higher source pressure results in greater impact as more energy is required to move the spool valve.
It should be noted that the innovative VB 54 allows air to exit the side of the spool valve 57. This allows VB 54 to be closed to the external pressurized fluid source as opposed to requiring an exhaust port or ports. Specifically, when fluid is directed to the interior volume 24 of the upper end of the FPC 41, through FPCC 46 (
It should be noted that suitable seals are well-known in the art to enable the portable driving device 10 to function properly and reliably even though there are moving parts therein, notably the VCR 51 and FPCCR 42, which oscillate in and out of the pressurized VB 54.
Preferably when the portable driving device 10 is at rest ORS 20 is down—that is, the interior volume of the lower end 23 of FPC 41 is filled with fluid and so the device is collapsed into a configuration of minimum length.
It should be noted that the portable driving device 10 allows for compactness with an economy of space and parts. All valve assembly components, and all means of control thereof, are within the footprint of the ORS 20 and the device 10 need not employ more than a single power cylinder.
The subject invention is preferably constructed of components which are bolted together although alternatively welded components are viable. It will become apparent that bolted components will allow the subject driving device to be modular wherein the power driving components can be disassembled and reassembled—namely, bolted to an alternative IRS 30 and compatible ORS 20 which are cooperatively adapted for a post of alternative cross-sectional dimensions. For example, ORS 20 may break down into five components: a top, a bottom, two side panels and a closed end. For example, the top and bottom may be used for a post that has a similar cross-sectional length but a greater width, which would require the side panels and closed end to have a greater height. For example, preferably for a reflective post ORS 20 has a length of approximately 20 inches and a width of approximately 5 inches and a depth or thickness of approximately 1.5 inches.
Alternatively, ORS 20 need not break down into fewer components. However, what is preferred, to provide modularity which will also ease service to individual components, is for the BB 52 to be releasably affixed to IRS 30, and VB 54 and FPCUB 44 to be releasably affixed to ORS 20. Accordingly, the fluid power assembly, which includes FPC 41, FPCCR 42, FPCP 43, and FPCUB 44, and the VCA 50, which includes VCR 51, BB 52, and VB 54, may be removed and affixed to an alternative ORS and compatible IRS. As illustrated in
Alternatively, the slot in ORS 20 may extend to its bottom end and a cover plate 21 (
The handle assembly HA 60, and the hand switches 62a, 62b, and the aforementioned means for providing fluid communication between the hand switches and the supply of air, which may be referred to as a hand switch valve control assembly, may be releasably affixed to IRS 30 at its lower end adding another, if necessary, modular component, since the handle assembly and hand switch valve assembly communicates solely with VB 54 with an appropriate fluid.
It should also be noted that the portable power driving device 10 allows for the handle to remain fixed in space during operation of the device—excluding the time the ORS 20 impacts the IRS 30 which in turn drives the post into the ground/soil/other. This makes for a portable driving device that is more user friendly and ergonomic.
The HA 60 with pressurized fluid control is depicted in part of
The handle valve assembly 64 has an internal portion including a recessed core 70 with an aperture 71. When switch 62a is not engaged, a pressure nut 69 presses an O-ring A against the handle valve assembly. Therefore when external fluid is supplied to the interior volume of the handle 61a through the source intake means 39, the O-ring A prevents fluid from entering the handle valve assembly 64 along the switch shaft and into the internal portion thereof. When air is allowed to pass O-ring A, along the switch shaft and into the internal portion of the handle valve assembly, then O-ring B and O-ring C prevent air from escaping into the interior volume of the handle 61a and air is diverted out of the aperture 71.
When switch 62a is engaged the handle valve assembly does not move—it remains aligned with the aperture 63, however the switch shaft 65 moves (typically downwardly) the pressure nut 69 away from O-ring A, thereby allowing O-ring A to float, or flutter, thereby allowing compressed fluid to enter into the inner body of the handle valve assembly and exit the handle valve assembly aperture 71 and out the aligned aperture 63 in handle 61a, which in turn provides pressurized fluid to handle 61b via the handle conduit 68.
On the other hand, when hand switch 62a is not engaged, the pressure nut 39 seals O-ring A against the handle valve assembly. Only upon engaging switch 62a is the O-ring A allowed to float.
Manual switches 62a and 62b a will not be sealed so air exits after operation and both switches are released.
Handle 61b is essentially identical to handle 61a with the exception that there is no intake means 39, and pressurized fluid exiting the aperture 63 in the handle 61b is delivered to a device which requires, or preferably includes, a two switch means by which to control the delivery of pressurized fluid. It is not illustrated in
While specific embodiments of the invention have been described in detail, it will be appreciated by those skilled in the art that there are modifications and alterations that do not depart from the inventive concepts disclosed herein. Accordingly, the particular arrangements disclosed are meant to be illustrative only and not limiting as to the scope of the invention which is to be afforded the full breadth of the disclosure and any and all equivalents thereof. For example, while the subject invention is directed to post driving devices the innovative driving mechanisms disclosed herein may be adapted for utilization with fracturing devices such as jack-hammers or other devices that can utilize reciprocating motion.
Moreover, while the disclosure herein focuses on embodiments which have FPC 41 releasably affixed to ORS 20, and the BB 52 releasably affixed to IRS 30, it is fully within the scope of the subject invention to have FPC 41 releasably affixed to IRS 30 and the BB 52 releasably affixed to ORS 20 with accompanying design modification, which would not require independent invention or undue experimentation from one skilled in the art.
Additionally, while embodiments of the subject invention are described as having components that are releasably affixed to other components, it should be appreciated that this is to improve the modularity of the subject invention and does not limit the invention to releasably affixed components, and so components may be affixed to other components within the scope of the invention by non-releasable means.
10 portable driving device
17 lower end of IRS 30
18 upper end of IRS 30
20 ORS—outer rectangular sleeve
20
a outside top surface of ORS 20
20
b upper end of ORS 20
21 cover plate
22 upper end of FPC 41
23 lower end of FPC 41
23
a extreme end portion of 23
27 slot in ORS 20
30 IRS—inner rectangular sleeve
30
a outside top surface of FRS 30
31 upper closed end of ORS 20
33
a and 33b upper and lower nuts attached to VCR 51
34
a and 34b upper and lower springs carried by VCR 51
36
a and 36b upper and lower washers carried by VCR 51
38
a and 38b faces of spool valve 57
39 source intake means for HA 50
40 fluid power assembly
41 FPC—fluid power cylinder
42 FPCCR—fluid power cylinder connecting rod
42
a lower end of FPCCR 42
43 FPCP—fluid power cylinder piston
44 FPCUB—fluid power cylinder upper box
45 fluid power cylinder conduit safety valve
46 FPCC—fluid power cylinder conduit
50 VCA—valve control assembly
51 VCR—valve control rod
52 BB—base block
54 VB—valve box
55 pneumatic connector
56
a and 56b—chambers of VB 54
57 spool valve
501
a and 501b—slots in VB 54
503—VB threaded chambers
503 stops in VB 54
60 HA—handle assembly
61
a and 61b handle bars
62
a and 62b hand switches
63 first and second handle apertures
64 first and second handle valve assemblies
65 switch shaft
67 handle brace bar
68 handle conduit
69 pressure nut
70 recessed core of handle valve assembly 64
71 aperture through recessed core 70
O-rings A, B, and C
This application claims the benefit of U.S. 61/575,883, filed Aug. 29, 2011, which is incorporated by reference herein in its entirety.
Number | Date | Country | |
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61575883 | Aug 2011 | US |