The present application is a national stage filing under 35 U.S.C 371 of PCT application number PCT/AU2019/050527, having an international filing date of May 28, 2019, which claims priority to Australian patent application number 2018203763 having a filing date of May 29, 2018, the disclosures of which are hereby incorporated by reference in their entireties.
This invention relates to a hydraulic cylinder and more particular to a hydraulic cylinder having an intrascopic arrangement of a co-axial cylindrical hollow rod within it acting as a piston-rod thereby enabling it to produce a multitude of variations in forces, speeds, pressures and flows for its application in areas beyond the scope of conventional hydraulic cylinders.
Hydraulic cylinders are used extensively in a variety of industrial applications to provide linear motion control. These cylinders are composed of a cylindrically shaped metal case with a piston-rod assembly that moves back and forth within the case. The piston and rod assembly divides the volume inside the cylinder case to two separate chambers, for example front chamber and rear chamber. For a single rod cylinder, these two volumes are called: the rod end volume (front chamber), where the rod end is the end of the cylinder from which the rod protrudes, and the cap end volume (rear chamber), where the cap end does not have a rod.
As these volumes are pressurized, hydrostatic forces due to the pressurized fluid act on the surfaces of the vessel containing the fluid. Thus, the forces acting on the piston-rod assembly cause it to move, extending the rod out of the cylinder case or retracting the rod into the cylinder case. An external load can be attached to cylinder rod, and as the piston-rod assembly moves, a force is exerted on the load causing the load to move along a linear path. For a cylinder in retraction, the flow leaving the cap end exits through a port before returning to the rest of the hydraulic circuit through a cylinder port. The cylinder stops when the piston reaches the end of its stroke, or when the piston makes contact with the end cap. Usually, a cylinder cushion spear and a collar are attached on the either side of the piston to help it decelerate before it contacts the end cap during retraction or reaches the other end during extension, respectively.
Thus, the conventional double acting hydraulic cylinders which have a rear chamber and a front chamber essentially function by extending and retracting the piston-rod assembly within the internal surface of cylinder case. In a normal case, the speed with which piston-rod assembly extends is larger than when it retracts. This means that it moves in either direction at different speeds. The reason for this difference can be understood by considering the fact that when the pump pushes certain amount of fluid, it goes through the valve either to the rear end or to the front end. As it is, there is much more fluid required in the rear chamber to push the piston to extend than there is fluid required in the front chamber to push it for retraction. Thus, when a dominant pressure is introduced to the rear of the cylinder the rod extends slowly and when a similar pressure is applied to the front of the cylinder then it would retract much more quickly.
When there is need for speed control of piston-rod assembly during extension or during the retraction, the same can be achieved by controlling the fluid flow. A general approach is to install a flow control device in the hydraulic circuit between valve and fluid inlet/outlet of the rear or front chambers.
There have been many attempts as reported in the prior art literature to create a multi-power cylinder but they all included external solutions. The invention disclosed herein is a solution fully integrated into a standalone hydraulic cylinder and control. There is no need for an external intensifier, secondary hydraulic lines with high pressure, or any other compromises.
Since the conventional hydraulic cylinders rely on pressures and flows provided by hydraulic pumps and valves, its maneuverability is quite limited. A normal cylinder is limited by way of limited pressure and flow input and therefore may not work where greater force is required. For applications, where greater force is required, it is required to replace the smaller cylinder by a relatively larger cylinder. A consequence of this is that the larger cylinder will be slower to extend and retract. Therefore, there is a felt need for an efficient and compact hydraulic cylinder that can work over a broad range of required force.
The intrascopic arrangement of multiple cylinders within each other as disclosed in this invention creates its own pressure higher than what is supplied by conventional hydraulic circuits. This transforms a cylinder into a cylinder-pump.
The intrascopic cylinder of this invention can work quickly as a small cylinder does but has the added ability to produce enormous force when needed. In most applications a hydraulic cylinder will only use a small amount of its potential strength but it needs to be large enough to produce occasional peak loads. This invention allows for a cylinder to be smaller, lighter, and faster but still have the ability to produce great force when needed.
The intrascopic hydraulic cylinder of this invention can be used for variety of applications where conventional hydraulic cylinders are used and beyond where standard hydraulic cylinders are found inadequate. The major uses of the invention are intensification, variable speed, variable loads, variable forces and greater forces than are possible with the same size conventional hydraulic cylinder.
1 Cylinder Hollow Rod
2 Piston
3 Piston—Gland
4 Inner Rod
5 Cylinder Base
6 Chamber
7 Chamber
8 Chamber
9 Chamber
10 Cylinder
11 Hydraulic port
12 Hydraulic port
13 Hydraulic port
14 Fibre
15 Hollow Rod
The details of preferred embodiment of this invention along with inventive steps will now be specifically described that address the issues raised in the background and prior art above. There could be several other possible embodiments of this invention deploying the key inventive steps described here and, therefore, the scope and objective of the patent are not limited.
The intrascopic cylinder of this invention has been conceived as a combination of two hydraulic cylinders integrated into one whose outer casing or envelope is virtually similar to a standard cylinder. Thus, in this conception an inverted smaller hydraulic cylinder inside the outer cylinder acts like a piston-rod assembly of a conventional hydraulic cylinder. This contraption allows one to have more than two chambers (front and rear chambers) as in conventional hydraulic cylinder with attendant more number of hydraulic ports. In this contraption, when pressure is applied to one of the chambers, its internal rod would extend into the opposite chamber displacing its mass and dramatically increasing the pressure inside it. This displacement is effectively an internal pump which can be activated multiple times within a given stroke of the modified rod (i.e. inverted smaller cylinder inside the outer cylinder).
The above conception is completely ‘novel’ and has not been reported, to our knowledge, anywhere before. Further, inventive features of this invention are described below by way of possible embodiments in the following examples:
By introducing pressure in to chamber 6 and then upon challenge, subsequently into chamber 7, rod 4 will displace the existing pressurized chamber 6 and increase the pressure in that chamber. The cylinder, 10 will produce more force transmitted through rod 1 than a conventional cylinder of the same bore size.
By introducing pressure to chamber 7 after chamber 6 has reached its maximum force potential at system pressure or pre-determined pressure, rod 4 will displace fluid in chamber 6 increasing the pressure in chamber 6 beyond what was previously introduced by the hydraulic supply or “system pressure”. This enables the intrascopic cylinder to create forces previously not achievable within normal size envelopes and in a hydraulic system which cannot offer unlimited pressure.
The concept of integrated hydraulic cylinders within each other can be practiced in many different embodiments.
In this embodiment of
Thus, whereas the conventional hydraulic cylinders rely on pressures and flows provided by hydraulic pumps, valves and external intensifiers, the intrascopic cylinder of this invention creates its own pressure higher than what is supplied by conventional hydraulic circuits. This transforms the cylinder into a cylinder/pump.
Buckling and band strength are two significant challenges in the manufacturing of hydraulic cylinders, which is overcome here in this invention by having the inner rod 1 being wide and hollow. Care is taken to see that the rod, 4 and the rear block, 5 as in
Bowing, i.e. the expansion of the outer cylinder, 10 (
In order to demonstrate the industrial applicability of this invention, a laboratory scale prototype cylinder was fabricated as per the design shown in
Number | Date | Country | Kind |
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2018203763 | May 2018 | AU | national |
Filing Document | Filing Date | Country | Kind |
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PCT/AU2019/050527 | 5/28/2019 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2019/227146 | 12/5/2019 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
2577462 | Hackney | Dec 1951 | A |
3722375 | Sievenpiper | Mar 1973 | A |
5007327 | Kamimura et al. | Apr 1991 | A |
5341725 | Dick | Aug 1994 | A |
6688211 | Viet | Feb 2004 | B1 |
7823803 | Peterson | Nov 2010 | B2 |
20120126055 | Lindahl | May 2012 | A1 |
20170261015 | Tsutsui | Sep 2017 | A1 |
Number | Date | Country |
---|---|---|
2015190972 | Dec 2015 | WO |
2018065670 | Apr 2018 | WO |
Entry |
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International Search Report and Written Opinion dated Jun. 27, 2019, PCT Patent Application No. PCT/AU2019/050527, filed May 28, 2019, Australian Patent Office, 8 pages. |
Number | Date | Country | |
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20210207626 A1 | Jul 2021 | US |