The present invention relates generally to rotary piston and cylinder devices.
Rotary piston and cylinder devices can be configured for a variety of applications, such as an internal combustion engine, a fluid pump such as a supercharger, or as an expander such as a steam engine or turbine replacement.
A rotary piston and cylinder device comprises a rotor and a stator, the stator at least partially defining an annular cylinder space, the rotor may be in the form of a ring, and the rotor comprising at least one piston which extends from the rotor ring into the annular cylinder space, in use the at least one piston is moved circumferentially through the annular cylinder space on rotation of the rotor relative to the stator, the rotor body being sealed relative to the stator, and the device further comprising cylinder space shutter means which is capable of being moved relative to the stator to a closed position in which the shutter means partitions the annular cylinder space, and to an open position in which the shutter means permits passage of the at least one piston, the cylinder space shutter means comprising a shutter disc.
The term ‘piston’ is used herein in its widest sense to include, where the context admits, a partition capable of moving relative to a cylinder wall, and such partition need not generally be of substantial thickness in the direction of relative movement but can often be in the form of a blade. The partition may be of substantial thickness or may be hollow. The shutter disc may present a partition which extends substantially radially of the annular cylinder space.
Although in theory the shutter means could be reciprocable, it is preferred to avoid the use of reciprocating components, particularly when high speeds are required, and the shutter means is preferably at least one rotary shutter disc provided with at least one aperture which in the open condition of the shutter means is arranged to be positioned substantially in register with the circumferentially-extending bore of the annular cylinder space to permit passage of the at least one piston through the shutter disc.
We have devised an improved rotor.
The geometry of the surface interacting with the disc of the rotor for a rotary cylinder device is governed by the curved outer face of the rotating shutter disc that forms the end face of the cylinder, and allows the piston (blade) to pass through an aperture in the shutter disc at the end of a stroke. Depending on the specific configuration this shape can vary, but is in any event substantially curved. A solution apparent to one skilled in the art would therefore be for the outer face of the rotor to be substantially similar and curved with respect to the inner face, resulting in a substantially constant wall thickness, as shown by the rotor in
We have realised that it is significantly simpler to manufacture and inspect the accuracy of a conical surface as it does not require the use of user-implemented gauges, and significantly decreases the duration of digital inspection.
According to an aspect of the invention, there is provided a rotor of a rotary piston and cylinder device wherein at least part of an outer surface of the rotor is a substantially frusto-conical shaped surface.
By frusto-conical surface we include the meaning of the shape of the surface of a truncated cone.
By ‘outer surface’ we mean a surface which is an opposite surface to that surface of the rotor which defines (in part) the cylinder space.
Preferably the outer face of the rotor is not curved, but instead is formed of at least one substantially conical element.
Preferably there is provided an annular cylinder space, and the rotor is provided with the piston forming the end face of the cylinder space, and a housing portion which extends away from the annular cylinder space, at an (axially) distal end of the rotor (i.e. at an end portion of the rotor along the axis of rotation of the rotor) which is substantially co-axial with the axis of rotation of the rotor, and the housing portion is rotationally connected to a transmission assembly to transmit rotation from the rotor to a rotatable shutter of the device, and the transmission assembly is at least partially enclosed by the housing portion.
The at least one aperture of the shutter disc may be provided substantially radially in the shutter disc.
Preferably the axis of rotation of the rotor is not parallel to the axis of rotation of the shutter disc. Most preferably the axis of rotation of the rotor is substantially orthogonal to the axis of rotation of the shutter disc.
Preferably the piston is so shaped that it will pass through an aperture in the moving shutter means, without balking, as the aperture passes through the annular cylinder space. The piston is preferably shaped so that there is minimal clearance between the piston and the aperture in the shutter means, such that a seal is formed as the piston passes through the aperture. A seal is preferably provided on a leading or trailing surface or edge of the piston. In the case of a compressor a seal could be provided on a leading surface and in the case of an expander a seal could be provided on a trailing surface. The term seal is used to include an arrangement which reduces clearance, minimising leakage, but not necessarily preventing fluid transfer across the seal.
The rotor body is preferably rotatably supported by the stator rather than relying on co-operation between the piston and the cylinder walls to relatively position the rotor body and stator. It will be appreciated that a rotary piston and cylinder device is distinct from a conventional reciprocating piston device in which the piston is maintained coaxial with the cylinder by suitable piston rings which give rise to relatively high friction forces.
The rotor is preferably rotatably supported by suitable bearing means carried by the stator.
Preferably the stator comprises at least one inlet port and at least one outlet port.
Preferably at least one of the ports is substantially adjacent to the shutter means.
Preferably the ratio of the angular velocity of the rotor to the angular velocity of the shutter disc is 1:1, although other ratios are possible.
The rotor may comprise one or more features described in the detailed description below and/or shown in the drawings.
Various embodiments of the invention will now be described, by way of example only, with reference to the following drawings in which:
Reference is made initially to
In a further embodiment, the outer surface of the rotor comprises a frusto-conical portion and a curved portion, which occupy a major portion of the surface area of the outer surface of the rotor. In this embodiment, the frusto-conical portion is adjacent to the curved portion.
For example, where the axial expansion of the rotor (i.e. expansion substantially in the direction of the rotational axis of the rotor) during service at the location of a particular shoulder is more significant than the radial expansion, the preferred sealing face is the one that is more substantially cylindrical, as the sealing gap will be less adversely affected by deformation of the rotor. Conversely if the radial expansion is more significant than the axial, sealing on the substantially planar face is preferred, as that gap will experience lower variation during operation of the device. It will be understood that both of these conditions can be experienced in different locations on a single rotor.
If the behaviour of the rotor during operation is well understood such that the location-dependant relative effects of thermal, centrifugal and pressure-related deformation on the rotor as well as any displacements are known, the preferred angle of a substantially conical sealing region (between the rotor and the stator) in any of the above examples can be calculated. Put otherwise, the cone angle can to tailored according to operational conditions. In one embodiment, a particular angle of the substantially conical face will minimise variation of the sealing gap at a particular position during operation of the device. Furthermore, the angle can be set to selectively vary the gap (between the rotor and the stator) during operation, such as to either prioritise frequent running conditions by minimising the sealing gap (i.e. reducing the size of the gap as compared to when the device is stationary) at those operating points, or reduce input power for transient conditions such as start-up by increasing the sealing gap under these scenarios.
It is to be noted that it is the substantially outer faces of the ridges (which define the grooves) that are more significant for sealing purposes, and that the substantially inner surfaces of the grooves can conform to a plurality of different sections, including conical, curved or irregular. Although it is possible to cut grooves into a geometry which provides a constant operational gap width and obtain the benefits of improved axial leakage sealing performance with a controlled and substantially constant sealing gap, it may be preferred to instead orient the face to maximise relative motion along the normal direction. Here the deformation of the rotor at the location of the face is largely radial during operation, and less than the clearance between the labyrinth outer face and mating stator face. In this manner it is possible to control the sealing gap at different operating conditions, to either target specific operating conditions or reduce power consumption during transient conditions.
In a further possible variant, the maximum deformation of the rotor at a particular point is greater than the static clearance between it and the stator, and a material that can be worn away by the ridges is applied to the mating face. The material is an abradable coating applied to the stator face (or alternatively which may be applied to the rotor conical surface, with ridge formations on the stator), and the labyrinth structure is formed of a series of circumferential grooves on the outer rotor face. The rotor may be assembled so that the sealing faces are clear of each other or such that they are touching (and then rotated to abrade on clearance). During operation, the substantially outward radial deformation of the rotor (towards the stator) causes the ridges to cut into the abradable coating on the mating stationary sealing face of the stator. This results in a sealing interface in which the gap is minimised during operation as shown in
It will be noted that it is also possible to assemble the device while the rotor is being rotated, such that the grooves wear away the abradable material during assembly, immediately resulting in a geometry similar to that shown
In a further variant, it is possible to create a mating inverse labyrinth geometry on the stator using a material that will not be worn by the groves on the rotor. While this approach reduces uncertainty in wear patterns of the abradable, it will be understood that the deformation of the rotor must be minimised in order to achieve low gap widths throughout the labyrinth during operation, without allowing the mating faces to touch.
Number | Date | Country | Kind |
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1413173 | Jul 2014 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/GB2015/052147 | 7/24/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2016/012805 | 1/28/2016 | WO | A |
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6250900 | Gostomski | Jun 2001 | B1 |
20110174095 | Lindsey | Jul 2011 | A1 |
20120034122 | Hayes-Pankhurst | Feb 2012 | A1 |
20130202458 | Byrne et al. | Aug 2013 | A1 |
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United Kingdom Search Report dated Feb. 23, 2015 in corresponding United Kingdom Application No. 1413172.6. |
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Number | Date | Country | |
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20170204727 A1 | Jul 2017 | US |