Title of Invention	'AN IMPROVED ROTARY PISTON MACHINE'
Abstract	This invention relates to an improved rotary piston machine comprising two variable- volume units (1,4) each unit (1,4) having a rotary multi-lobed epitrochoidal chamber (3,6) and a multi-sided rotary piston (2,5) forming therein a plurality of individual sub-chambers (3a, 3b,3c,6a,6b,6c) 5y its co-operation with the periphery of an associated chamber, the numher (n+1) of piston sides being greater by one than the number (n) of epitrochoid ares, wherein the two chambers (3,6) are constrained to rotate at a first common speed about a first effective common axis through their centers while the two pistons (2,5) are constrained to rotate at a second common speed about a second effective common axis through their centers in a same direction, the ratio of first to second common speeds being n+1:n, wherein each chamber (2,5) has a plurality (n) of dual-function ports (7,8,9,10) enabling connection between the chambers (2,5) via ducts (10,11) and wherein said ducts (10,11) each contain a regenerators, enabling one variable-volume unit (1) to perform intake, expansion and exhaust, while the other unit (4) performs intake, compression and exhaust, as a result of the relative rotation and port positions.

Title of Invention

'AN IMPROVED ROTARY PISTON MACHINE'

Abstract

This invention relates to an improved rotary piston machine comprising two variable- volume units (1,4) each unit (1,4) having a rotary multi-lobed epitrochoidal chamber (3,6) and a multi-sided rotary piston (2,5) forming therein a plurality of individual sub-chambers (3a, 3b,3c,6a,6b,6c) 5y its co-operation with the periphery of an associated chamber, the numher (n+1) of piston sides being greater by one than the number (n) of epitrochoid ares, wherein the two chambers (3,6) are constrained to rotate at a first common speed about a first effective common axis through their centers while the two pistons (2,5) are constrained to rotate at a second common speed about a second effective common axis through their centers in a same direction, the ratio of first to second common speeds being n+1:n, wherein each chamber (2,5) has a plurality (n) of dual-function ports (7,8,9,10) enabling connection between the chambers (2,5) via ducts (10,11) and wherein said ducts (10,11) each contain a regenerators, enabling one variable-volume unit (1) to perform intake, expansion and exhaust, while the other unit (4) performs intake, compression and exhaust, as a result of the relative rotation and port positions.

Full Text	This invention relates to rotary piston machines. It is concerned with an adaptation of the Stirling principle, with multi-sided rotary pistons operating in chambers with epitrochoidal lobes, the working fluid or vapour undergoing closed thermodynamic cyclic processes. The machine may operate as an engine or as a heat pump. According to the present invention there is provided a fluid or vapour rotary piston machine including two variable-volume units, each unit having a rotary multi-lobed epitrochoidal chamber and a multi-sided rotary piston therein forming a plurality of invididual sub-chambers by its co-operation with the periphery of the associated chamber, the number (n+l) of piston sides being greater by one than the number (n) of epitroichoid arcs, wherein the two chambers are constrained to rotate at a first common speed about a first effective common axis while the two pistons are constrained to rotate at a second common speed about a second effective common axis, the ratio of first to second common speeds being n+l:n, wherein each chamber has a plurality (n) of dual-function ports enabling connection between the chambers via ducts, and wherein said ducts each contain a regenerator, enabling one variable-volume unit to perform intake, expansion and exhaust, while the other unit performs intake, compression and exhaust, as a result of the relative rotation and port positions. Preferably, the chambers will be co-axial, as will be the rotors. That simplifies construction. But they could, in theory, be on different axes but coupled tc rotate in liaison. The term "effective" is intended to cover this alternative. Heating means may be provided for the variable-volume unit which performs the expansion processes, and there could be further heating means between each said regenerator and the variable-volume unit which performs the expansion processes. Cooling means may also be provided for the variable- volume unit which performs the compression processes, and there could be further cooling means between each said regenerator and the variable-volume unit which performs the . compression processes. In the preferred form n=2, so that there are three sided pistons operating in double-lobed chambers. The expansion unit which may, but not necessarily, be heated, will have its ports disposed in such a way that the chambers formed therein are increasing in volume generally when not in communication with a port and decreasing in volume generally. when said chambers are in communication with a port. The other, compression unit which may, but not necessarily, be cooled, will have its ports disposed in such a way that the chambers formed therein are decreasing in volume generally when not in communication with a port, and increasing in volume generally when said chambers are in communication with a port. Work processes thus occur in chambers isolated from port openings, while the transfer of working fluid or vapour occurs between a pair of chambers each in communication with ports opening to a common duct. If high-grade heat transfer is accomplished to the working fluid or vapour flowing to, from or contained within, the expansion unit, while low-grade heat transfer is accomplished from the working fluid or vapour flowing to, from, or contained within, the compression unit, the machine behaves as an engine, with mechanical work output. If mechanical work is applied to the rotating components, but low-grade heat transfer is accomplished to the region of the expansion unit while high-grade heat transfer occurs from the region of the compression unit, the machine behaves as a heat pump or refrigerating machine. For a better understanding of the invention, reference will now be made by way of example, to the accompanying drawings, in which: Figures 1, 2, 3,4 and 5 are schematic diagrams showing the relative positions of expansion and compression units of a rotary piston machine at intervals during a cycle of rotation, and Figure 6 is a diagrammatic cross-section through a preferred embodiment of the machine. An expansion unit 1 has a rotary piston 2 contained in a chamber 3 and a compression unit 4 has a rotary piston 5 contained in a chamber 6. Each piston 2 and 5 is of flat, generally equilateral triangular form, but with the sides of the triangle convex and arcuate. Each chamber 3 and 6 is also flat, closely to confine the faces of the piston, and is of two-lobed epitrochoidal form. The chambers thus have major and minor axes intersecting at right angles at their centres. The two units 1 and 4 are rigidly linked to rotate about a common axis through their centres in the same direction and at the same speed, the major axes of the chambers 3 and 6 being at 90° to each other. The two rotary pistons 2 and 5 are also rigidly linked to rotate about a common axis through their centres in the same direction and at the same speed, this being two thirds the speed of rotation of the chambers 3 and 6. The arcuate sides 2a, 2b and 2c of the piston 2 are disposed at 180° to the counterpart sides 5a, 5b and 5c of the other piston 5. The sides of the pistons 2 and 5 co-operate with the profiles of the respective chambers 3 and 6 to form sub-chambers 3a, 3b and 3c and 6a, 6b and 6c, of variable volume and shape in operation, as described below. Ports 7 and 8 in the expansion unit 1 are diagonally opposite each other and offset 30° in the direction of motion (clockwise as seen in Figures .1 to 5) from the minor axis of the chamber 3. Corresponding ports 9 and 10 are similarly disposed in the compression unit 4, but are offset by 30° in the direction opposite that of rotation from the minor axis of the chamber 6. This positioning ensures that during operation a port, 7 or 8, is about to open to a sub- chamber when that sub-chamber is at maximum volume in the expansion unit 1. Similarly, a port, 9 or .10, has just closed to a sub-chamber when that sub-chamber is at maximum volume in the compression unit 4. The expansion unit port 7 is linked by an interconnecting duct 11 to the compression port 9 diagonally opposite with reference to the axis of rotation of the units 1 and 4, while the expansion unit port 8 is similarly linked by an interconnecting duct 12 to the compression unit port 10. These ducts each contain a regenerator (not shown). The sequence of operation is as follows.- In Figure 1, heated working fluid or vapour occupies the sub-chamber 3a, which is at minimum volume and is open, via the port 8, to the duct 12. The sub-chamber 3b is isolated and increasing in volume. The sub-chamber 3c is decreasing in volume, thereby expelling working fluid or vapour via the port 7, through the duct 11. The fluid or vapour is giving up, in the case of an engine, or taking up, in the case of a heat pump, heat within the regenerator in that duct 11. Cooled working fluid or vapour occupies the chamber 6a which is at maximum volume, isolated, and about to start its compression cycle. The sub-chamber 6b is in its compression cycle, is decreasing in volume and isolated. The sub-chamber 6c is increasing in volume and is open, via the port 9, to the duct 11. It is therefore receiving the working fluid or vapour from the sub-chamber 3c. The port 10 is closed by the piston 5. In Figure 2 the pistons 2 and 5 have rotated clockwise by 30° and the chambers 3 and 6 by 45°. The sub-chamber 3a is increasing in volume and accepting working fluid or vapour, via the port 8, from the duct 12 and from the sub- chamber 6b, which continues to decrease in volume and now communicates with the port 10. The sub-chamber 3b continues to increase in volume, with the isolated heated working fluid or vapour therein being expanded, while the transfer of working fluid or vapour continues from the sub-chamber 3c to the sub-chamber 6c via the port 7, the duct 11, and the port 9. The cooled working fluid or vapour in the sub- chamber 6a remains isolated and is compressed as the volume of that -sub-chamber decreases. In Figure 3 the pistons have rotated through 60° from their initial, positions and the chambers by 90°. The sub- chamber 3a continues to increase in. volume, but the piston 2 closes the port 8, thereby terminating the ingress of working fluid or vapour, whereupon the expansion process commences within that sub-chamber. The sub-chamber 3b has attained its maximum volume, and the heated working fluid therein has reached the end of its expansion process, while the sub-chamber 3c continues to decrease in volume with the egress of working fluid or vapour, via the port 7, the duct 11 and the port 9 to the compression unit 4. The cooled working fluid continues to be compressed in the isolated sub-chamber 6a as the volume therein decreases. The sub- chamber 6b is at minimum volume and open, via the port 10, to the duct 12, but the working fluid or vapour ceases to flow due to the closure of the port 8. The sub-chamber 6c continues to increase in volume and to accept the working fluid or vapour, via the port 9, from the sub-chamber 3c. In Figure 4 the pistons 2 and 5 have moved on another 30° and the chambers 3 and 6 another 45°. The sub-chamber 3a is isolated and increasing in volume, with the heated working fluid therein continuing its expansion process. The sub-chamber 3b now communicates with the port 8 as that is uncovered by the piston 2 and, since that sub-chamber is decreasing in volume, the working fluid or vapour therein is forced out into the duct 12. The sub-chamber 3c continues to decrease in volume, and transfer of working fluid or vapour, via the port 7, the duct 11 and the port 9, continues to the compression unit 4. The sub-chamber 6a remains isolated and decreasing in volume, with the cooled working fluid or vapour therein continuing its compression process. The sub- chamber 6b is now increasing in volume and, due to its communication with the port 10, accepts the working fluid or vapour from the sub-chamber 3b via the duct 12. The sub- chamber 6c continues to increase in volume and the ingress of working fluid or vapour continues, via the port 9 and the duct 11, from the expansion unit 1. In Figure 5 the pistons are 120° from their original positions and the . chambers 180° from theirs. The sub- chamber 3a continues to increase in volume, with the heated, isolated working fluid therein continuing its expansion process. The sub-chamber 3b continues to decrease in volume, with its working fluid or vapour passing via the port 8, the duct 12, and the port 10 to the sub-chamber 6b which is increasing in volume. The sub-chamber 3c is at minimum volume and open, via port 7, to the duct 11, but the compression unit piston 5 has closed the port 9, and so the working fluid or vapour ceases to flow. The sub-chamber 6a is still isolated and decreasing in volume, with the cooled working fluid therein at the end of its compression process. The sub-chamber 6b continues to accept the transferred working fluid or vapour from the expansion unit 1. The sub- chamber 6c, now isolated due to the closure of the port 9, is at maximum volume with the working fluid or vapour therein at the commencement of its compression process. The situation within the machine is now similar to that of Figure 1, although the various bodies of working fluid or vapour occupy different spaces to those in the earlier diagram. Consider the body of cooled working fluid in the sub- chamber 6a in Figure 1 at the commencement of its compression process. As the units 1 and 4 rotate through 180° and the rotary pistons 2 and 5 rotate through 120°, the relative rotor rotation will be 60° in the opposite direction-. This finds the body of fluid in sub-chamber '6a at the end of its compression process in a similar situation to that of the cooled working fluid or vapour in the sub- chamber 6b in Figure 1. After a further 30° of relative rotor rotation (corresponding to the Figure 3 positions) the sub-chamber 6 a will be at minimum volume, and the major proportion of the working fluid or vapour that was therein will have transferred to the sub-chamber 3c via the port 9, the ducts 11 and the port 7, absorbing; in the case of an engine, or rejecting, in the case of a heat pump, heat during its passage through duct 11. At this point, where . the total relative rotor rotation is 90°, the piston 2 will have passed the port 7. The expander sub-chamber 3c allows expansion of the heated working fluid or vapour therein until a further 60° of relative rotor rotation has occurred (making the total 150°), when the sub-chamber 3c is at maximum volume. Further rotation uncovers the port 8, allowing egress of heated working fluid or vapour via the duct 12, in which it is cooled in the case of an engine, or heated in the case of a heat pump. It then enters the sub chamber 6c via the port 10, this transfer process occurring over a further 90° of relative rotor rotation, the total then being 240°, when the sub-chamber 3c will be at minimum volume. The piston 5 now covers port 10 and the thermodynamic cycle involving this particular body of working fluid or vapour is repeated. The processes may be tabulated over 360° of relative rotor rotation, corresponding to 720° of piston rotation and 1080° of chamber rotation, as set out below in Table 1. The closed thermodynamic cycle described above occurs and repeats, with phase displacement, with four main bodies of working fluid or vapour. In Figure 1, these are located in sub-chamber 6a at the commencement of compression, in sub-chamber 6b towards the end of compression, in sub- chambers 3c and 6c and duct 11 undergoing regenerative transfer, and in sub-chamber 3b undergoing expansion. The residual working fluid or vapour in sub-chamber 3a is awaiting mixing with the main body of working fluid or vapour in the sub-chamber 6b. It will be noted that work processes in both the expansion and compression units are of equal duration, namely 60° of relative rotor rotation. Working fluid or vapour regenerative transfer from the compression unit 4 to the expansion unit 1 is always to a sub-chamber of dissimilar designation, that is, 6a to 3c, 6b to 3a and 6c to 3b, and is of short duration, namely 30° of relative rotor rotation. Working fluid or vapour regeneration transfer from the expansion ' unit 1 to the compression unit 4 is always to a sub-chamber of similar designation, that is, 3a to 6a, 3b to 6b and 3c to 6c, and is of long duration, namely 90° of relative rotor rotation. If the units 1 and 4 are of equal size, which is not a necessity, the geometry ensures that this latter transfer occurs under constant summed volume. The regenerative transfer of any one main body of working fluid or vapour is always accomplished alternately between the two ducts 11 and 12. That is, transfer from one unit to the other via one duct is always followed, by the return transfer via the other duct. Because of the pairings of sub-chambers during those transfers, any one main body of working fluid or vapour will eventually be transported through every sub-chamber within the machine, allowing mass and energy balances of the working fluid or vapour to be attained rapidly. The route followed by one main body of working fluid or vapour may be. tabulated over 720° of relative rotor rotation, corresponding to 1440° of piston rotation and 2160° of housing rotation, as shown below in Table 2. The main body of working fluid or vapour under study in that table is that which appears in sub-chamber Sa in Figure 1, at the start of its compression process. It can be seen to undergo three complete thermodynamic cycles before it returns to that sub-chamber 6a, after passing through all the other sub-chambers of the machine. A second main body of working fluid or vapour which appears in sub-chamber 6b in Figure 1, undergoing its expansion process, will follow an identical route to that shown in Table 2, with a phase displacement of +360° relative rotor rotation from that shown in Table 2. A third main body of working fluid or vapour which appears in sub-chamber 6b in Figure 1, towards the end of its compression process, will follow a similar route, but with the ducts interchanged so that expansion unit to the compression unit transfers are made via the duct 11 whilst the reverse transfers are made via the duct 12, with a phase displacement of +180° relative rotor rotation from that shown in Table 2. The fourth main body of working fluid or vapour which appears in sub-chambers 3c and 6c and duct 11 in Figure 1, undergoing regenerative transfer to the compression unit, will follow an identical route to that of the third main body of fluid or vapour, with a phase displacement of -180° relative rotor rotation from that shown in Table 2 . The machine therefore provides for a total of twelve thermodynamic cycles over the period defined by 1440° of piston rotation, corresponding to 2160° of chamber rotation and 720° of relative rotor rotation. It.should be noted that each individual thermodynamic cycle occurs over a period defined by 24 0° of relative rotor rotation, that is, 480° of piston rotation and 720° of chamber rotation. Whichever component, whether the coupled pistons 2 and 5 or the coupled units 1 and 4 is employed as the engine work output medium or . heat pump work, input medium, the thermodynamic cycles have a longer duration than those occurring in conventional reciprocating heat engines and reciprocating heat pumps. These must, perforce, occur over 360° of the output, or input, shaft rotation. This feature of the rotary machine described above allows enhanced heat transfer processes, enabling the theoretically ideal thermodynamic cycle to be approached. In Figure 6, the two units 1 and 4 are rigidly coupled by a hollow shaft 13 journalled at 14 and 15 in a fixed mounting 16. The pistons 2 and 5 are carried by a common shaft 17 journalled at 18 and 19 in the mounting 16. The ports 7, 8, 9 and 10 are in the flat radial sides of the chambers 3 and 6, near their peripheries, and are open and closed by the flat faces of the pistons 2 and 5. A gear coupling 20 between the shafts 13 and 17 ensure that the units 1 and 4 rotate relatively to the pistons 2 and 5 in the manner described. The units 1 and 4 can be encapsulated or shrouded to distinct upper and lower temperature regions around them, each unit presenting a large surface area for efficient heat transfer. The rotation of those units promotes near-uniform temperature distribution. In addition to maintaining a temperature differential between the units 1 and 4, there can be additional heating and cooling means for the ducts 11 and 12 provided, for example, by adaptation of the encapsulation or shrouding to enclose the ends of the ducts. Any further heating means will be between the regenerators and the unit 1, while any further cooling means will be between the regenerators and the unit 4. Figure 6 . shows the two rotatable structures isolated, for simplicity. There will of course be a connection to one or the other in order to get work out, in the case of an engine, or to put work in, in the case of a pump. The shafts 13 and 17 can be suitably adapted. It will be understood that while a simple embodiment with three-sided pistons operating in two-lobed chambers has been described, there could be more elaborate arrangements with n+l(n>2) sided pistons in n-lobed chambers connected by a corresponding number of ducts with regenerators. The relative speeds of rotation of the chambers to the pistons will be n+1:n. WE CLAIM 1. An improved rotary piston machine comprising two variable- volume units (1,4) each unit (1,4) having a rotary multi-lobed epitrochoidal chamber (3,6) and a multi-sided rotary piston (2,5) forming therein a plurality of individual sub-chambers (3a, 3b,3c,6a,6b,6c) by its co-operation with the periphery of an associated chamber, the number (n + 1) of piston sides being greater by one than the number (n) of epitrochoid ares, wherein the two chambers (3,6) are constrained to rotate at a first common speed about a first effective common axis through their centers while the two pistons (2,5) are constrained to rotate at a second common speed about a second effective common axis through their centers in a same direction, the ratio of first to second common speeds being n+l:n, wherein each chamber (2,5) has a plurality (n) of dual-function ports (7,8,9,10) enabling connection between the chambers (2,5) via ducts (10,11) and wherein said ducts (10,11) each contain a regenerators, enabling one variable-volume unit (1) to perform intake, expansion and exhaust, while the other unit (4) performs intake, compression and exhaust, as a result of the relative rotation and port positions. 2. The rotary piston machine as claimed in claim 1, wherein heating means are provided for the variable-volume unit (1) which performs the expansion processes. 3. The rotary piston machine as claimed in claim 2, wherein heating means are provided between each said regenerator and the variable-volume unit which performs the expansion processes. 4. The rotary piston machine as claimed in claim 1,2 or 3, wherein cooling means are provided for the variable volume unit (4) which performs the compression processes. 5. The rotary piston machine as claimed in claim 4, wherein cooling means are provided between each said regerator and the variable volume unit (4) which performs the compression processes. 6. The rotary piston machine as claimed in any preceding claim 1, wherein n=2. 7. The rotary piston machine substantially as hereinbefore described with reference to the accompanying drawings.

Full Text

This invention relates to rotary piston machines. It
is concerned with an adaptation of the Stirling principle,
with multi-sided rotary pistons operating in chambers with
epitrochoidal lobes, the working fluid or vapour undergoing
closed thermodynamic cyclic processes. The machine may
operate as an engine or as a heat pump.
According to the present invention there is provided a
fluid or vapour rotary piston machine including two
variable-volume units, each unit having a rotary multi-lobed
epitrochoidal chamber and a multi-sided rotary piston
therein forming a plurality of invididual sub-chambers by
its co-operation with the periphery of the associated
chamber, the number (n+l) of piston sides being greater by
one than the number (n) of epitroichoid arcs, wherein the
two chambers are constrained to rotate at a first common
speed about a first effective common axis while the two
pistons are constrained to rotate at a second common speed
about a second effective common axis, the ratio of first to
second common speeds being n+l:n, wherein each chamber has
a plurality (n) of dual-function ports enabling connection
between the chambers via ducts, and wherein said ducts each
contain a regenerator, enabling one variable-volume unit to
perform intake, expansion and exhaust, while the other unit
performs intake, compression and exhaust, as a result of the
relative rotation and port positions.
Preferably, the chambers will be co-axial, as will be
the rotors. That simplifies construction. But they could,

in theory, be on different axes but coupled tc rotate in
liaison. The term "effective" is intended to cover this
alternative.
Heating means may be provided for the variable-volume
unit which performs the expansion processes, and there could
be further heating means between each said regenerator and
the variable-volume unit which performs the expansion
processes.
Cooling means may also be provided for the variable-
volume unit which performs the compression processes, and
there could be further cooling means between each said
regenerator and the variable-volume unit which performs the
. compression processes.
In the preferred form n=2, so that there are three
sided pistons operating in double-lobed chambers.
The expansion unit which may, but not necessarily, be
heated, will have its ports disposed in such a way that the
chambers formed therein are increasing in volume generally
when not in communication with a port and decreasing in
volume generally. when said chambers are in communication
with a port. The other, compression unit which may, but not
necessarily, be cooled, will have its ports disposed in such
a way that the chambers formed therein are decreasing in
volume generally when not in communication with a port, and
increasing in volume generally when said chambers are in
communication with a port. Work processes thus occur in
chambers isolated from port openings, while the transfer of
working fluid or vapour occurs between a pair of chambers

each in communication with ports opening to a common duct.
If high-grade heat transfer is accomplished to the working
fluid or vapour flowing to, from or contained within, the
expansion unit, while low-grade heat transfer is
accomplished from the working fluid or vapour flowing to,
from, or contained within, the compression unit, the machine
behaves as an engine, with mechanical work output. If
mechanical work is applied to the rotating components, but
low-grade heat transfer is accomplished to the region of the
expansion unit while high-grade heat transfer occurs from
the region of the compression unit, the machine behaves as
a heat pump or refrigerating machine.
For a better understanding of the invention, reference
will now be made by way of example, to the accompanying
drawings, in which:
Figures 1, 2, 3,4 and 5 are schematic diagrams showing
the relative positions of expansion and compression units of
a rotary piston machine at intervals during a cycle of
rotation, and
Figure 6 is a diagrammatic cross-section through a
preferred embodiment of the machine.
An expansion unit 1 has a rotary piston 2 contained in
a chamber 3 and a compression unit 4 has a rotary piston 5
contained in a chamber 6. Each piston 2 and 5 is of flat,
generally equilateral triangular form, but with the sides of
the triangle convex and arcuate. Each chamber 3 and 6 is
also flat, closely to confine the faces of the piston, and
is of two-lobed epitrochoidal form. The chambers thus have

major and minor axes intersecting at right angles at their
centres. The two units 1 and 4 are rigidly linked to rotate
about a common axis through their centres in the same
direction and at the same speed, the major axes of the
chambers 3 and 6 being at 90° to each other. The two rotary
pistons 2 and 5 are also rigidly linked to rotate about a
common axis through their centres in the same direction and
at the same speed, this being two thirds the speed of
rotation of the chambers 3 and 6. The arcuate sides 2a, 2b
and 2c of the piston 2 are disposed at 180° to the
counterpart sides 5a, 5b and 5c of the other piston 5. The
sides of the pistons 2 and 5 co-operate with the profiles of
the respective chambers 3 and 6 to form sub-chambers 3a, 3b
and 3c and 6a, 6b and 6c, of variable volume and shape in
operation, as described below.
Ports 7 and 8 in the expansion unit 1 are diagonally
opposite each other and offset 30° in the direction of
motion (clockwise as seen in Figures .1 to 5) from the minor
axis of the chamber 3. Corresponding ports 9 and 10 are
similarly disposed in the compression unit 4, but are offset
by 30° in the direction opposite that of rotation from the
minor axis of the chamber 6. This positioning ensures that
during operation a port, 7 or 8, is about to open to a sub-
chamber when that sub-chamber is at maximum volume in the
expansion unit 1. Similarly, a port, 9 or .10, has just
closed to a sub-chamber when that sub-chamber is at maximum
volume in the compression unit 4. The expansion unit port 7
is linked by an interconnecting duct 11 to the compression

port 9 diagonally opposite with reference to the axis of
rotation of the units 1 and 4, while the expansion unit port
8 is similarly linked by an interconnecting duct 12 to the
compression unit port 10. These ducts each contain a
regenerator (not shown).
The sequence of operation is as follows.-
In Figure 1, heated working fluid or vapour occupies
the sub-chamber 3a, which is at minimum volume and is open,
via the port 8, to the duct 12. The sub-chamber 3b is
isolated and increasing in volume. The sub-chamber 3c is
decreasing in volume, thereby expelling working fluid or
vapour via the port 7, through the duct 11. The fluid or
vapour is giving up, in the case of an engine, or taking up,
in the case of a heat pump, heat within the regenerator in
that duct 11. Cooled working fluid or vapour occupies the
chamber 6a which is at maximum volume, isolated, and about
to start its compression cycle. The sub-chamber 6b is in
its compression cycle, is decreasing in volume and isolated.
The sub-chamber 6c is increasing in volume and is open, via
the port 9, to the duct 11. It is therefore receiving the
working fluid or vapour from the sub-chamber 3c. The port 10
is closed by the piston 5.
In Figure 2 the pistons 2 and 5 have rotated clockwise
by 30° and the chambers 3 and 6 by 45°. The sub-chamber 3a
is increasing in volume and accepting working fluid or
vapour, via the port 8, from the duct 12 and from the sub-
chamber 6b, which continues to decrease in volume and now
communicates with the port 10. The sub-chamber 3b continues

to increase in volume, with the isolated heated working
fluid or vapour therein being expanded, while the transfer
of working fluid or vapour continues from the sub-chamber 3c
to the sub-chamber 6c via the port 7, the duct 11, and the
port 9. The cooled working fluid or vapour in the sub-
chamber 6a remains isolated and is compressed as the volume
of that -sub-chamber decreases.
In Figure 3 the pistons have rotated through 60° from
their initial, positions and the chambers by 90°. The sub-
chamber 3a continues to increase in. volume, but the piston
2 closes the port 8, thereby terminating the ingress of
working fluid or vapour, whereupon the expansion process
commences within that sub-chamber. The sub-chamber 3b has
attained its maximum volume, and the heated working fluid
therein has reached the end of its expansion process, while
the sub-chamber 3c continues to decrease in volume with the
egress of working fluid or vapour, via the port 7, the duct
11 and the port 9 to the compression unit 4. The cooled
working fluid continues to be compressed in the isolated
sub-chamber 6a as the volume therein decreases. The sub-
chamber 6b is at minimum volume and open, via the port 10,
to the duct 12, but the working fluid or vapour ceases to
flow due to the closure of the port 8. The sub-chamber 6c
continues to increase in volume and to accept the working
fluid or vapour, via the port 9, from the sub-chamber 3c.
In Figure 4 the pistons 2 and 5 have moved on another
30° and the chambers 3 and 6 another 45°. The sub-chamber
3a is isolated and increasing in volume, with the heated

working fluid therein continuing its expansion process. The
sub-chamber 3b now communicates with the port 8 as that is
uncovered by the piston 2 and, since that sub-chamber is
decreasing in volume, the working fluid or vapour therein is
forced out into the duct 12. The sub-chamber 3c continues to
decrease in volume, and transfer of working fluid or vapour,
via the port 7, the duct 11 and the port 9, continues to the
compression unit 4. The sub-chamber 6a remains isolated and
decreasing in volume, with the cooled working fluid or
vapour therein continuing its compression process. The sub-
chamber 6b is now increasing in volume and, due to its
communication with the port 10, accepts the working fluid or
vapour from the sub-chamber 3b via the duct 12. The sub-
chamber 6c continues to increase in volume and the ingress
of working fluid or vapour continues, via the port 9 and the
duct 11, from the expansion unit 1.
In Figure 5 the pistons are 120° from their original
positions and the . chambers 180° from theirs. The sub-
chamber 3a continues to increase in volume, with the heated,
isolated working fluid therein continuing its expansion
process. The sub-chamber 3b continues to decrease in volume,
with its working fluid or vapour passing via the port 8, the
duct 12, and the port 10 to the sub-chamber 6b which is
increasing in volume. The sub-chamber 3c is at minimum
volume and open, via port 7, to the duct 11, but the
compression unit piston 5 has closed the port 9, and so the
working fluid or vapour ceases to flow. The sub-chamber 6a
is still isolated and decreasing in volume, with the cooled

working fluid therein at the end of its compression process.
The sub-chamber 6b continues to accept the transferred
working fluid or vapour from the expansion unit 1. The sub-
chamber 6c, now isolated due to the closure of the port 9,
is at maximum volume with the working fluid or vapour
therein at the commencement of its compression process. The
situation within the machine is now similar to that of
Figure 1, although the various bodies of working fluid or
vapour occupy different spaces to those in the earlier
diagram.
Consider the body of cooled working fluid in the sub-
chamber 6a in Figure 1 at the commencement of its
compression process. As the units 1 and 4 rotate through
180° and the rotary pistons 2 and 5 rotate through 120°, the
relative rotor rotation will be 60° in the opposite
direction-. This finds the body of fluid in sub-chamber '6a
at the end of its compression process in a similar situation
to that of the cooled working fluid or vapour in the sub-
chamber 6b in Figure 1. After a further 30° of relative
rotor rotation (corresponding to the Figure 3 positions) the
sub-chamber 6 a will be at minimum volume, and the major
proportion of the working fluid or vapour that was therein
will have transferred to the sub-chamber 3c via the port 9,
the ducts 11 and the port 7, absorbing; in the case of an
engine, or rejecting, in the case of a heat pump, heat
during its passage through duct 11. At this point, where .
the total relative rotor rotation is 90°, the piston 2 will
have passed the port 7. The expander sub-chamber 3c allows

expansion of the heated working fluid or vapour therein
until a further 60° of relative rotor rotation has occurred
(making the total 150°), when the sub-chamber 3c is at
maximum volume. Further rotation uncovers the port 8,
allowing egress of heated working fluid or vapour via the
duct 12, in which it is cooled in the case of an engine, or
heated in the case of a heat pump. It then enters the sub
chamber 6c via the port 10, this transfer process occurring
over a further 90° of relative rotor rotation, the total
then being 240°, when the sub-chamber 3c will be at minimum
volume. The piston 5 now covers port 10 and the
thermodynamic cycle involving this particular body of
working fluid or vapour is repeated.
The processes may be tabulated over 360° of relative
rotor rotation, corresponding to 720° of piston rotation and
1080° of chamber rotation, as set out below in Table 1.
The closed thermodynamic cycle described above occurs
and repeats, with phase displacement, with four main bodies
of working fluid or vapour. In Figure 1, these are located
in sub-chamber 6a at the commencement of compression, in
sub-chamber 6b towards the end of compression, in sub-
chambers 3c and 6c and duct 11 undergoing regenerative
transfer, and in sub-chamber 3b undergoing expansion. The
residual working fluid or vapour in sub-chamber 3a is
awaiting mixing with the main body of working fluid or
vapour in the sub-chamber 6b. It will be noted that work
processes in both the expansion and compression units are of
equal duration, namely 60° of relative rotor rotation.

Working fluid or vapour regenerative transfer from the
compression unit 4 to the expansion unit 1 is always to a
sub-chamber of dissimilar designation, that is, 6a to 3c, 6b
to 3a and 6c to 3b, and is of short duration, namely 30° of
relative rotor rotation. Working fluid or vapour
regeneration transfer from the expansion ' unit 1 to the
compression unit 4 is always to a sub-chamber of similar
designation, that is, 3a to 6a, 3b to 6b and 3c to 6c, and
is of long duration, namely 90° of relative rotor rotation.
If the units 1 and 4 are of equal size, which is not a
necessity, the geometry ensures that this latter transfer
occurs under constant summed volume.
The regenerative transfer of any one main body of
working fluid or vapour is always accomplished alternately
between the two ducts 11 and 12. That is, transfer from one
unit to the other via one duct is always followed, by the
return transfer via the other duct. Because of the pairings
of sub-chambers during those transfers, any one main body of
working fluid or vapour will eventually be transported
through every sub-chamber within the machine, allowing mass
and energy balances of the working fluid or vapour to be
attained rapidly.
The route followed by one main body of working fluid or
vapour may be. tabulated over 720° of relative rotor
rotation, corresponding to 1440° of piston rotation and
2160° of housing rotation, as shown below in Table 2. The
main body of working fluid or vapour under study in that
table is that which appears in sub-chamber Sa in Figure 1,

at the start of its compression process. It can be seen to
undergo three complete thermodynamic cycles before it
returns to that sub-chamber 6a, after passing through all
the other sub-chambers of the machine. A second main body of
working fluid or vapour which appears in sub-chamber 6b in
Figure 1, undergoing its expansion process, will follow an
identical route to that shown in Table 2, with a phase
displacement of +360° relative rotor rotation from that
shown in Table 2. A third main body of working fluid or
vapour which appears in sub-chamber 6b in Figure 1, towards
the end of its compression process, will follow a similar
route, but with the ducts interchanged so that expansion
unit to the compression unit transfers are made via the duct
11 whilst the reverse transfers are made via the duct 12,
with a phase displacement of +180° relative rotor rotation
from that shown in Table 2. The fourth main body of working
fluid or vapour which appears in sub-chambers 3c and 6c and
duct 11 in Figure 1, undergoing regenerative transfer to the
compression unit, will follow an identical route to that of
the third main body of fluid or vapour, with a phase
displacement of -180° relative rotor rotation from that
shown in Table 2 . The machine therefore provides for a total
of twelve thermodynamic cycles over the period defined by
1440° of piston rotation, corresponding to 2160° of chamber
rotation and 720° of relative rotor rotation.
It.should be noted that each individual thermodynamic
cycle occurs over a period defined by 24 0° of relative rotor
rotation, that is, 480° of piston rotation and 720° of

chamber rotation. Whichever component, whether the coupled
pistons 2 and 5 or the coupled units 1 and 4 is employed as
the engine work output medium or . heat pump work, input
medium, the thermodynamic cycles have a longer duration than
those occurring in conventional reciprocating heat engines
and reciprocating heat pumps. These must, perforce, occur
over 360° of the output, or input, shaft rotation. This
feature of the rotary machine described above allows
enhanced heat transfer processes, enabling the theoretically
ideal thermodynamic cycle to be approached.
In Figure 6, the two units 1 and 4 are rigidly coupled
by a hollow shaft 13 journalled at 14 and 15 in a fixed
mounting 16. The pistons 2 and 5 are carried by a common
shaft 17 journalled at 18 and 19 in the mounting 16. The
ports 7, 8, 9 and 10 are in the flat radial sides of the
chambers 3 and 6, near their peripheries, and are open and
closed by the flat faces of the pistons 2 and 5. A gear
coupling 20 between the shafts 13 and 17 ensure that the
units 1 and 4 rotate relatively to the pistons 2 and 5 in
the manner described.
The units 1 and 4 can be encapsulated or shrouded to
distinct upper and lower temperature regions around them,
each unit presenting a large surface area for efficient heat
transfer. The rotation of those units promotes near-uniform
temperature distribution.
In addition to maintaining a temperature differential
between the units 1 and 4, there can be additional heating
and cooling means for the ducts 11 and 12 provided, for

example, by adaptation of the encapsulation or shrouding to
enclose the ends of the ducts. Any further heating means
will be between the regenerators and the unit 1, while any
further cooling means will be between the regenerators and
the unit 4.
Figure 6 . shows the two rotatable structures isolated,
for simplicity. There will of course be a connection to one
or the other in order to get work out, in the case of an
engine, or to put work in, in the case of a pump. The
shafts 13 and 17 can be suitably adapted.
It will be understood that while a simple embodiment
with three-sided pistons operating in two-lobed chambers has
been described, there could be more elaborate arrangements
with n+l(n>2) sided pistons in n-lobed chambers connected by
a corresponding number of ducts with regenerators. The
relative speeds of rotation of the chambers to the pistons
will be n+1:n.

WE CLAIM
1. An improved rotary piston machine comprising two variable- volume units
(1,4) each unit (1,4) having a rotary multi-lobed epitrochoidal chamber
(3,6) and a multi-sided rotary piston (2,5) forming therein a plurality of
individual sub-chambers (3a, 3b,3c,6a,6b,6c) by its co-operation with the
periphery of an associated chamber, the number (n + 1) of piston sides
being greater by one than the number (n) of epitrochoid ares, wherein the
two chambers (3,6) are constrained to rotate at a first common speed
about a first effective common axis through their centers while the two
pistons (2,5) are constrained to rotate at a second common speed about a
second effective common axis through their centers in a same direction,
the ratio of first to second common speeds being n+l:n, wherein each
chamber (2,5) has a plurality (n) of dual-function ports (7,8,9,10)
enabling connection between the chambers (2,5) via ducts (10,11) and
wherein said ducts (10,11) each contain a regenerators, enabling one
variable-volume unit (1) to perform intake, expansion and exhaust, while
the other unit (4) performs intake, compression and exhaust, as a result
of the relative rotation and port positions.
2. The rotary piston machine as claimed in claim 1, wherein heating means
are provided for the variable-volume unit (1) which performs the
expansion processes.
3. The rotary piston machine as claimed in claim 2, wherein heating means
are provided between each said regenerator and the variable-volume unit
which performs the expansion processes.

4. The rotary piston machine as claimed in claim 1,2 or 3, wherein cooling
means are provided for the variable volume unit (4) which performs the
compression processes.
5. The rotary piston machine as claimed in claim 4, wherein cooling means
are provided between each said regerator and the variable volume unit
(4) which performs the compression processes.
6. The rotary piston machine as claimed in any preceding claim 1, wherein
n=2.
7. The rotary piston machine substantially as hereinbefore described with
reference to the accompanying drawings.

Documents:

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Patent Number

272920

Indian Patent Application Number

IN/PCT/2000/533/KOL

PG Journal Number

19/2016

Publication Date

06-May-2016

Grant Date

03-May-2016

Date of Filing

20-Nov-2000

Name of Patentee

CERES IPR LIMITED

Applicant Address

NORTHERN TECHNOLOGIES, NETHERFIELD ROAD, NELSON, LANCASHIRE BB9 9AR, UNITED KINGDOM

Inventors:

#	Inventor's Name	Inventor's Address
1	WESLAKE-HILL, IAN.,	64 THORNHILL ROAD, LLANISHEN, CARDIFF CF4 6PF, GREAT BRITAIN

PCT International Classification Number

F04C18/063

PCT International Application Number

PCT/GB1999/01290

PCT International Filing date

1999-04-26

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	9808780.2	1998-04-25	U.K.