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WO2006003678A1 - A piston assembly for an engine and an engine comprising the same - Google Patents

A piston assembly for an engine and an engine comprising the same Download PDF

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Publication number
WO2006003678A1
WO2006003678A1 PCT/IN2005/000226 IN2005000226W WO2006003678A1 WO 2006003678 A1 WO2006003678 A1 WO 2006003678A1 IN 2005000226 W IN2005000226 W IN 2005000226W WO 2006003678 A1 WO2006003678 A1 WO 2006003678A1
Authority
WO
WIPO (PCT)
Prior art keywords
piston assembly
pistons
pinions
housing
piston
Prior art date
Application number
PCT/IN2005/000226
Other languages
French (fr)
Inventor
Prasanta Ray
Original Assignee
Prasanta Ray
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Prasanta Ray filed Critical Prasanta Ray
Publication of WO2006003678A1 publication Critical patent/WO2006003678A1/en

Links

Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F01MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
    • F01CROTARY-PISTON OR OSCILLATING-PISTON MACHINES OR ENGINES
    • F01C1/00Rotary-piston machines or engines
    • F01C1/02Rotary-piston machines or engines of arcuate-engagement type, i.e. with circular translatory movement of co-operating members, each member having the same number of teeth or tooth-equivalents
    • F01C1/063Rotary-piston machines or engines of arcuate-engagement type, i.e. with circular translatory movement of co-operating members, each member having the same number of teeth or tooth-equivalents with coaxially-mounted members having continuously-changing circumferential spacing between them
    • F01C1/077Rotary-piston machines or engines of arcuate-engagement type, i.e. with circular translatory movement of co-operating members, each member having the same number of teeth or tooth-equivalents with coaxially-mounted members having continuously-changing circumferential spacing between them having toothed-gearing type drive

Definitions

  • the present invention relates to a piston assembly for an engine
  • engine is the reciprocating, spark-ignition, otto engine in which a
  • Valves open and close inlet and exhaust ports at
  • Palleja engine This engine is a mix of the off-centre rotating piston
  • a cylindrical rotor mounted off-centrally within a cylindrical housing carries radially arranged vanes that can move out and
  • the vanes alternately push out and draw in as the
  • cylindrical member rotates so that the chambers alternately expand
  • Wankel engine A triangular piston (rotor) with convex sides rotates
  • an elliptical rotor rotates within a triangular cavity with rounded edges creating three chambers between the sides of the
  • the chambers alternately expand and shrink
  • Hybrid engine This engine is a mix of the reciprocating engine and a
  • Ball-piston engine This is very roughly like the Palleja engine
  • Rotating vane engine This is basically a turbine but with intermittent
  • Rotary opposed piston engine Two pairs of pistons rotate
  • the present invention has tangential thrust and, even though having
  • the presently disclosed piston assembly comprises (a) an assembly of
  • pistons comprising at least one pair of rotating pistons provided in a
  • the assembly of pistons comprises two coaxial pistons, preferably
  • the speed-control mechanism is mounted on the housing to link the
  • housing ignites the charge of each chamber at the desired instants - namely,
  • ports built into the housing allow induction and evacuation of fuel charges.
  • the inlet and exhaust ports are apertures only and are opened and closed by
  • the present invention relates to a piston assembly
  • i o comprising a housing provided with an assembly of rotating pistons
  • the present invention also relates to a four-stroke engine as and when
  • the housing is preferably
  • cylindrical housing and the pistons are preferably butterfly-shaped pistons.
  • the pistons have substantially "V"-shaped wings joining at the center and
  • pistons further comprise the holding means at the center, wherein the
  • tube of one of the pistons is longer than the other.
  • the pistons are mounted in "X"-fashion in the housing
  • the housing further comprises a lid fitted onto projecting holding
  • the pistons are capable of periodically expanding and contracting while
  • i o speed control means is mounted on the housing on its outside and comprises
  • the pins are provided on the upper surface, preferably near the peripheries of the respective pinions, more
  • the pins are provided at the same radial distance from the axis of
  • this pin levels with free end of pin of another small pinion.
  • the flywheel is provided with a groove on one of its face, preferably
  • flywheel when assembled faces towards a pinion of smaller diameter
  • the flywheel is provided with an axle on
  • Fig.1 illustrates an exploded view of the assembly of pistons
  • Fig.2 illustrates an isometric view of the pistons assembled in the
  • Fig.3 illustrates an exploded view of the speed-control mechanism
  • Fig.4 illustrates an isometric view of the assembled speed-control
  • Fig.5 illustrates the piston assembly in accordance with the present
  • Fig.6 illustrates a schematic top view showing the essential compo-
  • Fig.7 illustrates the mechanism how the pins of the small pinions
  • H represents the housing of the present piston assembly provided
  • L represents the lid of the housing of the present piston assembly.
  • PPl and PP2 represent the piston-pairs of the present piston
  • Tl and T2 represent tubes attached to piston-pairs PPl and PP2
  • Each Chamber circles the axis of rotation of the piston-pairs and carriers an
  • BPl and BP2 represent two identical pinions of the speed control
  • SPl and SP2 represent two smaller and identical pinions of the
  • SPl engages BPl and SP2 engages BP2 so that, for exactly
  • Pl and P2 represent pins attached rigidly to SPl and SP2
  • Pl is longer than P2 and sticks out
  • W represents a window, preferably crescent-shaped window provided
  • this enables a certain degree of relative play between the two
  • FW represents flywheel, supported from one side by support S2,
  • the axis AFW of rotation of the flywheel lies on the (imaginary)
  • the axis AFW lies between the axis ASP and
  • G represents diametric groove running across one face of the flywheel
  • Sl and S2 represents supports for the small pinions and the flywheel
  • SP spark-plug
  • IP inlet port
  • EP represents
  • the "X" shape can narrow
  • piston-pairs form four chambers, preferably roughly "V"-
  • the speed-control mechanism controls the speed-control mechanism
  • SP2 is provided with a crescent-shaped window.
  • the speed control means further comprises two identical and coaxial
  • the big pinions BPl and BP2 are
  • BPl and BP2 also can rotate relatively to
  • the pins Pl and P2 are preferably
  • ends are level with each other.
  • the flywheel FW is provided with an axle A on one of its faces -
  • a diametrical groove G preferably running
  • the axis of rotation of the flywheel AFW lies between the axes of
  • the length of the groove G provided in the flywheel FW is sufficient
  • ASP 5 AFW and ABP are collinear and the groove G lies parallel to that
  • each small pinion periodically gains on, and falls back from, the other, angularly, so that, while rotating in the same direction, in the
  • each small pinion attains a state of zero
  • each small pinion attains
  • each big pinion attains a state of maximum angular gain on the
  • each piston-face of a given piston of a given piston-pair attains a
  • advance or retardation may be pre-programmed, if and as desired.
  • SP represents a fuel-injector
  • Induction stroke and the exhaust stroke can be pre-programmed through
  • the axle A of the flywheel may be considered to be the power

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Compressors, Vaccum Pumps And Other Relevant Systems (AREA)

Abstract

A piston assembly comprising a housing (H) provided with an assembly of rotating pistons, preferably at least a pair of rotating pistons (PP1, PP2) forming air-tight chambers (C1, C2, C3, C4) in the housing (H) and a speed control means mounted on the housing (H) for controlling speed of the rotating pistons in the housing (H) is disclosed. A four-stroke engine comprising the piston assembly is also disclosed.

Description

TITLE
A Piston Assembly for an Engine and an Engine Comprising the same
FIELD OF THE INVENTION
The present invention relates to a piston assembly for an engine and
5 an engine comprising the same. Particularly, it relates to a piston assembly
for a four-stroke engine and the engine comprising the same.
BACKGROUND OF THE INVENTION
The most common form of a four-stroke, internal-combustion, heat
engine is the reciprocating, spark-ignition, otto engine in which a
i o cylindrical piston moves up and down within a cylinder to create the
following four strokes: (a) the induction stroke, when a fresh fuel charge is
sucked in, (b) the compression stroke, when the charge is compressed, (c)
the power stroke, when the charge is ignited by a spark so that it burns and
expands producing motive energy, and (d) the exhaust stroke, when the
15 burnt charge is expelled. Valves open and close inlet and exhaust ports at
appropriate times to let in the fresh fuel charge and let out the burnt charge. These four strokes are repeated cyclically and the reciprocating motion is
converted to a rotary motion by means of a rod hinged to the bottom of the
piston at one end and to the periphery of a wheel at the other.
Another common form of the four-stroke, internal combustion engine
is the reciprocating, compression-ignition, diesel engine where the four
strokes are similar except that air is sucked in by the induction stroke and
compressed by the compression stroke to a high adiabatic temperature when
fuel is injected into the compressed air and ignites automatically from the
high temperature at the start of the power stroke.
i o One drawback of the reciprocating engine is that energy output loss
occurs from the fact that the direction of the thrust created by the expanding
charge is not the same as that of the motion of the output shaft.
Another drawback is the imbalances and vibrations caused by the
presence of a number of oscillating members such as the pistons and valves. An alternate genre of the four-stroke, internal-combustion, heat
engine is the rotary engine where, basically and ideally, (a) the thrust of the
expanding charge is tangential to the rotary motion of the output shaft, and
(b) there are few, if any, oscillating members; most members are rotary.
These features are expected to, and do, overcome, at least to an extent,
the drawbacks of the reciprocating engine mentioned hereinabove.
Many designs of the four-stroke, rotary, internal-combustion engine
have been, and continue to be, tried out. These may be very roughly be
categorized as (a) the off-centre rotating piston engines, (b) the rotating
i o vane engines, and (c) the orbital piston engines. Of many such designs,
some typical ones are described below in brief in their essentials. The ideals
of tangential thrust and absence of imbalances and vibrations are achieved in
these engines in varying measures.
Palleja engine: This engine is a mix of the off-centre rotating piston
1 5 and the rotating vane types. A cylindrical rotor mounted off-centrally within a cylindrical housing carries radially arranged vanes that can move out and
draw in. The vanes touch the inside of the cylindrical housing to create
enclosed chambers. The vanes alternately push out and draw in as the
cylindrical member rotates so that the chambers alternately expand and
shrink to create the four strokes.
Wankel engine: A triangular piston (rotor) with convex sides rotates
within a cavity of an oval shape having a slight constriction in the middle
called epitrochoid. The three edges of triangular piston remain in contact
with the walls of the cavity. The centre of rotation of the piston itself
I o circles, or orbits, the centre of the cavity over a small circumference. As it
rotates, the three chambers formed between the sides of the triangular piston
and the wall of the cavity alternately expand and shrink to create the four
strokes. The piston edges open and close the inlet and outlet ports; no vales
are necessary.
15 Epielliptical rotary engine : Somewhat similar to the Wankel engine
described hereinabove. Here, an elliptical rotor rotates within a triangular cavity with rounded edges creating three chambers between the sides of the
rotor and the wall of the cavity. The chambers alternately expand and shrink
to create the four-strokes.
Hybrid engine : This engine is a mix of the reciprocating engine and a
rotary engine. Reciprocating pistons-in-cylinders of the reciprocating engine
type are mounted tangentially around a common output shaft.
Ball-piston engine : This is very roughly like the Palleja engine
described hereinabove with balls replacing the vanes.
Rotating vane engine : This is basically a turbine but with intermittent
i o ignition as in reciprocating engines.
Rotary opposed piston engine : Two pairs of pistons rotate
intermittently around a common axis to create four chambers that alternately
expand, stay expanded for a moment, then shrink and stay shrunk for a
moment to produce the four strokes. BRIEF DESCRIPTION AND OBJECTS OF THE PRESENT INVENTION
The present invention has tangential thrust and, even though having
(angularly) oscillating members, suffers very little from imbalances
because, as shown hereinbelow, the acceleration of an oscillating member
is balanced by an equal deceleration of another identical member. It is a
four-stroke, internal-combustion, heat engine of both the spark-ignition and
the compression-ignition types. The description given hereinbelow
isexpressly for the spark-ignition type, but is also for the compression-
i o ignition type, for which, the spark-plug, see infra, will be considered
replaced by a fuel-injector.
The presently disclosed piston assembly comprises (a) an assembly of
pistons comprising at least one pair of rotating pistons provided in a
cylindrical housing, and (b) a speed-control mechanism for controlling the
1 5 speed of the pistons, mounted on the housing.
Figure imgf000007_0001
The assembly of pistons comprises two coaxial pistons, preferably
butterfly-shaped, diametrically-opposed and roughly "V"-shaped pistons,
mounted in "X"-fashion, within a cylindrical housing, with a certain
degree of angular play possible between them, thus forming four roughly
"V"-shaped air-tight chambers.
The speed-control mechanism is mounted on the housing to link the
piston-pairs so that they are capable of turning in the same direction, but
with periodically-fluctuating angular velocities, thereby causing the
aforesaid four chambers to periodically expand and contract while bodily
Q circling in the same direction about the axis of rotation of the piston-pairs.
Such periodic expansion and contraction causes each chamber to go through
the four strokes - viz. induction, compression, power and exhaust - of a
reciprocating four-stroke internal-combustion heat engine.
In accordance with the preferred embodiment of the present invention,
5 the speed-control mechanism, mounted on outside of the housing, causes maximum expansion and maximum contraction of every chamber to occur at
the same (angular) positions in the housing. A spark-plug fitted into the
housing ignites the charge of each chamber at the desired instants - namely,
roughly at the moments of maximum contraction - and inlet and exhaust
ports built into the housing allow induction and evacuation of fuel charges.
The inlet and exhaust ports are apertures only and are opened and closed by
the pistons themselves; valves, as in conventional reciprocating four-stroke
engines, are not needed for the purpose.
Accordingly, the present invention relates to a piston assembly
i o comprising a housing provided with an assembly of rotating pistons,
preferably at least a pair of rotating pistons forming air tight chambers in the
housing and a speed control means mounted on the housing for controlling
speed of the rotating pistons in the housing.
The present invention also relates to a four-stroke engine as and when
5' ϊ comprising a piston assembly as described herein. In accordance with the present invention, the housing is preferably
cylindrical housing and the pistons are preferably butterfly-shaped pistons.
The pistons have substantially "V"-shaped wings joining at the center and
are provided with undercuts at the center for fitting with each other. The
5 pistons further comprise the holding means at the center, wherein the
holding means in one of the pistons is on a face provided with the undercut
and in another piston is on the opposite face to the undercut. In accordance
with the preferred embodiment of this invention the holding means are tubes
and tube of one of the pistons is longer than the other.
i o In accordance with the preferred embodiment of this present invention
the pistons, when mounted in the housing, have certain degree of angular
play therebetween. The pistons are mounted in "X"-fashion in the housing
with the holding means of one piston passing through holding means of
another piston. The pistons, when mounted form "V"-shaped air-tight
2 5 chambers. The housing further comprises a lid fitted onto projecting holding
means of the pistons and a projection on the inner surface of the bottom to
hold the pistons.
In accordance with one of the preferred embodiments of this invention
5 the pistons are capable of turning in the same direction, but with
periodically-fluctuating angular velocities and the four chambers formed by
the pistons are capable of periodically expanding and contracting while
bodily circling in the same direction about the axis of rotation of the pistons.
According to another preferred embodiment of this invention the
i o speed control means is mounted on the housing on its outside and comprises
at least a pair of pinions of one size and at least a pair of pinions of another
size, and a flywheel, wherein one of the pairs of the pinions have larger
diameter / circumference than the another pair, preferably exactly twice the
diameter / circumference of the smaller pinions. The pinions having larger
15 diameter are provided with a pin. The pins are provided on the upper surface, preferably near the peripheries of the respective pinions, more
preferably the pins are provided at the same radial distance from the axis of
rotation of smaller pinions. The pin of one of the smaller pinions is longer
than the pin of the another pinion so that, when assembled, the free end of
5 this pin levels with free end of pin of another small pinion. One of the
pinions having smaller diameter is provided with a crescent-shaped window
for engaging pin of another pinion, The pinions having smaller diameter are
provided with a hole for engaging the support S 1.
The flywheel is provided with a groove on one of its face, preferably
i o running from one end to another end of the flywheel. The groove of the
flywheel, when assembled faces towards a pinion of smaller diameter and
engages pins of smaller pinions. The flywheel is provided with an axle on
the face opposite to the face provided with the groove. The flywheel is held
in place by a support S2 fitted on one end to the housing. The axis of
15 rotation of the flywheel lies between the axes of rotation of the smaller pinions and the larger pinions. The axes of rotation of the flywheel, me
smaller pinions and the larger pinions are collinear.
The other objects, advantages and the preferred embodiments of the
\ present invention will become more apparent from the following description
5 when read in conjunction with the accompanying drawings, which are not
intended for limiting the scope of the present invention, but are incorporated
for illustration of the present invention, particularly the best mode of the
present invention.
BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS
i o Fig.1 illustrates an exploded view of the assembly of pistons and the
housing of the piston assembly in accordance with the present
invention.
Fig.2 illustrates an isometric view of the pistons assembled in the
housing showing the pistons in place within the housing of the
15 piston assembly in accordance with the present invention. Fig.3 illustrates an exploded view of the speed-control mechanism
of the piston assembly in accordance with the present inven¬
tion.
Fig.4 illustrates an isometric view of the assembled speed-control
5 mechanism of the piston assembly in accordance with the
present invention.
Fig.5 illustrates the piston assembly in accordance with the present
invention.
Fig.6 illustrates a schematic top view showing the essential compo-
l o nents of the piston assembly and the spark-plug and inlet and
exhaust ports of an engine comprising the piston assembly of
the present invention.
Fig.7 illustrates the mechanism how the pins of the small pinions
draw towards and away from each other as the flywheel
15 rotates. DETAILED DESCRIPTION OF THE PRESENT INVENTION
In the accompanying figures the reference letters are common and
represent the following components and/or features:
H represents the housing of the present piston assembly provided
with a short, cylindrical projection, t, on the inner surface of the bottom of
the housing to engage tube T2.
L represents the lid of the housing of the present piston assembly.
PPl and PP2 represent the piston-pairs of the present piston
assembly.
Tl and T2 represent tubes attached to piston-pairs PPl and PP2
respectively, enabling the piston-pairs to be assembled together coaxially.
Cl, C2, C3 and C4 represent four roughly "V"-shaped air-tight
chambers formed by the piston-pairs of the present piston assembly. Each Chamber circles the axis of rotation of the piston-pairs and carriers an
independent fuel charge.
BPl and BP2 represent two identical pinions of the speed control
means of the present piston assembly fixed rigidly to the ends of the tubes
5 Tl and T2 attached to the piston-pairs. BPl is provided with a hole in the
centre.
SPl and SP2 represent two smaller and identical pinions of the
speed control means of the present piston assembly, each of a circumference
half that of BPl and BP2.
i o In accordance with one of the preferred embodiments of the present
invention SPl engages BPl and SP2 engages BP2 so that, for exactly
every one revolution of BPl (or BP2), SPl (or SP2) revolves exactly
twice.
Pl and P2 represent pins attached rigidly to SPl and SP2
1 5 respectively near the circumference at identical radial distances from the axis of rotation of SPl and SP2. In accordance with one of the preferred
embodiments of the present invention, Pl is longer than P2 and sticks out
through a window W provided in SP2.
W represents a window, preferably crescent-shaped window provided
in SP2.
In accordance with one of the preferred embodiments of the present
invention, this enables a certain degree of relative play between the two
small pinions SPl and SP2 by allowing Pl a certain freedom of angular
movement relative to SP2.
FW represents flywheel, supported from one side by support S2,
and having a groove G along a diameter substantially end to end.
In accordance with the preferred embodiment of the present invention,
when parts of the speed-control mechanism are properly assembled, the pins
Pl and P2 engage this groove. In accordance with another preferred embodiment of the present
invention, the axis AFW of rotation of the flywheel lies on the (imaginary)
line joining the axis ASP of rotation of the small pinions and the axis ABP
of rotation of the big pinions; the axis AFW lies between the axis ASP and
5 the axis ABP in such a manner that the (imaginary circle centred on the axis
ASP, and passing through the locations of Pl and P2, encloses the axis
AFW.
G represents diametric groove running across one face of the flywheel
FW and extending almost from end to end.
i o ASP, AFW & ABP represent axes of rotation of SPl and SP2
(coaxial), of FW and of BPl and BP2 (also coaxial) respectively.
Sl and S2 represents supports for the small pinions and the flywheel
respectively.
SP represents spark-plug, IP represents inlet port and EP represents
5 exhaust port of the engine. Now referring to accompanying figures, Figures 1 and 2 show how
the two piston-pairs PPl and PP2 are assembled coaxially together with
T2 passing through Tl. When so assembled, the piston-pairs form an
assembly, "X"-fashion, with a certain degree of mutual angular movement
5 or play possible thererbetween. In other words, the "X" shape can narrow
or widen within certain limits. When the piston-pair assembly is placed in
position within the housing H, the short cylindrical inner projection t of the
housing engages the tube T2, and with the lid L of the housing fastened
into place, the whole assembly looks like Figure 2, with portions of the
l o tubes Tl and T2 sticking out of the lid L, as shown, T2 a little more than
Tl.
In accordance with one of the preferred embodiments of the present
invention the piston-pairs form four chambers, preferably roughly "V"-
shaped air-tight chambers Cl, C2, C3 and C4, which can expand and
5 contract within certain limits. The expansion and contraction occur in pairs
of chambers Cl and C3 constituting one pair and C2 and C4 constituting the other pair. When the pair Cl and C3 expands, the pair C2 and C4
contracts, and vice versa.
In accordance with the present invention, the speed-control mechanism
- Figure 4 and Figure 3, comprises two identical and coaxial small pinions
5 SPl and SP2 provided with pins Pl and P2 respectively, mounted onto
the pinions SPl and SP2, and the flywheel FW provided with a diametrical
groove G across one face, namely, the one that faces SP2. In accordance
with the preferred embodiment of this invention, one of the small pinions
SP2 is provided with a crescent-shaped window.
i o The speed control means further comprises two identical and coaxial
big pinions BPl and BP2 attached to the ends of the tubes Tl and T2 of
the piston pairs pl and P2 respectively. The big pinions BPl and BP2 are
provided with a circular hole at their centre to enable them to be fitted onto
the tubes Tl and T2. Thus, BPl and BP2 also can rotate relatively to
5 each other within the same angular limits as those for the piston-pairs PPl
and PP2 and in correspondence with the latter. According to one of the preferred embodiments of this invention, the
circumference of the smaller pinions SPl and SP2 is exactly half that of the
big pinions BPl and BP2, and the small pinions SPl and SP2 are so
supported by the support Sl [Figure 5] provided on the housing H, that the
5 small pinions SPl and SP2 engage BPl and BP2 respectively, which
causes, for every one revolution of the big pinions BPl or BP2, two
revolutions of the small pinions SPl or SP2.
In accordance with this invention the pins Pl and P2 are preferably
attached near the peripheries of the small pinions SPl and SP2, and at the
j o same radial distance from the axis ASP of rotation of the small pinions SPl
and SP2. The pin Pl of the small pinion SPl projects out through the
window W of the small pinion SP2 and is longer than P2 so that their free
ends are level with each other.
The flywheel FW is provided with an axle A on one of its faces -
15 being the face away from the pinion SP2 and without a groove G - and is held in place by the support S2 [Figure 4 and Figure 5], which in-turn is
connected to the housing H. The other face - being the face towards the
pinion SP2 - of the flywheel faces the pinion SP2 and, as described
hereinabove, is provided with a diametrical groove G, preferably running
across it form end to end.
The axis of rotation of the flywheel AFW lies between the axes of
rotation of the small pinions and the big pinions ASP and ABP
respectively, and also on the (imaginary) line joining the ASP and ABP,
that is the ASP, AFW and ABP are collinear.
The length of the groove G provided in the flywheel FW is sufficient
to enable the pins Pl and P2 to engage therein G, sliding back and forth in
it, as the small pinions and the flywheel rotate.
The working principle is now explained as follows. Since the flywheel
FW is off-axial to the small pinions SPl and SP2, in a situation where the flywheel revolves with a constant angular velocity, the pins Pl and P2
periodically draw towards, and away from, the axis AFW of rotation of the
flywheel. A small pinion rotates fastest when its pin is farthest from the
AFW, and slowest when its pin is closest to the AFW [Figure 7]. Thus,
while the flywheel rotates with a constant angular velocity, the small pinions
rotate with periodically-fluctuating angular velocities, with each small pinion
going through one complete revolution, and one complete cycle of fastest-to-
slowest-to-fastest rotation, during one complete revolution of the flywheel.
Since the pins are located at the same radial distance from ASP, the fastest
and the slowest angular velocities of SPl and SP2 are the same. Besides,
the pins Pl and P2 are so constrained by the groove that when one is at its
closest to AFW, the other is at its farthest from it; in that situatin, Pl, P2,
ASP5 AFW and ABP are collinear and the groove G lies parallel to that
(imaginary) line of coUinearity. Thus, the phase difference between the two
small pinions SPl and SP2 is 180 degrees. As the flywheel rotates,
therefore, each small pinion periodically gains on, and falls back from, the other, angularly, so that, while rotating in the same direction, in the
absolute sense, they oscillate relatively to each other. The crescrent-shaped
window W of SP2 accommodates this oscillation by allowing the pin Pl
sufficient angular movement relative to SP2. During every one full
revolution of the flywheel FW, each small pinion attains a state of zero
relative angular motion with the other twice; namely, when their angular
velocities equal. This happens when the groove orients itself at 90 degrees
to the (imaginary) line joining ASP, AFW and ABP, so that Pl and P2
are located at the same radial diatance from AFW but in diametrically
opposite directions from the latter; in that situatin, each small pinion attains,
also, a state of maximum angular gain on, or of maximum angular lag
behind, the other. During every one revolution of FW, therefore, each
small pinion attains a state of maximum gain on the other once, and,
similarly, of maximum lag behind the other also once, with one full cycle of
relative oscillation occurring between the two small pinions in that period.
The big pinions, engaging the small ones, and executing a half-revolution for every full revolution of the small pinions, also go through the same cycle
of fastest-to-slowest-to-fastest rotation during every one revolution of the
flywheel but with the difference that each big pinion executes a half-
revolution only in that period. Over two full revolutions of the flywheel
5 therefore, each big pinion completes one full revolution and goes through a
double-cycle of fastest-to-slowest-to-fastest-to-slowest-to-fastest rotation; in
that situation, each big pinion attains a state of maximum angular gain on the
other twice, and that of maximum angular lag behind the other, also twice.
Such states of the big pinions coincide with similar states of the small
i o pinions. Whatever is true, in this respect, of the big pinions, is, clearly,
also true of the piston-pairs, for the former are attached rigidly to the latter.
Therefore, each piston-face of a given piston of a given piston-pair attains a
state of closest approach to the opposite piston-face, (belonging to the other
piston-pair), twice, and, likewise, farthest separation from such opposite
j 5 piston-face, also, twice, during every double-revolution of the flywheel
corresponding, as explained hereinabove, to every single revolution of each
Figure imgf000025_0001
piston-pair. In that period, therefore, each chamber - Cl, C2, C3 and C4
- executes a double-cyle of maximum contraction-to-maximum expansion,
thus: maximum contraction-to-maximum expansion-to-maximum
contraction-to-maximum expansion-to-maximum contraction.
5 It is clear that the chambers attain a state of maximum contraction, and
of maximum expansion too, in mutually-opposite pairs, simultaneously:
when chambers Cl and C3 attain maximum contraction — at diametrically-
opposite positions in the housing - the chambers C2 and C4 attain maximum
expansion, again at diametrically-opposite positions in the housing, with the
i o (imaginary) line of symmetry passing (diametrically) through C2 and C4. It
is also clear that such maximum contractions occur at the same pair of
diametrically-opposite positions, for both the pairs of chambers, Cl and C3,
or C2 and C4, and so also for maximum expansion. This is so because such
states of maximum contraction / maximum expansion of the chambers occur,
15 as seen hereinabove, when the flywheel groove orients itself at 90 degrees to
the (imaginary) line joining ASP, AFW and ABP, and, each piston-pair completes an exact half-revolution over every full revolution of the flywheel
which carries the groove. In other words, at the moment of maximum
contraction of any diametrically-opposite pair of chambers, the aforesaid
(imaginary, diametrical) line of symmetry is the same. A single spark-plug,
5 SP, shown in Figure 6, is fitted into the curved wall of the housing and is
positioned on such fine of symmetry passing through a pair of chambers in a
state of maximum contraction. It is made to fire, periodically, at
appropriate, pre-determined instants via the use of an appropriate means;
advance or retardation may be pre-programmed, if and as desired. For the
J o compression-ignition type of engine, SP represents a fuel-injector which
injects fuel periodically at appropriate instants. Inlet and exhaust ports, IP
and EP respectively as shown in Figure 6, are built into the same curved
walls of the housing and are so positioned, and have such angular widths,
that IP starts and stops letting in fresh fuel charges at appropriate,
j 5 predetermined instants, and, likewise, EP starts and stops evacuating burnt
charges at appropriate, pre-determined instants; the opening and closing of
the ports are done by the piston themselves, obviating the need for valves. It
is clear that such starting and stopping times are determined by the angular
width of the piston-pair extremities, the positions and the angular widths of
the ports, and the angular measures of maximum contraction and maximum
5 expansion of the chambers. If and as desired, an overlap too, of the
Induction stroke and the exhaust stroke can be pre-programmed through
appropriate choice of these parameters. The radial distance of the pins Pl
and P2 from ASP, and that of AFW from ASP, plus the angular width of
the piston-pairs, determine the measures of maximum contraction and
i o maximum expansion, which, in turn, determine the compression ratio. It is
evident that, over every two revolutions of the flywheel each chamber
executes the four-stroke cycle of induction, compression, power and
exhaust, once, so that a total of four such complete cycles occur in that
period. The axle A of the flywheel may be considered to be the power
15 OUtput.
The present invention has been described and illustrated with the help
of the accompanying drawings, which are not intended to limit the scope of
the present invention. Various modifications are possible without deviating
from the scope of the disclosed invention.
Figure imgf000029_0001

Claims

I CLAIM:
1. A Piston assembly comprising a housing provided with an assembly of
rotating pistons, preferably at least a pair of rotating pistons,
preferably at least a pair of rotating pistons forming air tight chambers
5 in said housing and a speed control means mounted on said housing for
controlling speed of said rotating pistons in said housing.
2. A piston assembly as claimed in Claim 1 wherein said housing is pre¬
ferably cylindrical housing.
3. A piston assembly as claimed in Claim 1 wherein said pistons are pre-
i o ferably butterfly-shaped pistons.
4. A piston assembly as claimed in Claim 1 or 3 wherein said pistons have
substantially "V"-shaped wings joining at the center.
5. A piston assembly as claimed in any one of the preceding claims,
wherein said pistons are provided with undercuts at the center for fitting
15 with each other.
6. A piston assembly as claimed in any one of the preceding claims,
wherein said pistons are provided with holding means at the center.
7. A piston assembly as claimed in Claim 6 wherein said holding means
in one of the said pistons is on a face provided with said undercut and
5 in another piston is on the opposite face to the same undercut.
8. A piston assembly as claimed in Claim 6 wherein said holding means
are tubes and tube of one of the pistons is longer than the other.
9. A piston assembly as claimed in any of the preceding claims, wherein
said pistons, when mounted in said housing, have certain degree of
i o angular play therebetween.
10. A piston assembly as claimed in any one of the preceding claims,
wherein said pistons are mounted in "X"-fashion in said housing
with holding means of one piston passing through holding means of
another piston.
11. A piston assembly as claimed in any one of the preceding claims,
wherein said pistons, when mounted form "V"-shaped air-tight
chambers.
12. A piston assembly as claimed in any one of the preceding claims,
5 wherein said housing is provided with a lid fitted onto projecting
holding means of said pistons.
13. A piston assembly as claimed in any one of the preceding claims,
wherein said housing is provided with a projection to hold the pistons.
14. A piston assembly as claimed in any one of the preceding claims,
l o wherein said pistons are capable of turning in th§ same direction, but
with periodically-fluctuating angular velocities.
15. A piston assembly as claimed in Claim 11 or 14 wherein said four
chambers are capable of periodically expanding and contracting while
bodily circling in the same direction about the axis of rotation of the
5 said pistons.
16. A piston assembly as claimed in Claim 1 wherein said speed control
means is mounted on the said housing on its outside.
17. A piston assembly as claimed in Claim 1 wherein said piston control
means comprises at least a pair of pinions of one size and at least a pair
5 of pinions of another size, and a flywheel.
18. A piston assembly as claimed in Claim 17 wherein said one of the
pairs of said pinions have larger diameter / circumference than the
another pair, preferably exactly twice the diameter / circumference
of the smaller pinions.
I O 19. A piston assembly as claimed in Claim 18 wherein said pinions
having larger diameter are provided with a hole.
20. A piston assembly as claimed in Claim 18 wherein said pinions
having smaller diameter are provided with a pin.
21. A piston assembly as claimed in Claim 20 wherein said pins are
provided on upper surface, preferably near the peripheries of the
respective pinions.
22. A piston assembly as claimed in Claim 21 wherein said pins are
provided at the same radial distance from the axis of rotation of
smaller pinions.
23. A piston assembly as claimed in Claim 20, 21 or 22, wherein pin of
one of the smaller pinions is longer than the pin of the another pinion
so that, when assembled, the free end of this pin levels with free end
of pin of another small pinion.
24. A piston assembly as claimed in Claim 18 wherein one of the said
pinions having smaller diameter is provided with a crescent-shaped
window for engaging pin of another pinion.
25. A piston assembly as claimed in Claim 18 or 24 wherein said pinions
having smaller diameter are provided with a hole for engaging the
support Sl.
26. A piston assembly as claimed in Claim 17 wherein said flywheel is
provided with a groove on one of its face, preferably ranning from one
end to another end of the flywheel.
27. A piston assembly as claimed in Claim 26 wherein said groove of
5 said flywheel, when assembled faces towards a pinion of smaller
diameter and engages pins of smaller pinions.
28. A piston assembly as claimed in Claim 17 wherein said flywheel is
provided with an axle on the face opposite to the face provided with
said groove.
i o
29. A piston assembly as claimed in Claim 28 wherein said flywheel is
held in place by a support S2 fitted on one end to the said housing.
30. A piston assembly as claimed in any one of the preceding claims,
wherein axis of rotation of said flywheel lies between the axes of
rotation of said smaller pinions and said larger pinions.
31. A piston assembly as claimed in any one of the preceding claims,
wherein axes of rotation of said flywheel, said smaller pinions and
said larger pinions are collinear.
32. A piston assembly substantially as herein described with the help of
foregoing description and as illustrated in the accompanying drawings.
33. A four-stroke engine as and when comprising a piston assembly as
claimed in any one of the preceding claims.
Figure imgf000036_0001
PCT/IN2005/000226 2004-07-05 2005-07-04 A piston assembly for an engine and an engine comprising the same WO2006003678A1 (en)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
IN386KO2004 2004-07-05
IN386/KOL/2004 2004-07-05

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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2013104968A1 (en) * 2012-01-12 2013-07-18 Dattatraya Rajaram Shelke System and methods for converting rotational to linear motion with non - zero force
WO2021070199A1 (en) * 2019-10-07 2021-04-15 Vipulkumar Dhirubhai Patel An internal combustion engine

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB582924A (en) * 1944-10-05 1946-12-02 Ryke Postumus Improvements in or relating to rotary internal combustion engines
GB1068170A (en) * 1963-01-22 1967-05-10 Aero Commerce G M B H Rotary piston machines
GB2007771A (en) * 1977-11-10 1979-05-23 Griffenthal Pty Ltd Rotary positive-displacement fluid-machines
WO2000079102A1 (en) * 1999-06-17 2000-12-28 Hugo Julio Kopelowicz A system of two or more rotors with at least one piston on each moving in the same direction at varying and alternatively opposite velocities to each other inside a cylindrical chamber, either independent or formed by the rotors themselves

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB582924A (en) * 1944-10-05 1946-12-02 Ryke Postumus Improvements in or relating to rotary internal combustion engines
GB1068170A (en) * 1963-01-22 1967-05-10 Aero Commerce G M B H Rotary piston machines
GB2007771A (en) * 1977-11-10 1979-05-23 Griffenthal Pty Ltd Rotary positive-displacement fluid-machines
WO2000079102A1 (en) * 1999-06-17 2000-12-28 Hugo Julio Kopelowicz A system of two or more rotors with at least one piston on each moving in the same direction at varying and alternatively opposite velocities to each other inside a cylindrical chamber, either independent or formed by the rotors themselves

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2013104968A1 (en) * 2012-01-12 2013-07-18 Dattatraya Rajaram Shelke System and methods for converting rotational to linear motion with non - zero force
WO2021070199A1 (en) * 2019-10-07 2021-04-15 Vipulkumar Dhirubhai Patel An internal combustion engine

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