CA2466987A1 - Post mechanical, retromechanical and bimechanical motor machines (conclusion: interpretive additions) - Google Patents

Abstract

The present invention aims to complete our inventions previous examples by giving other examples of methods of compressive parts of rotativo-circular motor machines, by adding some comments on the interpretation of the movement of the compressive parts of which they are equipped, and this so that this object is well understood.

Description

Disclosure In our previous work, we specified that the three solutions rotary-type engines that appeared to us most likely to be put into practice effectively by the engine mechanics were the top-level, so-called gear methods hoop, of second level, said by polycarnés gears, and by poly induction, preferably semixansmittive or dynamic, and finally, third-degree, by dynamic Clokwise, cylinder or of blade, and preferably with a contrario movement of the parts.
(Fig.l) The present invention therefore simply intends to add, as a additional considerations relating to the previous objections.
The present invention therefore has for its first object to specify the origin of the Clokwise dynamics from the point of view of the method observation system to implement it. (Fig.2) The second purpose of this one will be to give some interpretation to better understand and distinguish the concepts of induction rising, descending, and semi transmittive, or transfers on themselves. (Fig.4) The third purpose of this one will serve to specify the margin of realization contrario movements, that is to say movement realize the machines in their engine form, compressive parts machines. (Fig. 5) The fourth part of this technical solution will consist of show other examples of support methods applicable for this type of machine, and how, again, we get them ~ ~ from basic induction methods, which have been subdivided into horizontalizant. (Fig. 6) Clok wise dynamics and type of observation.
As we have shown in our previous work, the mechanical compressive parts were carried out by the inventors at from given types of observation of the movement of the parts the mechanical and compressive nature of these machines, and therefore different observations were the consequence of mechanical type very different.
A first example of this statement is the observation of machines by an observation by a point of observation outside and fixed. In this case, it can be seen that the blade of the post-rotating machines turns at the same time sense, but at a reduced speed of that of the eccentric or the crankshaft.
This observation directly induces a control of the blade by a mechanical in producing the directional speed reduction appropriate. We mainly think of mechanics by mono Wankle induction, allowing to mechanize: machine figures Fixen, Cooley, Maillard, Sparrow. (Fig.2 a) A second example is to assume that the observation is rather proceeds from a point fixed on the eccentric of the machine. In this case, it is found that, invariably for the machines post and retro rotary, the blade moves in the opposite direction than that of the crankshaft. This type of observation will necessarily imply that one will aim to achieve mechanics whose goal will be to make an opposite movement of the blade to that of the eccentric.
The realized mechanics will be for example by gearing intermediate, by gear hoop, by gear heel. (Fig 2 b) A third example is to imagine a point of observation this once constructed in such a way as to be in continuous rotation in the same meaning as the blade and at its height. In this case, we see the secondary rotational movement of the blade, in the same direction as that of the observer. This method allows to realize the support by poly induction. (Fig 2.c) Subsequently, we can imagine two dynamic observation points, but located in opposite ways, which will better capture the poly double induction, as well as poly induction This observation is important not only because it allows to deduce the method by poly induction, but also, from this method, understand the statement that the actual crankshaft, in conventional machinery was made to wrongly fa ~ con confused with the blade, and what exists mainly two fa = con to correct this error, either by realizing it as a crankshaft master of a poly induction, either by realizing it, partially, or totally, confused with the cylinder, thus realized rotatively, and that of preferences in motion to contrario. From these only two ways, one manages to realize the master crankshaft, not in periphery, and confused with the blade.
A more specific look at the turning ratios of the blade compared to the eccentric, in conventional machines, and filming of subsidiary crankshafts and crankshaft master, shows well that the two methods realize the desired shapes of rotary shapes, inversely, but in identical ratios. Indeed, both ratio are one in three. The blade turns in fact by one turn, for three eccentric turns, while the master crankshaft also turns a turn, for three towers of secondary crankshafts. The provision center or periphery of these elements therefore gives the same result of figure, but opposite results from the point of view of the power, since one of the methods realizes the machine in its form compressive, and the other in its motor form.

That is why, the retrenchment of the action of the real master crankshaft, and the transfer of its rotativity to the cylinder, can also be realized in retrenching total or partial of this virtual crankshaft of the blade of conventional machines, to still achieve it in a confused way with the cylinder. The retrenchment of the virtual crankshaft of the cylinder will do by realizing a turning blade at the rate of one for one of the central eccentric, or central secondary crankshaft.
A final type of observation will be constructed assuming an observer located this time on the crankshaft master of poly induction. So located, the observer will observe both the Clokwise movement of the blade, and the retrorotational movement of the cylinder. (Fig.3 a) The realization of the machine by Clokwise blade is therefore the expression direct from this type of observation. (Fig. 3b) A last observation can be made by returning to the observation basic, ie from an outside observer, but by observing this time a machine with Clokwise blade movement. This observation makes it possible to subtract the subsidiary crankshafts from their location and dispose of them, in a single subsidiary crankshaft central, which will coordinate, with an induction, the movement in clokwise of pale.
Obtaining the dynamics of clokwise motion by transfer of dynamic crankshaft mait ~ e poly cylinder inductions As has been shown so far, the simplest method of to realize a dynamic in Clokwise of total blade, is to subtract the crankshaft master methods by poly induction, and do keep, to as a support for blades, that the subsidiary crankshafts, mounted rotatively in one side of the machine. The movement of crankshaft master will be compensated by the retro movement of the cylinder. (Fig.ld) Obtaining the dynamics of movement in Clokwise not transfer partial of the movement ret ~ orotative from blade to cylinder The ability to realize the clokwise movement machine with the help of a central eccentric finds its solution not from a observation from the outside, in which, as we have already mentioned, we note, for the triangular pale base figure, a blade movement occurring three times slower than the eccentric movement. In other words, the movement of the crankshaft is equivalent to three rotations per turn of blade. This constitutes a gap from the design of the prior art of these machines, which like us as already noted, attempts to lift each blade face successively.
The number of rotations of the crankshaft is therefore equivalent to the number of blade face.
We must rather observe the machine from an observation by the eccentric. It can thus be seen that the retro rotation of the blade is always, for triangular cases, is one-half of that of the rotation of the eccentric.
This finding allows us to state a different understanding reports of the movement of blade and crankshaft. Indeed, instead of understand that she rotates post rotatively three times more slowly that the eccentric, one will observe that it rotates retro rotatively, and orientationally, and that the number of retro rotations per turn is equivalent to one on the number of face of the cylinder.
On the basis of this observation, it may for example be said that, in the case of post rotary machines, the blade turns retro rotational a half turn per crankshaft revolution Always based on this observation, it will be easier to understand that if we stop, orientally the movement of the blade, we will be able to transfer in return realization to the cylinder, which will realize it.
In the case of first level inductions, therefore, the movement of the cylinder is obtained not by transfer of crankshaft movement real master, but rather, since the master crankshaft is found virtually and loosely in the blade in these machines, of that ci to the cylinder.
Obtaining the movement dynamics in Clokwise by transfer partial retrorotatory movement of blade to cyylinder As we have already shown, the achievements of the prior art have suffered from the virtual realization of the master crankshaft so confused with the blade, and among the first works allowing counter this gap and restore the machine to its effect of connecting rod, we we proposed the realization of the machine with crankshafts shelves.
Still taking as an example the rotary post machine triangular, during its realization this time it shelves, we will be able to find that the elements can be redistributed by subtracting crankshaft master and in doing so confused with the cylinder, which will then become rotatable. Horizontal displacement of the crankshaft master will force the layout to the center of the secondary crankshaft.
From then on we will see again that the rations are perfectly respected, since the rotation of the central crankshaft will be twice that of the cylinder, therefore equivalent, for a turn of it to its number of arcs, and not the number of arches of the blade, as it is the interpretation in the machines of the prior art.
So we see here that the redistribution is simply a moving the master crankshaft in such a way to realize it virtually in the cylinder, not in the blade, as it is ~ e case conventional machines, and secondaire crankshaft in the center, the pale keeping exactly the same ratio of retro-turning compared to this one, which proves the quality of redistribution.
It is therefore important to clarify that blade movement machines in Clokwise, when they are made with a single central crankshaft, are the result, in turn, of an observation that can be produced after mounting the machines in motion Clokvvise by poly induction ~ xe. Therefore, it is realized that the center of the blade realizes a circular stroke that can be produced by crankshaft.
So there is a series of observations, one of which is the fale of the others allow to realize the machines in movement Clokwise of blade, and which were not known from the prior art.
The prior art, let's repeat, considered the movement of the eccentric central as turning at the rate of three turns for one of that of the blade.
The movement of the blade can not be transferred directly to the cylinder here, without also changing the speed of the central crankshaft, such way that it is identical to that of the subsidiary crankshafts of the inductive poly machine, and that of the blade, identical to that of crankshaft Moorish, these speed determinations not being known to the prior art and changing the nature of the pieces in such a way that it was not known from the prior art.
The movement of rotary blade machines in Clokwise and rotary post figuration, defined in such a way that the crankshaft subsidiary, or the crankshaft rotates due to the number of sides of cylinder and not the number of blade sides, is a movement that falls poly induction and observation from it and can not by therefore be part of the previous year. Therefore this movement is original to our theory.

.. ~~. ~ s. ~ .. _ ~ w ... m. _ ~ r .. ~ r. ~~, m ~~ ... M ... ~. ~ __ ~ ...__ ~ _ Interpretation of induction methods, rising, descending, semi transmittedtives staged, turned on themselves.
The purpose of this letter is also to specify the originality of our work, point of view of support methods.
The prior art is clearly contained in mainly two rather rigid and problematic methods of support, namely the methods by mono induction and Wankle intermediate gear.
We have added to these methods a series of methods which can also be characterized by such as hoop gear methods, gear heel and so right now. These methods are called rising because they start from center of the machine, taking as support the support gear, and climbs to the induction gear located on the blade.
We have refined these methods by assuming a support gear dynamic, either central or tiered. In the second case, we speak by therefore a staged ascending method.
We then showed that we could use all methods support, this time in the opposite direction, by providing the blade with a support gear, and a rotating part mounted centrally with an induction gear. This time, it will be the movement of the part at the periphery which will cause the central rotary motion.
As an example, if we assume a Clokwise movement of pale made with the help of sliding parts. If subsequently the blade is provided of an induction gear and a central part of a gear induction, connecting the latter with a gear such as hoop, the Clokwise movement of the blade will cause a movement of cylinder reinterpretation.
~. ... z. ~ ".R ~ c ~,. ~ ~ ~~., ~~~. # ~. ~ _ ~~~~ .E ~. ~~ k, ~ - .. ~~ :. ~~~. ~~ w ~, ~. ~ .Nna ., ~.,. rt ~~ .. ~. ~ .M ~ _r. ~ m .. ~ _ ~ _ __ The cylinder is thus controlled by downlink induction by gearing hoop.
Another type of induction will be self-induction on itself, by semi transmission. In these inductions, it's about converting a movement center by another center movement. So the movement rotational cylindrical retro, may, instead of being made from a downward induction of blade, to be made by an inversion and reduced movement of the central crankshaft.
The present invention is simply for the effect of specifying what is meant by also by central movement a movement whose parts would be supported by the outside, and not by an axis, the center of rotation being then virtual.
These types of mechanics are not provided by the prior art because the prior art did not detect the most important interest of restoring to these Machine types the minimum number of component parts, three, and n, did not find that the best way, subsequently to dispose them, in such a way that control of the parts can be achieved without knocking, was to dispose of them, so to say horizontally, which supposes the participation of the cylinder in contrario that of the blade.
Movement with cont ~ a ~ ° io Similarly, in the prior art, we do not find the motor effect pushed at its maximum by the contrario movement of the compressive parts, blade and cylinder.
Of course, as we have shown, the figure both the most simple and the most perfect of contrario movements is that realizes when the blade or cylinder is moving in Clokwise.

The purpose of this letter is to specify that the realization of movements contrario, however, is not restrictive to these figures alone. Indeed, contrario movements are possible for post-rotating machines, for any retro blade movement whose speed in excess between that movement in Clokwise and the standard movement.
The increase in speed of the blade 's rotation, even for the same figure will then be compensated for by the cylinder's reverse rotation, in a lower proportion, however, than during the Ckokwise movement of blade.
The same logic applies during the contrario retrorotative movement per cylinder Clokwise. From then on the cylinder movement will no longer be in perfect Clokwise, and the rotary motion of the crankshaft will be falsified, these two elements, however, remain in movement on the contrary.
Straight movement and Clokwisc movement backstage For the case of realization of small pumps or small engines by example, the movements in rectiligno-alternative, or in Clokwise being preferential, it should be noted that they can also be made by slide.
In a first example, we realize a Hybrid machine, which even of retromotative figuration, provides, twice in four compression interesting. In fact, we note that contrary to what we found in simply first-degree machines, in which blade and cylinder rotates simply rotatively, here the blade has a rectilinear motion and the cylinder a rotational movement, which has as a result the blade penetrates less deeply into the corners, but deeper in the sides. This is understandable because the rectilinear is the limit of the retrorotative movement, (Fig.) A second example has already been given by ourselves, during comments on downward inductions. It is simply to specify that the movement in Clokwise can also be realized by slides, or sliding rods, for small applications.
Semi transmissive polyinduction We have specified that the induction of motion machines Clokwise, or second and third degree could be realized by the addition of more than one induction, arranged not in a staged manner, but by horizontal association. We have also specified that certain induction, including for example poly inductions, and poly induction semi transmittive were of a higher level in a natural way. We have shown that one could indeed divide the poly induction and realize clokwise blade movement machines.
The purpose of this letter is simply that it is possible in the same way divide and divide the inductions by semi transmative poly induction and dynamic.
In the first case, we will motivate the internal gear cylinder rotational by intermediate gears of semi transmission, no longer arranged on the master crankshaft, but on fixed axes of the machine. On fixed axes of the machine, the following subsidiary crankshafts supporting the blade.
It should be noted that one of the axes may not be fixed, but rather rotational to transport energy to the outside. It will be seen at this assembly that the rotation of subsidiary crankshafts causing the Clokwise movement of blade, will cause rotation of the gears of semi transmission which in turn will result in the cylinder. Assuming that the rotational output axis is set to one of the semi transmission gears, it will be seen that it will absorb the post rotary blade and retrorotative cylinder forces, and will couple them in a single output force.

The machine will therefore be driving. In addition, we will need more rod passing through it as in the case of poly machines simple fixed induction. It should be noted that more than one side of the cylinder can be opened and segmented in such a way; to let the gases pass and explosive fires.
Poly dynamic induction It will be noted that in the case of mounting machines by poly induction fixed, we can achieve a dynamic alternative poly induction, in such a way as to relieve the mechanical action.
Clokwise movement and polycammed gears.
It should be noted that, as we have specified, several times, all the machines can benefit from polycammed gears. In the case clokwise motion machines, as in others, the softening of the cylinder and the accelerations and decelerations successive parts will allow an increase in the length of the crankshafts and speed of blade compared to that of the crankshaft which will result in increases in power.
Brief description of the figures Figure I shows the first-level methods, known as gearing hoop in a), of second level, said by polycammed gears in b) and by poly induction, preferably served transmittive or dynamic in c), and finally, of third degree, by dynamic Clokwise, of cylinder or blade, and preferably with contrario movement parts in d).

Figure 2 shows the observation methods implemented in our previous work, and the resulting mechanics Figure 3 shows the observation methods implemented for realize the dynamics in Clokwise.
Figure 4 shows the Clokwise redistribution logic in motion from a standard poly induction.
Figure 5 shows the logic of redistribution from mechanics of first degree, as for example by mono induction.
Figure 6 shows the logic of redistribution from a logic of mechanics by staging. -Figure 7 shows once again, the advantages of more important Clokwise dynamics, which not only make it possible push on the blade which is equalized, and that, even in a superior way to that of a piston of piston machine, but also which allows to replace the contradictory movement within the same paxtie compressive, to achieve it in opposite movement between two parts compressive, which is a major advantage.
Figure 8 gives some additional interpretations allowing to better understand and distinguish the concepts of induction montanie, descending, and semi transmittive, or turned on themselves.
Figure 9 will be used to specify the margin of achievement of the movements at contrario, that is to say, movements enabling the machines in their engine form, compressive parses of machines. The limits of this are between the movements in Clokwise and the standard movement.
Figure 10 shows the unfolding for a turn of a movement to contrario lying between the movement in Clokwise and the movement standard. There are eight cuts, and therefore explosions, by turns, therefore a support for example by poly Gear ratio induction of one out of nine Figure 11 shows that we can realize the movements to pale rectilinear alternative, or with Clokwise movement through the wings.
In a) it is the cylinder which has a movement at the same time rectilinear and rotary, and only the rotary blade. In b) the movement in Clokwise of pale is provided by two sliding arrangements in combination. These arrangements, which do not require any gearing, are suggested for small rotary pumps.
Figure 12 shows for a lathe, a cylinder structure in action rectilinear-circular in conjunction with a circular blade action.
Figure 13 will show other examples of supports for this type of machine, and how, again a times, we obtain them from basic induction methods, which we have subdivided into the horizontal. Here the method is applied supports semi transmittive with two sets of gears semi transmittif, or only one.
Figure 14, a) shows that dynamic poly inductions are also applicable, as well as poly inductions or gear induction polycamés. It can be seen that the poly induction used carries tooth elision of the support gear, the effect of which is to neutralize alternatively the negative induction and to make work the effect of hinge of blade, named boomerang movement.
In b), it is simply shown that gears, even machines in Clokwise can be realized in a movement way, in such a way to realize the successive deceleration acceleration of the pieces.
Figure 15 shows that one of the parts can be made by poly induction, and the cylinder by induction served transmittive.
Figure 16 shows rather an arrangement whose service transmission reversive is performed by gears not pinion. Here the served transmission will be inversive, but the speed of the cylinder will be greater than that of the crankshaft.
Figure 17 shows that to not only make the speed of the cylinder reversive, but also decrease it compared to that of the crankshaft, one Raises the internal gear on the crankshaft, then the indirectly coupled by the use of intermediate gears descendants, to the blade gear, internal type, or external type.
Figure 18 shows that both structures can be made, one by one poly induction induction, and the other by poly induction down Figure 19 shows that one could limit the simplification of induction and realize them for one by a rising mono induction and for the other by a mono induction descendantel, these inductions being be placed on the same side, or on each side of the blade.

Detailed description of the figures Figure 1 shows the first-level methods, known as gearing hoop in a), of second level, said by polycammed gears in b) and by poly induction, preferably will be transmittive or dynamic in c), and finally, of third degree, by dynamic Clol ~ wise, of cylinder or blade, and preferably with contrario movement parts in d).
We believe that each of these guiding methods allows realize the rotary figurative machines in such a way as to improve performance and subtract defects.
The hoop gear method allows among other things a control of the induction gear 1 by an external coupling 2 of the hoop gear 3 Moreover, it allows the support of the blade by crankpin 4, and not eccentric, as is the case in machines standard. which greatly reduces friction. Finally, it allows a coupling part of the support gear 5 and the gearing induction 1, evening the hoop gear 3, whose rotation is slow and well centered.
Figure b shows the polycammed gear method. The position of polycammed gears can be diverse. Here, we have a position of the polycentric induction gear 6 in the direction of the blade 7, and the polycammed support gear 8 in the direction perpendicular to the 9. The result of this arrangement produces accelerations and favorable decelerations of the blade with respect to the constant speed of the eccentric. In particular here, there is a reduction in speed of the blade during its upper passage 10, which makes it possible to increase the compressive force of the machine, and an acceleration of the speed of this one, during the descent, ll, which allows him to catch up partly the speed of the eccentric, thereby reducing the contradiction of movement between these parts, blade and crankshaft.
Figure c) shows a dynamic poly induction method. This guy poly induction is very advantageous since allows, realizes a poly dual-part induction, the boomerang 12 construction of the movement of the blade, from a three-part poly induction of which the parties work alternately by the successive game of the parties active 13 and passive 14 gear drives.
Figure d) by boomerang movement totally evacuates contradictions between the crankshaft and the blade, and moves them between the blade and the cylinder 15, which makes the machine into. its function purely driving.
Figure 2 shows the observation methods used in our previous work, and the resulting mechanics It must be assumed that conventional mechanics, such particularly the mono induction method has been created from a observation of the parts by the outside I6, in which, what appears the more obvious, is that, for post rotary machines, the blade acts in the same direction, but in a slower way than that of the eccentric 18. This is a major flaw of rotating machines standard, since in these, the explosion is asked to produce two different speeds, one of which, that of the crankshaft will be in overspeed.
We have already proposed a second type of observation, called inside. Starting from this type of observation, of which the observer is here placed on the sleeve of the eccentric, I9, one realizes rather that the The blade is in reverse gear with respect to the eccentric 21. Again, this type of observation reveals a second fundamental deficiency conventional rotary machines, namely that the same explosive must be produced at the same time and simultaneously retrotect ~ .tion and rotation, which is contradictory.
Figure c) shows a type of observation constructed. In this one the observer is arranged on a piece itself in constant rotation with height of the blade.22 This observer will therefore see the circular motion of the blade tips 23. The addition of movements of observer 24 and observation 23 will allow create the basic poly induction method.
This observation will therefore enable the movement of the blade as an addition of two post rotary motions, and by consequently, to remove the pale from the contradictions created by from the first two observations.
Figure 3 shows the observation methods implemented for realize the dynamics in Clokwise.
In the first, an observer is located this time on the crankshaft master of an inductive poly machine.25 He can thus perceive at the same time the Clokwise movement of the blade 26, and the retro motion of the cylinder 27.
From then on, we will be able to realize the machine in a material way of such way that she respects the observation.
The realization of this machine will in turn produce observations from the outside and the inside 28. These observations will reveal that when the movement in Clokwise of blade, any point of the blade, and therefore the center 29 of it produces exactly the same rotation as the eccentrics and the spikes.

Therefore, this finding will reveal that one can replace the peripheral eccentrics with a central eccentric, and realize from it an induction of one on to achieve Clokwise movement of blade.
Figure 4 shows the Clokwise redistribution logic in motion from a standard poly induction. In this logic, the movement of the master crankshaft 30 is removed, and its realization is carried out in counter part by the rotation of the cylinder. The retro rotation of the cylinder 31 will be one turn for two crankshaft towers subsidiary 32, which is equivalent to the poly induction ratio.
Figure 5 shows the logic of redistribution from mechanics of first degree, as for example by mono induction. We have often mentioned that two of the main shortcomings of the machines standard was to have realized the movement of the blade by a movement excessive eccentric central, whose speed was to be thereafter diminished by the retro rotation of the blade. The second gap has therefore consisted in making the master crankshaft in a confused way with the blade.
As in the poly induction method, it is the master crankshaft which this time will be confused with the cylinder, printing it a rotation.
Indeed, if one examines the movement of the blade, from the point of view of a observer placed on the crankshaft, one realizes that the blade undergoes a retro rotation of a value of one half of that of the rotation of the Therefore, for example, after ~ a quarter of a turn of turning of the eccentric 34, one must produce a retro rotation of the blade one-eighth of a turn to realize the projected cylinder.
Therefore, if one plans to subtract the pale opposition crankshaft by subtracting from it its retrorotative movement orientational, so the master crankshaft component that is there, it will be necessary to defer this movement by realizing it in a confused way with the cylinder. So we will have a master crankshaft that turns to because of the same number of turns as the number of arcs of the cylinder, and this per cylinder revolution, which corresponds to the prescription of machines with Clokwise cylinder Figure 6 shows the logic of redistribution from a logic of mechanics by staging.
One this method, as in the poly inductïon, the master crankshaft will be moved horizontally and will be made in a confused way with the cylinder.36 The stepped crankshaft and blade will be returned to center 37.
As a result, the turning ratios of the blades, crankshaft and cylinder will be respected, since, the secondary crankshaft, disposed center will turn right two turns per cylinder turn, for this figuration, which corresponds to the number of roll arcs and not to number of sides of the blade, which is obtained p ~~ r poly induction, any Clokwise realization being an image of redistributed poly induction.
Figure 7 shows once again, the most important advantageous dice Clokwise dynamics, which not only make it possible push on the blade which is equalized, and that, even in a superior way to that of a piston of piston machine, but also which allows to replace contradictory movement within the same part compressive 38, to achieve it in opposite motion between two compressive part 39, which is a major advantage.
Figure 8 gives some additional interpretations allowing to understand and distinguish the notions of rising induction, descending, and semi transmittive, or turned on themselves.
In this figure, we summarize the set of rising inductances in saying that as a rule they have a support gear, fixed or dynamic located in the center of the machine, an induction gear located on the blade 41, and a gear, or a set of gears coupling of these 42. The orientational movement of the blade is therefore controlled, even on the periphery by this set.
Conversely, downward inductions start from a movement given peripherally and transforms them into rotary or retrorotative motion central. If we assume for example in b) a blade guide in Clokwise movement made by sliding parts 44. Thereafter, the blade is provided with a peripheral support gear 45 and a workpiece center of an induction gear 46. One couples these gears a third gear 47.
It will be realized then that during the rotation of the crankshaft and by consequence of the execution of the movement in Clokwise of blade, the central gear and the workpiece to which it is attached will rotate , hence the expression of descending induction.
In c) we find a poly semi transmissive induction. This type of poly induction was done by ourselves to make even the active part back of the blade. In this arrangement, the secondary crankshafts 48 and their induction gears 49 and semi transmission 50 are activated by their coupling to the support gear 51.
In d) one has a stepped induction, composed of two mono inductions, one with a fixed support gear 52, and the other with a support gear dynamic device 53.
In e) we finally have a dynamic in Clo: kwise semi support transmissive. 55 Figure 9 will be used to specify the margin of achievement of the movements at cont ~ a ~ io, that is to say, movements allowing to reelize the machines in their engine form, compressive parts of machines. The limits of this are between the movements in Clokwise and the standard movement.

For post rotary machines, the back rotation of the blade must be decreased to make a Clokwise move. If it is too much, the figure will become retrorotative, and will not be. more to the contrary:
We can therefore reduce it less appreciably than during a realization in Clokwise, and so take advantage of the opposite effect.
For example, after a quarter turn of the eccentric of a machine standard the blade has completed a one-eighth turn reversion 56.
In a Clokwise motion engine, she accomplished a retro rotation canceling the rotation of the eccentric, one to one, so a quarter turn, compared to the eccentric 57.
We will be able to realize a contrario movement with a retro blade rotation on the order of one sixth of a turn per quarter turn eccentric, without making a Clokwise movement, and this case, after a quarter turn the blade will be between the two points initial. 5 8 Another explanation for this may be produced from a external observation. View from outside the blade of a standard machine traveled an eighth of a turn, that of a movement in Clokwise a eighth. Therefore a blade movement of three thirty second The turn will be in contrario, but not in Clokwise.
Station 10 shows the unfolding for a turn of a movement at contrario lying between the movement in Clokwise and the movement standard. There are nine cuts, 60 and therefore explosions, by turns, therefore a support for example by poly gear ratio induction of one out of nine.
The Bure 11 is to show that one can realize the movements to pale rectilinear alternative, or movement in ClokW ise backstage.

In a) it is the cylinder which has a movement both rectilinear and rotary, and the only rotary blade In b) the movement in Clokwise of blade is provided by two sliding arrangements in combination 61. These arrangements, which do not require any gearing, are suggested for small rotary pumps.
Figure 12 shows for a lathe, a cylinder structure in action rectilinear-circular in conjunction with a circular blade action.
It shows that the rectilinear movement increases the depression of blades during compressions 62 and decreases the depression of their points during the expansions 63, which allows good compression ratons, even for retrorotative machines.
This type of arrangement will make it possible to realize retrorotative type with few parts and enough compression.
Figure 13 will show other examples of supports for this type of machine, and how, again a times, they are obtained from basic induction methods, which have been subdivided by horizontizing them. Here the method is applied supports will be transmittive with two sets. gears serai transmittif, or only one.
In this type of arrangement, the two-way transmission method will be redistributed, so to speak horizontally.
. As in the redistributed poly induction method for a arrangement in Clokwise, the crankshaft-master will be cut off, The initial suppori gear will become the induction gear of Cylinder 66 The Servo Transmission Gears 67 Will Be Arranged rotatively on shafts 68 and will be coupled to the gears induction device 70 of the blade induction crankshafts 71.

The internal cylinder induction gear will be attached to the cylinder 72.
The blade 73 will be connected to the induction crankshafts. It will be noted that blade may also be provided with support rods, inserted to the cams of the induction gears, which will ensure a better balanced. We choose here simply the arrangement for its ease of representation.
Pale and cylinder will see their respective induction gears coupled with the same support gears, which will produce the opposition of movement of these sought after parts.
We can also choose one of the support gears, to equip it an output axis 80, which will be birotative, since it will accumulate the forces post and retrorotative of the machine. Several other methods of exits can be made without changing the essence of the machine.
In b of the same figure, a single support gear is used to feed mechanically both the blade induction gears and the cylinder induction gear, and this gear, as previously is set to Machine Master Tax 80.
It should be noted that the support gear can also be made under the a doubled form 81 of it, for simple reasons material to keep the arrangements well positioned and focused It should be noted that coupling and coordination can also be achieved.
gears and parts to which they are connected by a chain 82, as as shown in Figure 3. Here crankshaft induction gears There are three secondary 83, and the chain connects them to the cylinder gear 84 Figure I4, a) shows that dynamic poly inductions are also applicable, as well as poly inductions or gear induction , r ~~~.,. w. ~.,. ~ .m ~ _ ~~ "~ re ~ n ~~ p ~., .... ~ .... ~ __.__.._ u .. .__.

polycamés. It can be seen that the poly induction used includes tooth elision of the support gear, the effect of which is to neutralize alternatively the negative induction and to make work the effect of hinge of blade, named boomerang movement.
In b), it is simply shown that gears, even machines in Clokwise can be realized in a movement way, in such a way to realize the successive deceleration acceleration of the pieces.
Figure IS shows that one of the parts can be made by poly induction 92, and the cylinder by induction served transmittive. Both inductions are united by the same set. Indeed, here we assume the master crankshaft 92 and the service induction gear transmission 94, are mounted on the same axis. It is assumed later that the dynamic support gears of the poly induction 98 and the cylinder induction gear 95 are rigidly connected between them and to the cylinder, 86, and that this set is coupled to the gear of served transmission by servo transmission gear 94.
Consequently, the rotation of the crankshaft simultaneously of the cylinder, and thus produces the mechanical effect compressive diagonal between the blade and the cylinder Figure 16 shows rather an arrangement whose service transmission reversive is performed by gears not pinion. Here the served transmission will be reversed, but the speed of the cylinder will be greater than that of the crankshaft.
Figure 17 shows that to not only make the speed of the cylinder reversive, but also decrease it compared to that of the crankshaft, one Raises the internal gear on the crankshaft, then the indirectly coupled by the use of intermediate gears descendants, to the blade gear, internal type 102, or type external 103.
Figure 18 shows that both structures can be made, one by a poly induction induction, 105, and the other by poly induction 107. In this case, the induction gears of the first 108 will be coupled or arranged on the same axis as the support devices of the second 109, which will in turn the central cylinder gear 110.
We will obtain once again the mechanico-compressive effect on the contrary and diagonally already described 99 Figure 19 shows that we could simplify the induction and realize them for one by a rising mono induction120 and for the other by a mono induction descendantel2l, these inductions being able being disposed on the same side, 123, or each side of the blade 122.
Once again, we will find the same desired motor effect 99 contrario, as much for the geometry as for the mechanics of the parts compressive.
It will be noted in these last figures the following facts. In all mechanical, when the movement of blade or cylinder is in Clok wise, the virtual master crankshaft is subtracted from the blade, and disposed to center, since it is confused with the rotational cylinder contrario.
When, for these mechanics, the contrario movement is not in Clokwise, only one bet of the crankshaft is subtracted from the blade, and Benific effects are added.
Finally, when the machine is made in movements ~ contrario, but not in clokwise, and moreover in poly induction of blade, it is a part of the movement of the Moorish crankshaft which is transferred to the cylinder, to produce the mechanical contrario effect. The <~ advantages of the machine are therefore divided between those of poly induction and those of the partfait Clokwise movement, but moreover, this type of machine as one showed it allows several explosions per turn for a blade having a large displacement, which a blade with several faces, but with a non dynamic could not achieve without producing cylinder corners too marked for the segments.
~ 9

Claims

claims Claims for which a property right is claimed are the following:

Claim 1 A machine whose figuration whose movement of parts compressive, blades and cylinders, is said contrario Claim 2 A machine as defined in 1, the constituent parts of which are the following:

- a body of the machine, in which is disposed the whole compressive, and the mechanical assembly a compressive assembly formed of a cylinder having a dynamic function, and a blade, also dynamic each of the compressive parts acting in contrast to each other, and at the limit, the Clokwise or rectilinear motion that can be part of this contrario movement Claim 3 A machine as defined in 1 and 2, including the compressive parts make circular or planetary movements and are supported by first-degree induction mechanics Claim 4 A machine as defined in 1, 2, 3, the compressive parts of which are contrario describe each of the second-level forms and are supported by second-degree mechanics Claim 5 A machine whose part of the contrario movement is realized by a compressive part whose movement is alternately rectilinear, or in movement Clokwise.

Claim 6 Of which the alternative rectilinear motion, or in Clokwise is that of the blade Claim 7 Including the alternative rectilinear motion, or in Clokwise is that of the cylinder.

Claim 8 A machine as defined in 1,2,3, whose contrario movement is performed by an action of the parts lying between the standard action, and the action by dynamic Clokwise Claim 9 A machine as defined in 1 and 2, whose redistribution, from made from a standard polyinduction, will be transmittive, or dynamic, by transferring the rotation of the crankshaft-master to a counter retrorotative portion made by a rotational cylinder.
Claim 10 A machine as defined in 1 and 2, including the. redistribution is realized from a standard mechanics, and whose orientational movement of the blade is subtracted and transferred to a counterpart, such as a cylinder rotational, within the limits of a contrario movement of these parts Claim 11 A machine as defined in 1, 2, 10, whose blade and cylinder are driven by mechanical counter sense, made from semi Inverse transmissions.
Claim 12 A machine as defined in 11, the axis of motricity of the machine is attached or coupled directly to the cylinder Claim 13 A machine as defined in 1, 2, 11, the blade induction of which is a induction selected from inductions with central eccentric, and a semi gear type reverse gear transmission Claim 14 A machine as defined in 1, 2, 11, the blade induction of which is a induction selected from inductions with central eccentric, and a semi gear-type reverse transmission with poly gears reverse induction, or periphery Claim 15 A machine as defined in 13, 14, whose blade is driven by poly induction.

Claim 16 A machine as defined in 15, one of the poly induction is made from a fixed support gear, and the second, partly d, dynamic support gears fixed on the same axes as the Induction gears and activating the central cylinder gear. <

Claim 17 A machine as defined in 15, one of which is guided by poly induction and the other of which the support gear, of internal type, is arranged on the crankshaft and actuates the cylinder gear through the use of one or more intermediate gears mounted on axes mounted on the wall of the machine, or on the back of the support gear.

Claim 17 A machine as defined in 1.2 whose rising inductions and descendants are first degree inductions, for example by mono induction rising and falling, each of these inductions being located on one side of the blade, where both induction are located on the same side.
Claim 19 A machine as defined in 1 and 2, including the. redistribution is achieved from horizontally redistributed staging mechanics, realizing the master crankshaft in a way confused with a cylinder becoming rotational by this, and arranging it centrally secondary crankshaft supporting the blade whose movement will be Clokwise.
Claim 20 A machine as defined in 5,6,7, the movement of which crankshaft or subsidiary crankshafts rotates due to the same number of sides of cylinder arc, and this for each turn of rotation of the cylinder.
Claim 21 A machine whose reciprocating rectilinear motion, or in Clokwise is made from sliding action in combination.
Claim 22 A machine as defined in one with more than one part compressive, and for each one a mechanical induction, these inductions mechanical being horizontal relative to one another, and these mechanical may be of first degree, second degree, or more, in such a way as to perform a non-rotating or planetary race of its part.

Claim 23 Whose mechanics put in composition are for the rising one, and the other descendant Claim 24 A machine as defined in 1 and 9, of which both sets mechanics put in coordination are for the rising one, and for the other turns on itself Claim 25 A machine as defined in 1 and 9, the mechanics of which are a redistribution of an initial mechanism of second degree or degree superior natural, in two mechanics put in coordination.

Claim 26 A machine as defined in 1 and 9 Claim 27 A machine, as defined in 1, 2, 3 including guiding machines compressive parts are realized by the coupling - a standard support mechanism of first, second, third degree, for the peripheral compressive part, so-called rising mechanics, and starting from this blade, or from this mechanical, a mechanical, so-called downward mechanical, guiding the rotation of the central compressive room.

Or, A rising mechanism for guiding the compressive part peripheral, and a mechanics turned on itself, starting from the eccentric, realize the rotation of the central parts.

Claim 27 A machine as defined in 1 and 2, including the compression part of periphery is the blade and the compression piece of the center, the cylinder.

Claim 28 A machine as defined in 1 and 2, including the compression part of periphery is the cylinder and the compression piece of the center, the blade Claim 29 A machine whose blade and cylinder movement is realized at from the redistribution of the mechanics of supports said by polyinduction served transmittive, the parts that can be described as after, - A blade in motion Clokwise made from support of double crankshafts - Crankshafts supporting the blade and named crankshaft of induction, these crankshafts being rotatably mounted by or on axes themselves mounted in the side of the machine, And these crankshafts being coupled by such means as gears induction to servo gears - transmission gear wheels rotatably mounted by or sir axes located in the side of the machine, these gears indirectly coupling the support and induction gears - a cylinder rotatably mounted in the machine, and provided with a internal support gear, itself coupled to the gears of semi transmission an output shaft, fixed rigidly to one of the induction gears or semi transmission, All of these parts being mounted in such a way that the Clokwise movement of the blade is synchronized to the movement retrorotative due cylinder Claim 30 A machine as defined in 9, including the two induction gears are coupled to a single, or a single set of semi gears transmission Claim 31 A machine as defined in 1 and 10, including the Clokwise movement is attributed to the cylinder and the rotary motion to the blade.
Claim 32 A machine as defined in 1, 9, 11, including at least one gear or set of gears is polycammed type.
Claim 33 A machine as defined in 1, 9, 11, including internal gears are replaced by a string Claim 34 A machine as defined in 1, 12, including subsidiary crankshafts are located in the center and periphery Claim 35 A machine as defined in one whose control in Clokwise is made by gear structure, gear heel, gear hoop, or by any method of first degree, with or without semi transmission.

Claim 36 A machine as defined in 1, one of the dimensions of the cylinder is missing, the side of the engine serving, with the help of segment to keep the compression.

Claim 37 Any machine as defined herein whose gears are support and induction are connected by a chain Claim 38 Any machine as defined in 1, one of whose inductions is realized with the help of a dynamic, central support gear, medium, or peripheral or tiered