CA2481427A1 - Reverse-rotating, post-rotating and bi-rotating engines (second part: concluding generalization) - Google Patents

Abstract

The object of the present invention is to supplement our work on the motor machines by generalizing certain support methods, such as the mechanics by poly induction, by hoop gearing, as well as by generalizing the criteria of embodiments of motor machines, mainly showing that the Mechanical rotational degrees of these can be realized horizontally, thus ensuring the realization of so-called rotary-circular machines, with differential or contrario dynamics, these machines making it possible to complete the chromatic ranges of motor machines and to differentiate the levels of them. of dynamism, and the degrees of material, virtual and real figurations. It will be shown in addition that the mechanical generalizations correspond to the dynamic generalizations of the figures.

Description

Disclosure Fields of the present invention The present invention can be considered as the second part of our work related to machines, work of which we will find the first part summarized in our request for patent filed internationally under the title of retro engine rotary, post rotary and birotatives.
Moreover, the. this patent application summarizes in aggregate applications of patents filed in anteriority of this one As opposed to the figurative plane, developed in the first part, in which we showed a certain number of criteria to describe the degrees of figures and mechanics of machines, the present invention will determine the main determine, from precise division made possible by some units of the first part, the various degrees this time the dynamico mechanical machines, and by a new set of machinery possible on this plan, notably the king-circular machines differential post and retrorotatives, and circular rotativo machines to contrario.
In addition, it will be shown that the degrees of the machines can simultaneously belong to both plans. Finally, it will be shown that the machines also have degrees of figurative reality, either the material, virtual, and Real degrees.
In summary, therefore, the present invention therefore aims to complement our first works and to show that we can restore to rotary machines, geometrically and dynamically, degrees of achievement ensuring them not only a motor ability but also a versatility of realization and distinction of types of machines appreciable. This versatility will find its theoretical form in a broad set of criteria conceptual allowing to determine any machine.
This new set of machines, much larger, and responding to a set of criteria much more accurate and sophisticated, so will allow a new synthesis, much more broad and encompassing, which will be expressed in the various chromatic ranges of machines drive.
This new set of machines will be as important as it will reveal machines rotativo-circular with blade dynamics or cylinder in Clokwise not only as a point primordial of cutting the various types of machine dynamics forming the range chromatic, but also, from the practical point of view by its original realization fundamental rotary machines, in that this is the only machine in which we do not find, as in the turbines, no acceleration deceleration of any of the parts, and as in piston engines, equal and complete thrust on the parts compressive.

From the point of view of the commercialization capacity of the present invention, while the mechanical and dynamic configuration machines of the prior art are remained confronted to significant problems, and have fallen into a commercial abandonment, we think that some of the rotational-circular machines to contrario, the first of which version was provided in our previous work, we actually seem to be a type of machines that, by their qualities, make it possible to envisage a renewed commercial capacity for rotary machines ,.
More precise contents and objects of the present invention The first part of the present invention will consist in generalizing certain parts or methods support of the first part. In particular, it will extend the notions of poly induction, hoop, and polycamation gears.
The second part of the present invention will aim to generalize the.
rotary figure basic circular, clokwise blade movement, presented at the first part of this invention. In particular, we will show that this realization is original mechanically, since it is the dynamic realization perfectly birotative. We show indeed that the birotativity, which we figuratively put in evidence in our first part, there is also presented dynamically, in the form of circular rotativo machine with movement clokwise. We will explain here the immense advantages of this type of machines and We will generalize Horizontal support methods to ensure a correct supports compressive parts.
We will show, moreover, that Rotary-circular engines, usually performed by circular motion compressive party coordination and clockwise motion are important not only from the point of view of their specific qualities original but also theoretically, since they make it possible to accurately determine a cutting point bierotative, this point subsequently allowing the completion of a system full of dynamics of motor machines, which will be represented by the chromatic scales.
In other words, we will show that the mechanical degrees we have defined in first part, and which allowed to realize figuratively machines different degrees, by different cylinder curvatures and more sophisticated, will allow also, when will be carried out horizontally through the use of inductions transmittives, to differentiate dynamically the degrees of machines, depending on whether they are dynamic clokwise, in retrorotative differential dynamics, or post rotary, or according to are in dynamic to contrario.
In summary, we will show that all the advancements relative to the degrees and with birotativity machines that we made on the vertical plane in the first part of this work, will be able, from the rotativo-circular machine unit per blade in Clokwise movement too shown in this section, that we can generalize this dynamic and elaborate the complete plan of machines, this time from a dynamic and horizontal point of view.
This book will be completed by showing also that these two plans can be made in a same machine.

All these dynamics will make it possible to constitute a complete system of machinery motorcycles, including chromatic scales, and a completed criteriology allowing to define any machine.
More precisely a) we will show the rules of allowing to regroup under the same design multiples mechanical of these machines b) we will show the differentiation between the material figures, the virtual figures and real machine figures, which will show different machines has movement contrary, including those with Slinky movement c) we will generalize rotary-circulire machines to all machines, For example polyturbines or quasiturbines d) we will show that the notions of not only figurative degrees but surplus dynamics can be applied to machines in general and to poly turbines e) we will show that one can realize chromatic ranges of machines general, and that these apply in post, retro or fixed cylinder, or cylinder plant in motion Clokwise ~ we will show that circular rotary machines are also general From the point of view of their blade, namely that they can be made by sets of blades single-cylinder, blade in standard poly face, palic structure.
g) we will suggest more appropriate types of segmentation h) we will suggest crank supports and their means of realization I) we will show that circular rotary machines can not only be carried out by all induction, but also that they can be elevated in degrees by all the methods of elevation already listed for machines with fixed cylinder, notions of figurative degrees and figurative, as for example the polycammed gears; degrees inductions.
Worktop of the present invention ~ o ~
In order to achieve these objectives, the steps of following disclosure 1) Summarize the prior art, before Wankle and at Wankle,

2) Show Wanlcle's main practical shortcomings, and the difficulties mechanical arise.
S

3) Show how our different inputs greatly improve the thrust, and this same in first-degree rotary machines

4) Show clokwise dynamics

5) Summarize a general system of machine understanding, evacuating difficulties from Wankle

6) Extend to their limit the notions of mono induction and poly induction

7) Suggest adequate segmentation of the machines

8) Suggest support for compressive parts by crank pins.

9) Show the semantic gaps of Wankle All of these achievements, linked to those already produced pax ourselves, will allow show all the mechanistic and theoretical shortcomings of Wankle and how a more total system, more expanded, more encompassing and final can answer for it.
The stages of realization of this second part of our work will be the following a) the data relating to the prior art relating to the machines will be summarized driving mainly rotary, with compressive blade or piston (b) Wankle's contribution in this matter will be summarized.
(c) The various basic difficulties of the Wankle system will be stated (It is to note that we will subsequently show several errors of design and meaning of this one) d) A brief recap of the first part of the present invention, and in particular, will show how we have, in this one overcame the difficulties of this one, which will make it possible to carry out the characterization of degrees, of these, of same as the compressive, neutral, motor (e) Some of these achievements will be generalized, for achievements by gear hoop, the realization by poly induction f) It will be shown that one of our previous achievements, Belle by dynamic in clockwise movement of pale, is not a mere achievement among others, but one realization strategically of the most important, since not only she put in a degree of original dynamisation of these machines, but also because what will complete the dynamic chromatic range of these machines, and achieve new characterizations, such as contrario machines, and figuration machines virtual and figurative Real. It will be shown in addition that these types of machine are fundamentally original from the point of view of their quality, in particular by pushed them evenly distributed over the entire surface of the pistons, and by their absence Total acceleration and deceleration of all their motor parts and compressive.

g) Realizing a point missing from previous systems to create the ranges Chromatic machines differentiated into dynamic differential machines post or retro rotary, and Clokwise movement machines or contrario.
(h) The generalizing quality of compound dynamics rotativo circular, in that it can not only apply to any machine, be it retrorotative, post-rotating, or birotative, but also dynamic, first, second third degree or other.
i) It will be shown later that all these machines can also be realized by combination of single blades, standard multi-blade blades, or structures palici j) It will be shown that machines can also achieve degrees higher dynamically or figuratively, in particular by methods of correcting figure already commented, such as by polycarné gears.
(k) The general principles of the association of methods of support of these machines, the notions of induction turned on itself, of rising induction, d ° induction down.
1) We will finally show that from these new achievements, we can differentiate them virtual and real material levels of the maohines, and thus achieve machines to Slinky movement m) It will be shown that all mechanical achievements already made by ourselves can apply to circular rotary machines, which guarantees the character specifically generative of these machines. To do this, we will define semi-transmissions already commented by ourselves as induced inductions on themselves n) We will list all the characterizations that make it possible to specify the nature of a given machine encompasses and goes far beyond the simple determinations of art prior art, and allows for maximum machine versatility and comprehension To this end, we will show the semantic errors of many machines of the prior art.
o) It will be shown that all these characterizations form a unity synthetic by which number of machine, which can not be heard by the simple classifications of prior art, can now enter it correctly p) It will be shown that corrective methods, backstage, staging, gears polycamé, can also be applied to circular rotary machines, by poly crankpins q) It will be shown that circular rotary machines can also be made by blades Rotary and circular rotativo cylinder, thus creating counter-ranges color (r) Various types of simplified segmentation for these machines will be shown s) We will show the possibilities of suspension by crankpins Recapitulation of prior art before and at i ~ iV'ankle The prior art and posterior to Wankle excluding our work The period prior to Wankle can be summarized engines, principally rotating as the period in which one gradually discovered a set of figuration of blades and cylinders, allowing the displacement planetary of these blades in their respective cylinders.
The basic figures were discovered by a group of inventors Fixen, Cooley, Maillard and many others. (Fig.la) It can be said, excluding our own work that the prior art in general, concerning engines, particularly rotary ones, seems to have known its most significant expansion before Wankle and at Wankle. Subsequent developments to those of Wankle are very fragmented, and even today, the industry uses support method by mono induction, invented by Wankle. This is mainly due to the high opacity of the Wankellian theory, which leaves little room for restructuring. But, as we have already shown and will finish showing it here, a fairly large number of characteristics of machines, and serialization, semantic division of these, allows the development of a large number of new machines, a theory more vast and general, and especially, new types of machines totally excluding the set of defects of machines prior to Wankle, and Wankle machine.
The contributions of Wankle As we have already mentioned in previous work, the contributions of Wankle can be classified into three main categories, either 1) historical indexing, 2) that of mechanization, and finally 3) a segmentation on blade, and a serialization of these new figures At the limit, one could add the intake variants. But this last bet includes dynamic semantic errors and is deprived of media methods mechanical, which prevents to know the mature and the actual composition.
The contribution of historical record of ~ Yankle The consultation of the main patent of Wankle, titled Eintellung der rotationskolbermachinen.
Rotations kolbenmachinen mit parrallelen drehaschsen unt arbeitshramumwandungenaus starrem werstoff bearing the number xb02204164 allows to take cognizance the exhibition faithfully, by Wankle of the state of the machine motorology of his time and of the prior art.
In truth, many of these machines, and even the great mafority, remain however no mechanized, and in addition non-mechanized using strictly the two methods of induction proposed by the inventor. That's why we will not consider here that machines may be mechanized, that is to say machines whose motor parts may hearth mechanically supported.
Rationalization of figures at Wankle The most important theoretical contribution of Wankle is certainly to have organized the initial figurations of the prior art so that the segmentations can in these news machine be realized no longer in the corners of the cylinders, but rather on the tips of the blades.
Subsequently, Wankle, like Fixera and Cooley, realizes the series of these machines, retrorotative and post rotary. These logical serializations similar to machine figures of the prior art, it was allowed to group the machines into two categories, That we have later called retrorotatives, and post rotative, depending on their blade, observed by a observer, moves in the same direction as his eccentric, or in opposite direction of this one. (Fig., 1b) The second part of the. rationalization of Wankle consists of specific series of each of these categories, put in series to rationalize the ratio of number of side of the blades and cylinders of each of these categories. Wankle enacts so the. rule according which the retrorotative machines have a blade side number of one lower than their respective cylinder, while the post rotary machines have a blade side from a superior to that of their respective cylinder. (Fig. 1b) Mechanization The theoretical contributions of Wankle would certainly not be known to the general public today was of its mechanical contributions, which have resulted in a autonomous support of blades with respect to their respective cylinders and therefore to cut undue friction the blade on the cylinder, causing premature wear of the segments.
These types of mechanical support are limited in Wankle two in number. he these are supports by mono induction, and by intermediate gear. (Fig. 1 c) The support by mono induction is the type of medium typically used in the industry.
wagering The only dynamic variant for which Wankle provides methods of support is the variant by double rational action. This variant still serves today in production of pumps. Wankle provides two methods of support for this one. (Fig. 1 d) It is made by mono induction and triangular blade Let us note from the outset that the crankshaft of rotary machines, and mainly retrorotative must be made of very small size to allow the. realization of a report of acceptable compression. Likewise, the more the number of faces of the blades and cylinders machines is high, the more their eccentric is small. It is for these reasons that the industry has focused on close exclusively on rotary post machines with triangular blades.
When the mechanizations proposed by Wankle, in the mechanization by gearing intermediate, it is proving more difficult to achieve segmentation, and realize with a full assurance the correct positioning of the blade. The industry has recognized limitatively mono induction method as a reliable method of support allowing production commercial of this type of machine.
Period after the Wankle period excluding our work The opacity and rigor of the Wankle system have made the developments conceptual subsequent difficult. The rational organization of the engines does not has very little criteria of rationalization, criteria of distinction character machines, which will have made the design not only narrow, theoretically but in addition, insufficient and erroneous in several places, including those from the analytical perspective, and those about characters compressors and engine machines. Excess cleaning of the components by Wankle did to lose a large part of the rotational capacities of the machines. Among the works after those Wankle, whose contribution to the engines is significant, it is note those of Wilson and St Hilaire. The first shows that one can realize a machine motor whose blade will be a flexible set of blades, which we have called palic structure. The second uses this palic structure as support structure to a set of blades higher. Each of these inventing was able to suggest support structures adequate for these machines.
We have abundantly shown that these machines constitute machines for second degree, and of third degree, and that they could like first-degree to be put in series. We also mounted that same mechanics that ~~ s machines ~~ first degrees, but this time put in cpmbination allowed to sou ~~ nir parts coliressives.
Very concise summary of the preliminary course ~ t of the present ~ y. ~ Garlic As a first step, appointing a number of researchers, we found that machinery rotary, especially when they had strong compressionary parts by methods conventional products producing, b ~ a ~ fricing acoup, which is the consequence direct flares contradictory on ~~ a pale. Therefore, in the first place proposed several news support methods to counter these difficulties, such as methods by poly induction, by hoop gear, by central active induction, by will be transmission and and so on. (Fig. 2) We subsequently realized that the.
of construction mechanics performed during the expansion was more interesting in the rotating retro machines only in post rotary machines. In order to take advantage of this advantage important, we have worked extensively to correct the weak point of these machines, trying to show methods capable of increasing the compression of the retrorotative machines.
To realize that, we came to understand that it was necessary to correct the stroke of the blade, and the curvature of the cylinder, so that it sinks less deeply in the tips of the cylinders and deeper into the sides. As and when measure of this work, we were interested in machines with palic structures, whose first structure compressive was performed by ~ Vilson. We found that curvature of the cylinder of it was specific in that it had both a retro appearance rotary, and a post aspect rotary, which was corroborated by the various mechanical support methods That we have produced to support in parts. We concluded, in addition, that some machines by their nature, had a higher degree of rotativity proved by a higher number of rotating structures. It has therefore been shown that the mechanics of these machines could then be applied to retro rotary or post-rotating machines, which conferred a degree superior mechanics, a more subtle cylinder figuration, and finally, a characters in bi rotating part. These methods have therefore made it possible to increase not only compression of retro-rotating machines, but in addition to increasing the torque of the machines post rotary. The main methods of realization of turbotativity have therefore been that connecting rod geometry, polycammed gears, staging, poly induction. (Fig.3) The reasons for the results obtained, both in the retrorotative machines that post rotary consisted in giving these machines back their bi rotativity, the number of degrees of mechanization allowing the correct motricity of these The difficulty of realizing the mechanical layouts led us subsequently to propose others original solutions of realization of the bi induction. Poly induction permitting indeed horizontally realize the cut that we had produced. We have so also been more Far showing that the. birotativity could also be realized horizontal and dynamic, by making clokwise moving blade machines, which must be considered as we will show it, like the most important expression, theoretically, machinery circular rotativo (Fig.4) Very concise summary of the invention.
In the present invention, it will first devote a part to a first party to a generalization of certain methods of our previous work.
It will show in particular the notions of poly induction in descending inking, or poly alternative induction.
It will expand the concepts of polycammed gears, and method of support by gear hoop.
he r, _., .., c. ## EQU1 ## . ~ T = F zcuc2az eMSMmm, ... x ~ ra ~ smv ~ x., .a .. ow. wavmwau Nrmm, "~. ~ ,. r. ~~~, ~ a ". ~ o .. ~" ~ va ....- ~ .x. ",. ~~,., ~ rn In a second step, we will clarify our thinking about rotary machines basic circulars, and specify the bi inductive nature to motion clokwise of pale. We show the great mechanical relevance of these machines.
Then, in a third step, to generalize the methods of support of these types of machines, showing in particular that there is always a participation of at least two mechanical, by induction induction, by downward induction, or by transmission, and that the parties are linked by the blade, the crankshaft, or the support gear.
In a third time we will generalize to their limit the machines circular rotativo. We show that, starting from the dynamic clokwise, one can realize, this time on a horizontal plane, the whole of the degrees of the machines, together that we had realized figuratively and vertically in the first part of our work.
We will achieve more precisely this 1) showing that the number of degrees in these, is expressed dynamically, per share differential post rotary, retrorotative, or by contrario action 2) the types of corrective methods, for example geared polycamés, by increased degrees of rotativity can also be applied to them 3) that the various types of blades, simple, standard polyfacies, by structure palic can fear to be applied 4) that the horizontal plane on which they are carried out can be combined with the vertical plane of previous machines 5) that every rotativo-circular machine is both the expression of a material figuration pale cylinder, a virtual figuration express the movement of pale, and of a Real representation, expressing the correct location of the times of the machine 6) That rotativo-circular machines can also be realized with a dimension differential or a contrario dimension 7) That clokwise movement machines can be realized so virtual, in mirror reversed, either by clockwise cylinder and rotational blade, 8) That clokwise movement machines can also be realized in bifonctionalité.
All of these new generalizations will complete our work and will achieve a general theory of criteria for determinations of any prime mover.
More detailed summary of our previous work and the purpose of this paper invention of our previous work Our previous work has therefore realized the following aspects A) we have added several first level mechanics to both mechanical Wankle, which will have made it possible to determine a vast mechanical ensemble including following support methods, (Fig. 2) - by mono induction (Wankle) - by intermediate gears (iUankle) - by poly induction (Beaudoin) - Method by serai transmissian (Beaudoin) - Hoop Gear Method (Beaudoin) - Intermediate Gear Method (Beaudoin) - Heel Gear Method (Beaudoin) - Meihode by juxtaposed internal gears (Beaudoin) - Internal gearing method stacked (Beaudoin) - Central Post Gear Method (Beaudoin) - Engrenagic structure method (Beaudoin) - Unit Gear Method (Beaudoin) We subsequently produced together the following advancements (Fig. 3) a) We showed that we could increase the compression of the machines rétrorotative, the torque of post rotary machines b) We have therefore shown that it is possible to produce rotating machines of various degree, these machines making new cylinder shapes more subtle and being supported increasing the number of induction (c) we have shown that it is possible to produce accelerated actions decelerating parts compressive, thereby increasing their oscillatory effect, and thereby improving the race of compressive parts and the shape of the cylinders relating thereto d) we have shown the rules of combination of mechanics in staging e) we have generalized the cylinder shapes of the poly turbines we have shown the methods of modifying the degrees and cylinders of machinery g) we have shown the dynamic degrees of rotor cylinder machines at piston h) we have shown the effects of poly crankpin on rotating machines i) we showed the different types of cylinders obtained Carréifiés, ovalized etc.
j) we have shown that machines can be built in sets of blades units, blades in standard polyfaces, palic structures k) showed us the perfectly birotative dynamics of moving blades Clokwise, and the rotativo-circular dynamics that this movement implied.
Retrospective of the prior art ~ Wankle z and Wankle We can summarize the prior art to Wankle by saying that he is the expression progressive and not rationalized various figures of rotating machines. The main ones inventors to whom we must the basic geometric figures of rotary machines are Fixen, Cooley, Maulard and several others These inventors have shown that blades of various numbers of can be made to produce a planetary travel inside a cylinder, when they are mounted on an eccentric. (Fig. I a) Wankle contributions Wankle's contributions can be considered from three points of view individuals.
Wankle must first be an important historical part, since in his invention, this one makes a more exhaustive catalog of the engines of prior art.
The second contribution Wankle should rather be classified from the point of view of its value theoretical. Indeed , Wankle establish a classificatory rationalization of these figures, and segmentation figures on the blades, which allows him on the one hand to divide them into figures post rotary and figures retrorotatives, and on the other hand to fill the said classes of figures missing. (Fig. 1b) Wankle's third contribution consists in having two methods of Orientational support blades of machines, methods that we named by mono induction and by gear intermediate. (Fig.lc) These methods have had the main effect of making the totally pale independent, mechanically, of the cylinder in which it travels. By Therefore, (use of these methods allowed for a correct separation of the mechanical and compressive This is why mainly one of these methods, the method by mono induction, has been adopted by industry f, with the result that the engines are often referred to as Wankle engines, named after the inventor of these methods.
First paréïe In this first part, we identify more specifically the gaps most fundamental principles of the prior art and in particular that of Wan:
will produce a extension by precision of methods that we have previously proposed. .
General loopholes of the Wankle system It is a point of consensus to consider rotating machines before Wankle like very little resistant to premature wear of the segments, and Wankle machines as having a high coefficient of friction and a very low torque.
To really be able to correct these defects, you have to have a full awareness of their causes. It is known that the segments of the machines of the prior art at Wankle, underwent premature wear caused by the fact that the orientational support of the blade is realized by his anchoring to the cylinder. The segments then undergo mechanical pressure important for which they were not designed.
The deficiencies of the Wankle system can be classified into three main categories either mechanical, semantic and incompleteness gaps. We will not study semantic gaps and incompleteness only at the end of the present invention, and will not consider, for the fms of the this section only the mechanical gaps.
Wanhle Mechanistic Gaps Segmentation The positive effects of the new Wankle segmentations have been to allow a segmentation on the blades, and a softening of the cylinders, which had the effect of minimize wear segments. Moreover the main negative effect was to achieve the explosion so to speak on a placed horizontally, and not a righting blade, as this was the case in machines of the prior art. The price to pay to secure the segmentation has so in a first time that of considerably reducing the extent of the extension, reduced in Wankle machines with the only extension of the crankshaft.
Mëcahique Wankle's mechanical contributions have thus fulfilled their objectives of achieving Ia security orientation of the blade independently of the cylinder, and by therefore to realize Ia total separation of the mechanical action of the compressive action. Otherwise, it is obvious that the realization of these methods of orientational support has resulted in other difficulties, almost as important, theoretically mechanically.
Since we hear at the. first part of this application, expand some of our previous solutions, namely poly induction, gear induction hoop, and by polycammed gear, and in the second part, generalize the horizontal plane dynamico mechanical machines, we will discuss here Wankle's errors, and show that all our solutions are not fragmentary, but instead form a systematic corpus original allowing to fully account for the machines. It will therefore be easier to the reader of take into account the originality, efficiency, flexibility of the variability, and generality of the global synthesis that we propose for this purpose.
The set of Wankle's shortcomings and the set of solutions we have there brought and there bring are the following a) A realization, by means of two mechanics, the mono mechanics inductive and by intermediate gear, of contradictory thrust on the same blade, a part of these thrusts being in the opposite direction to the rotation of the machine ( solutions hoop gear inductions, will be transmission, central gear post active) b) A mechanical realization lowering the number of components on a number less than that strictly necessary for the. realization of the. traction (solution shelves, paly crankpins) (c) Counter-rotating mechanization, resulting from the reverse observation of the mechanical machines, from the outside to the inside of the machine system (solution constructed observation, and poly induction) d) an exaggeration in the regularity of the rotary movement of the blade gears polycamés) Wahkle's first shortcoming: centralization of the anchorage resulting in outbreaks contradictory on the blade IS

The element without any doubt constituting the major difficulty of any machine rotating, dorsyue the orientational action of this one is carried out by one of the methods of Wankle, that is to say in the center of the machines, is certainly that of the contradictory thrust of the explosive power on the blade. By contradictory push, we mean on the one hand that part of the blade has a orientation induction not only contrary to (other part of the same pale but also contrary to the machine system. This is exactly what happens in the two main mechanical induction of Wankle, ie mono induction, and induction by gearing intermediary, and this is certainly the main reason which is based on lack of motricity of these machines when performed in these ways. (Fig.S
b) To better understand the cause of this gap, we can use more examples understandable by comparing several piston engines, of different types.
We can indeed compare standard piston engines to piston piston engines sliding, and poly induction piston engines. (Fig.Sc) It can be seen in this figure that the power of the piston on the crankshaft, underway descent, is given in the standard piston engine by thrust vertical on this one, and b by lateral support of the latter and the connecting rod turning into a thrust lateral.
The two combined effects, thrust and rod effect combine to make the movement circular crankshaft. Pushed on the surface of the piston, is totally positively used.
Indeed, whether it is anterior or posterior to the point of support of that here it is transformed in a lateral-vertical push directed in one direction only.
In the sliding link engine, the lateral action of the thrust is lost, and the connecting rod effect is cut off. The machine therefore only has its vertical effect.
In the poly induction motor with straight rod, our patented titled Energy machine to poly induction Ia power is this time increased by the action strictly vertical of the.
pushed, added to that lever crankshaft superimposed.
In the rotary engines of the prior art at Wankle, it was possible to.
make a push, even uneven over the entire surface of the blade and therefore an effect of appreciable push on the crankshaft (Fig. 5 a) The crankshaft and the blade participate in realizing their compressive action to mechanical faction, the end of the blade realizing a certain inking in the cylinder and allowed an action of lever of the blade on the crankshaft. Unfortunately, such a procedure making the realization commercial of these machines difficult, since that mechanical parts carried out so confused with compressive parts necessarily result in wear premature them.
It was therefore absolutely necessary to carry out only positional, that is to say, the center of the blade, also friends, orientative of it, in such a way make the action totally independent of the cylinder and thus allow the realization of a strictly floating segmentation.

Wankle's methods: inductions by mono induction and gearing intermediate As we have just shown, we can say that (anchoring, in the rotary machines, is the equivalent of the effect of the connecting rod in the machines pistons.
So we can arm that the movement of the anchor from the outside to the center of these machines produces a similar effect if not worse than that of the retrenchment of the connecting rod effect realization of the sliding transmission previously shown in the engine piston.
Indeed, by inking the orientation aspect of the blade in the center of the machine, divides, necessarily, this so-called two-part blade that will realize the thrust of the explosion of way contradictory, in the opposite direction.
The thrusts on each part of the blade will therefore be contrary, and this will result in a reduced thrust on the crankshaft, since the thrust on it will not more than the difference contradictory outbreaks. In the case of mono induction machines, this who is the first Wankle's support method, (rear of the blade will undergo a negative thrust then the front will undergo a positive push. On the contrary, in the case of the application of gear method intermediate, that's it. front part of the blade that will push negative, and the. part back which will achieve a positive push. (Fig. 5b 1, 5b 2) The explanations of these mechanics are described in more detail.
this application prior patents.
Clarifications of the solutions of the brought We will take care to read our previous works relating to the engines, to take in load the various methods of support and correction of blade races machines, and to better understand the notions of degrees of these. For the purposes of present, we do not remember that those we intend to expand. We will generalize more A) the hoop gear inductions, realizing them with chains or belts B) the polycammed gear methods, realizing them this time circularly, with alternatively distant and closely spaced dentitions C) transmission with vertical compression and structure D) methods by poly induction 1) at the level of their induction 2) at the support sites 3) at the level of their alternation As we have already mentioned, we have already shown several solutions to these problems. Here, however, we will limit our exposition to solutions that will receive in the present invention and generalization.

We have demonstrated several solutions to these diff alties could be made without changing the level of the machine, that is to say, keeping the machine at its level of first degree. These solutions have common aunts the goal to achieve this time mechanically the externalization anchoring of these machines. These solutions already commented on our work previous ones are mainly, the mechanics by the hoop gear solution, by polycamation, by will be transmission, mechanics by poly crankpins To this end, we can re-read our previous work, as well as considerations on the push that these solutions bring, and that we show in our request patent in antecedence titrated Retrorotative machine, post rotary, and birotative (conclusion) These mechanisms for the purposes of this application must be supplemented by the following way A) Hoop gear mechanics must also understand their realization with chain, belt (Fig 6) (B) polycammed gear mechanisms must also include round gears in which accelerations and decelerations already commented are performed by approximation or removal of teeth. (Fig.7) C) The mechanics by serai transmission apply to any dynamics of machines, that the driving parts are the cylinder or the blades, that these machines be post rotary or retrorotative, or that these retrorotative machines are explosion lateral on the blade, or vertical explosion. (Fig.B) Mechanical hoop gear Hoop gear mechanics are made when the gears support and induction type are coupled together by a gear rotatively and planetarily mounted the reunited. One succeeds at the activation of the blade, climb this time on a crankpin, by its summit. Which gives it a great fluidity induction. We have already shown that in the hoop gear mechanics one could increase the effect of rope of the hoop gear, and angulation of the thrust by realizing these mechanical with a third gear. By the way, in our bicycles pedals we have showed that this mechanical could also be applied by realizing (hoop gear under the.
form of a chain. This merely has the effect of stating, for the machines motorists, that the mechanical, say by hoop gears, the hoop gear can materially be realized by a belt, or by a chain (Fig.6) As previously, in these embodiments, the rope effect prevents the realization of the effect of forward contradictory thrust on the. blade. The forward thrust is therefore rotative in the sense of the.
machine, and adds up to the rear thrust, which is also positive. Chain can also be made in the form of a belt.
Indeed, as during the realizations with three gears, the mechanics to gears hoops, when performed with a chair or belt, will extra rope, Iô

this effect canceling the ~ Ussée contradictory before and allowing by therefore a push, though uneven, positive over the entire surface of the blade.
The thrust on the blade will no longer be contradictory and since all ~ ussées on the blade are offensive and, moreover, respect the unequal nature of the openness of the blade when expansion.
Acceleromecelerative mechanics and polycamation techniques.
We have shown in our previous work that the realization of parts accélératio decelerative effects in the engines could machinery previously impossible, and allowed machines of degree of motor skills superior. These machines were made from gears that we said polycammed gears.
In particular, these machines, when made by such gears, moreover to admit a thrust acceleration compatible with the thermodynamics of the explosion, allowed a variation of inking point reducing the. against negative thrust on the blade. We can expand, hereby, the concept of polycammed gears by stating that standard gears or of polycammed form can be made in such a way as to produce acceleration deceleration by producing distancings of variable teeth. ILN
gear, whose teeth will not be equally willing, and which, therefore, will be in places closer and others farther away, will produce, even if they are circular, accelerations and decelerations similar to those of polycammed gears. (Fig. ~
In addition, two gears designed in this way can perform accelerate and alternating or similar decelerations between them over time.
The same accelerating and decelerating effects of the parts will then be produced which are fixed to them, and moreover, different shapes of cylinders, more convex, or more acute, that we will be able to surplus realize them in symmetry.
Generalization of the method by service-transmission As it appears in our works filed in an antecedent to the present, the method by service transmission applies to any rotary machine, and in the case of machinery retroactive to vertical explosion machines (Fig. 8 a) This method will allow an action verticalizing of thrust on the crankshaft In addition, it is important to mention here that the method by serai transmission can be subdivided by the conjunction of a support induction rising, and a Induction of downward axis of rotation (Fig.8 Finally, we must mention, as we will explain later, served transmittive to adequately support the blades in birotative motion clokwise.
Solutions for increasing the number of verticaulic rotational degrees:
staging of inductions and poly induction ..., u.-...-... ~. . "., .." ... ~. ~. a ........ mu., s,.,. ~ ar ,, r "K :: e ~~. .-", .mwxiso, ~ x ~ r. ~. ~~, ~ a" a ~.: ~ r., ...,. ~.,. w, ~ x ... .r '~,. .R .. ... a ...
: 5n ~ 's: ari: ~ r T; ~ as..a ~ aorr ~~' ~ .rt -., .. ~ - .. ~ ... ~, ~ ,, ~ m, .mm., ~ r: o., w ... .. ", ,.,., .. ~ ,. , Urvym .. "". ~. , ..,, ... t .., ~ "" m "." ~., ... r., .. ~ ...,.,. e We can certainly summarize by saying that the first gap Wankle consists of a excessive lowering of the number of parts of the machine. This lowering allows to realize the machine in its nature Compressive, but not in its motor nature.
This statement is also understandable with regard to the examples of pistons already presented. In the piston engine with connecting rod, connecting rod and pistons are carried out so confused. There are only two components of the machine either the party compression, realizes by including in a fixed way the ligating part and the mechanical part. The machine will be powerful in compres ~ ioh, but will be of lesser performance when used like motor.
The way to give him his power will be to restore Ia. ligating part, the connecting rod, so distinct from the piston.
It should be clearly seen that the centralized realization of the inking in the rotary machines, is equivalent to the subtraction to the subtraction of the connecting rod itself.
When the connecting rod is made in a way confused with the piston, the machine is deprived of its effect of connecting rod. A similar loss is achieved when the inking of the machine is brought back to center of it.
We affirm that, for internal combustion machines, the cross elements following be made for any machine in its engine form a compressive part, - a mechanical part a ligating party must be carried out jointly and cooperatively to achieve the machines under their neutral or motor form.
We think that the engines, whether piston or rotary, can be realized in two main ways, either in their compressive form, motor, or neutral. They are carried out in their neutral form when they are deprived of their effect of connecting rod and are made with all parties. They are of neutral and driving form when the effect of rod is restored, and moreover when we add a leverage effect, as in the engines to straight rods.
We have shown and will show again here that one of the errors major of Ia realization of any machine of the prior art is to have realized the rotary machines like first-degree machines, that is to say, being machines not possessing only one degree of peripheral rotativity. All machines have been realized in their nature Compressive, not Motor.
Mechanical staging as a degree elevation solution In our previous work, we have shown that mechanical staging, who had everything first of all to make retrorotative machines with a ratio of compression acceptable, was in fact of much more general value since could realize any motor machine according to this method. More specifically for Ies post type machines rotating, it allowed for an extremely powerful torque improving way considerable angles of attack of the blade on its crankshafts. As to bi-type machines rotating, since the mechanical degree allowed the support of the blades was already second degree, these mechanics by staging allowed a correct support Parties compressive material, which the previous art had not been able to achieve nature These machines of second degree were therefore more powerful and their nature was of a kind Motor, while the first-stage machines, carried out with a single staging, remained type machines Compressive, with two staging became neutral or motor type.
In the realizations by staging the motor parts of the r ~ achines do not are not conundant. In effect, the achievements by staging have been restored in full and distinct but coordinated, the motor parts of the machines, and thus realized in their form Engine.
For more information we will take care to read our work prior to this subject.
The brief reminder here of these notions is intended only to prepare the ground to a better understanding of mechanical combinations, which in this will be carried out, for circular rotativo machines, horizontally. We do not limit ourselves here to some machines.
The most obvious examples of these achievements are realized in the triangular motors retrorotative, with and triangular post rotary blade, (Fig. 9) In these machines, moving the center of the blades, in other words the displacement positions) blades, is no longer simply circular, but is itself planetary. The These mechanical machines all assume a superior mechanical the gear of support is dynamic and peripheral, since arranged in a fixed way at height the crankpin, or still polycamé and arranged in the side of the engine. The upper crankshaft of these machines performs a similar action to the action of the piston engine housing. he There are more than two hundred possible combinations of mechanics.
Second gap of Wankle and second solution of increase of degrees vertical: the poly induction We have worked extensively on the concept of poly induction for better understand no only the originality but also the scope of the notion of poiy induction, and this, not only from the mechanical point of view, but moreover at the conceptual level, it is necessary to place to a understanding of rotating machines from the point of view of observation.
As we have said before, the shapes of the cylinders of the machines rotating as well as their support strictly positioned) appeared before the elaboration of various t3 pes of Orientation guidance of the blades. Therefore, it can be said that in the field of rotary machines, the experience and the. practice preceded the theory.
Leaving indeed blades simply supported positionally by an eccentric and arranged in a cylinder, we have two types of observations, observations which later allowed the mechanical composition ensuring in addition the autonomous orientation of blades.
Observation types One must necessarily think that to obtain the result of mechanical by mono induction and by intermediate gear, it was necessary to precede the observation of the blade in two ways different. It will be said that the first type of observation is an observation by an absolute point, from the outside of the machine, (Fig.lO a) and we will say that the second observation is dynamic and interior, since it can be done from an observer hypothetical positioned on the crankshaft being rotated. (Fig. 10b) Observation by observation outside general.
In the first type of observation, said by absolute external observation, We suppose a observer located at (outside the machine and observing the movement of the pale and crankshaft. In post rotary machines, this one will observe that the blade acts in the same meaning that of the crankshaft that supports it, and but more slowly than this one. Conversely, in the retrorotative machines, he will find that the blade acts in sense opposite of rotation than that of the crankshaft that supports it. It is from these findings that must necessarily have been built the mechanical first mechanics of Wankle, that we we have subsequently named induction by mono induction.
In the case of post rotary machines, the need to produce a movement slower blade that of the eccentric was realized by (use of a gear blade induction reducer type, either of internal type, coupled to a type of support gear external. In Ie second case, that is to say, of retrorotative figuration, since the blade must turn in the opposite direction of the crankshaft, the blade gear is external type, while the support gear is of internal type, which will force a sufficiently accelerated retrorotation of the blade so that (Observer may observe, observe the opposite movement of it by compared to that of crankshaft. {Fig. 10 a) Observation by positioning on the crankshaft.
The second type of observation gives birth to all other mechanical first degree, including the Wankle intermediate gear mechanism, as well as that our first degree mechanical, including for example by transmission, and hoop gear, by active central gear;
This type of observation is punishable if it is assumed that an observer is positioned on the crankshaft of the machine and compares the direction of his own movement to that of the blade. The one-it will be noticed that contrary to what happens in the first case, the pale always acts to against crankshaft direction. There is no contradiction between the two observations. Indeed, even if the blade always turns in the opposite direction of the crankshaft, its speed of retrorotation varies depending on whether it is a post rotary or retrorotative machine. Thus, if his speed of retrorotation is less than that of crankshaft rotation, as it is cases in the machine post rotary, (outside observer will continue to observe that the planetary rotation is realized in the same direction as that of the crankshaft. Moreover, if backward speed is greater than that of its crankshaft as is the case in machines rétrorotatives, the outside observer will continue to observe a movement contrary to that ci compared to that of the crankshaft It can be deduced from these assertions that the mechanics to be built at from a observation on the crankshaft, will not seek directly to achieve a action in the same direction or in the opposite direction of the blade, as in the case of the. first observation, but a rotation in the opposite direction to that of the crankshaft, but with different speeds however, realizing thus post-rotating or retrorotative machines. (Fig. 10 b) Again, by way of example, the intermediate gear induction of Wankle product mechanically this observation. The blade is activated not in a report directly to the body of the engine, but through a gear mounted on the crankshaft, such way to be activated by his report to this one.
As we have already mentioned, the hoop gear mechanics, by active gear central, by served transmission, and several others of our design are installments from this same perspective and observation.
It is from these types of observations that we have been able to build the consequent mechanical that can be called first-degree mechanical prominence before, and mechanics of first degree with a backward prominence, depending on whether it is there. front part or back of the blade that produces a thrust, the. contrary party producing, as we already have shown, one against thrust.
External observation of displacement points.
A third type of observation can be made, and this type of observation will be the source rational of the realization of the mechanics by poly induction. In this type observation, he is again to make an observation from a fixed point outside., However, here he This is not about observing the movement of the. pale in general, or the compare with that crankshaft, as in the case of the first type of observation. It's about rather to observe the run various points of the blade for a turn. This will be called type of observation dynamic. (Fig. 10c) This observation will make it possible to realize that any point situated on a line from the centers to tips of blades travels the caricature of the cylinder in which she wanders. Secondly place, this observation will show that any point situated on a line uniting the center sides in the center of the blade travels a shape similar to the shape of the cylinder but this time in the opposite direction of it. The observer will then note that the points of two forms are always equidistant from each other, which will allow attach a rigid blade to mechanics realizing these two points.
Starting from this observation, we will therefore realize in combinations two planetary mechanics working however oppositionally, what will be called the poly induction. (Fig.l1) The original and foundational aesthetic aspect of poly induction Again, the poly induction method is much more than a method of support. She is in a way a dynamic geometric understanding quite contrary to those of prior art thinkers including Wankle. Indeed, for Wankle and his predecessors, the realization geometric shape of any cylinder shape is produced by subtracting movements, that is, say, a quick central movement, that of the crankshaft and a movement outside slow and in opposite direction, that of the blade. As we saw earlier, there is inversion and realization of the mechanical parts together. The subtraction of these movements made by the central eccentric and the blade, produces the curvature of the cylinder. (Fig. 12) ~ r poly induction shows that the production of the curvature of the cylinder can be realized from totally different way by achieving additively and non-additively subtractive, two positive movements, f a, master realized by the central crankshaft, and the second, secondary, made by a subsidiary crankshaft. In addition, the slow movement, so master, is this time this is done at the center of the machine, and by the crankshaft, and not in periphery, and so confused with the blade.
In addition to realize in a dissociated way the elements compressed, ligature and mechanics of the machine, the poly induction shows beyond any doubt that the curvature of the cylinder can be carried out by the. sum of two dynamic positive circular actions, and no, as inventors of the prior art by the sum of contradictory actions.
But there is much more to consider. As we will see later, the dissection type of movement under movement realized by the poly induction will allow realize on this basis, a new dynamic organization of the most important and determining, all as much theoretically, that is, the dynamically dynamic organization of circular to blade movement in Clokwise.
Before proceeding to this stage, however, we will generalize here a few notions of poly induction.
Pody induction: generalization of methods and horizontal distribution of under movement:
circular rotativo machine We here intend to generalize the method of poly induction in four ways following A) mention that any induction can be used to control each induction subsidiary post rotary of a poly induction B) that any location of the points of connection of the crank pins may be chosen, and will allow distinguish the compressive, neutral and motor aspects of the machine in poly mode inductive.
1) that when making with more than two subsidiary crankshafts, it is possible to retain the effect of slinky hinge by realizing the poly induction way dynamic, that is, alternatively A) poly induction by all inductances In standard poly induction, in double or multiple parts, each Subsidiary induction is comparable to a mono induction however post rotary, comprising a gearing post-rotary induction type, external type, and a support gear also of external type, common to each induction.
1) We simply intend to state here that the post inductive action of each sub-induction can be achieved by any induction of first degree, this one being however carried out so post rotary. For example, we can activate each induction gear by gear hoop, by intermediate gear, and so on. (Fig. 13) 2) the second clarification that we intend to make here is that every point of the blade produces the shape of the cylinder but with different orientations according to its situations. Like us noted above, the points in the axis of the points, and the points in the axis of the sides, produce complementary shapes of the cylinder. Note in addition that points intermediates produce the cylinder shape but this time oblique. The machine can to be supported not by double articulation, but by tri-articulation.
In this case, supports them by the sides will produce a descending inking, supports them in position intermediate, an inking descending late, or precipitated, and supports them by spikes, an inking superior. We will say so that in the first two cases, the machine is motor or neutral type.
The supports in the sides realize a contrary race of the crank pins, vertical, and the parts of the blades joining these Support points at the blade points should be considered as geometric additions whose effect will be to restore, despite this position, and race, the initial curvature of expected.
When supported by spikes, the machine is Compressive type.
Note that the latter type was made by Muelling. So it seems obvious here that even the poly induction can be carried out in a negative way.
The positioning of these induction will allow, as is partially realized in the poly double induction, an inking and a hinge effect in the process of downhill, which will realize the machine in its engine version 2) When producing by more than two supports, a large part of Slinky hinge effect realizes in double part disappears. 4r, it is important to keep this mega effect, which makes interacting inductions into them, and did not keep them in reports isolated from mini inductions. Moreover, but it is also important to realize a support balanced and also distributed between the various inductions of the machine blade faces, as allow them three-part achievements. (Fig. 13 b) The solution to this dilemma is to realize alternately and successively an induction ~ Linky. To do this we will remove teeth on the gear of support, spell on the induction gear in such a way that never more than two inductions, except when alternative transitions of these, do not work together.
Each induction is therefore alternately motivated by its direct connection to the poly mechanics inductive, or by its strict connection to the blade.

Therefore the blade is always maintained minimally by two inductions and the third induction is mechanically free and driven by the blade itself.
In this way, not only is it ensured (Slinky effect, but also suppresses is there induction contradictory, producing any counter or half-thrust.
As we have just shown by the mechanism of poly induction, the geometric design Wankle's machine dynamics is not only failing because, like us (We said, it lowers the number of parts making up the machine, but also because, this in fact, it reverses them.
Wankle reversal gap To better understand this idea, we will use as an example, new strictly piston engines. We will compare piston engines standards to piston engines of the orbital type and the rotor cylinder engines, these the last being taken from our Canadian patent In the proposed standard and orbital engines, each set compression, ligaturai and mechanical taken isolation is exactly the same, in that action purely rectilinear piston is transmitted by the connecting rod to the crankshaft mounted rotatively in the machine.
The differences between these machines are only relative to the positioning of departure from certain parts, such as piston cylinder assemblies and the crankpin.
In the case of standard machines, it establishes several successive explosions several crankpins in different dials of the crankshaft, each set of cylinders is finding on a same line. In orbital motors, it is rather the points of connecting rods that are on the same line, since they are connected to the same crank pin.
Conversely, cylinders are arranged in different dials. Again, the dynamic of construction or deconstruction of compression is exactly the same for these two machines, since the internal crankshaft, connecting rod and pistons are maintained.
The dynamics of the rotor piston cylinder speaker is very different.
The connecting rods and pistons are all attached to the same fixed axis, off-center, and the rotor cylinder is rotatably mounted in the center of the machine. (Fig. 15) The rectilinear action of the piston in its specific cylinder is therefore the result of the double action circular cylinder and piston from centers deserent. This machine is much less powerful than the other two previously commented versions, and that.
explained because the power is partly transmitted from the center to the periphery before return to the motor axis central. There is therefore a loss of energy. A second way of understanding the why Ia power deficiency of this type of machine, when used as a motor, is of understand that the. power is obtained, similarly to the resultant obtained between the keel and the sail of a sailboat, by a very small angle of torque, even half way of (expansion.

If one seeks to determine the geometric cause of this inadequacy of energy production, realize that the functions usually granted to the crankshaft have been deconstructed and subdivided and then allocated to different parties. Indeed, we see that the crankpin crankshaft is realized in the form of secondary axis ax, while the rotating part of crankshaft is granted to the rotor cylinder. So there is both de-embedding crankshaft, and part of the dismantling of the latter in a manner confused with cylinder. Indeed, the rotor cylinder performs both the crankshaft components and a part components compressive of the machine. So we see, so claimed, more exactly the contradiction, which consists in observing that a strictly rectilinear cylinder can not transmit that little energy when it is made as a crankshaft. In summary then, in the machines to rotor cylinder, rod piston and cylinder are present in the machine. This is the crankshaft that is not realized in its standard form, but is rather done in part so with the cylinder. The crankshaft is therefore on the periphery.
In the light of the foregoing, it can be seen that the role of parts of a machine is not definitive, and that several machine dynamics are possible. In doing so, these dynamizations allow certain pieces to play a different role.
In the case of the aforementioned machines, the strong knowledge of the provisions of basis, when this is done in a standard way and of orbit type, allow quite easily to understand that Ie role play performed in the rotor cylinder machine is a version built.
In rotary machines, taking care of construction mischief is more arduous, since these machines have, from their origin been rendered in a overturned disposition.
It must be assumed that in any rotary machine the crankshaft master, without the knowledge of inventors of the prior art, has been realized in a way confused with the blade, and that, starting from findings that can be drawn from our poty inductions, the eccentric central is no other thing that the expression of a subsidiary crankshaft, arranged in place and center crankshaft.
As we have said, the first shortcoming of machines rotary machines rotary machines do not have connecting rods, and that for this reason they have lost the effect of connecting rod. Gold at the light that what we have just demonstrated, one could say that if some parts of standard rotary machines have been carried out together, these are not not, as in sliding motors, connecting rods and pistons, but rather, as in the cylinder engines rotor, the crankshaft and the compressive part, the cylinder. We think that machines rotary machines are rather machines in which, as in the example above mentioned, the crankshaft master was made in one of the parts compressive, here the blade. Yes this is true, we could say that what we generally hear to be the crankshaft of a rotary machine, when carried out by induction of first degree, is not in fact that the subsidiary crankshaft thereof, the master crankshaft being made of way confused with the blade.
Fully rotating machines, such as machines in staging and already commented poly induction machines would include the correct arrangement of compressive parts, motor and ligature parts.

If this assumption is true, it can be said that in all standard achievements, namely first degree, rotary machines, the master crankshaft is retracted from his position central, to be replaced by the subsidiary crankshaft. From then on crankshaft master himself is realized in a way confused with the blade. So we see here that the second gap fundamental of the machines, namely that the master crankshaft of these is made in periphery, in a way confused with the blade, is quite a corollary of the first, in which it has been recognized that the parts of the machine have been lowered realization of certain elements.
Third fundamental flaw of ~ ankle: the realization of ~ erentiala post rotating ' machines.
In the previous discussion, we used examples of pistons, for show that the first-degree engines in a way reverse the pieces of the machine. But the main example, namely that of the rotor cylinder engine, remains imperfect.
In this one, actually, the crankshaft is moved in the cylinder, then that in the engine Rotary, it tests in the blade.
We will have to go further to give a valid image, when realized as engines to piston, rotary engine. This image will make it easier to achieve the third gap which we are talking about here.
To make the reader understand what we are saying, we will use one more example times taken from reciprocating, standard and rotary engines.
As we have already shown, standard piston engines, the best editing when are made with a fixed cylinder, and that when they are made with a rotor cylinder, as shown in our already cited Canadian patent and examples already cited However, in the rotor cylinder machine, the crankshaft, as we showed it previously is subdivided, and one of its parts, the crank pin is realized by the support axis connecting rods and pistons, and (other the central axis of rotation, by the cylinder rotor. It is possible, as that we have shown in our Canadian patent application titled Machine energetic poly crank and Machine inducti ~ n simple to achieve a movement of contraction and expansion of the cylinder and the piston by increasing the degree of the machine in splitting the crankshaft so to speak, that is, while keeping the part that has been allocated to the cylinder, completely rebuilding the initial crankshaft. The resulting will be an engine hybrid, consisting of both a standard engine, and a cylinder engine rotor. (Fig.l6.2) Such that we can see in the same figure, the opposite action or in the same sense two pistons can be obtained with a fixed cylinder and poly crank crankshafts in opposing dials and in same dial.
The action of this new crankshaft can therefore be determined in the both directions. one can indeed increase the post rotating speed of it and make it greater than that of cylinder, or invert it with respect to that of the cylinder. In doing so, we will reduce more power of the machine, or it will be increased. Indeed, in the first case, the thrust on the piston is realized against an element, the cylinder, which trip, though more 2 ~

slowly, in the same direction as this one. The developed power is therefore in part contradictory. It is produced only by the difference of the thrust real, less against pushed by the reaction on the cylinder. That's why we'll talk about push simply differential.
Conversely, when the crankshaft is activated in the opposite direction of the rotor cylinder, both The parties are traveling in contrario, and the expansion is taking place in the two parts. As in two cases of the transmissions coordinate parts, the power, in the second case is not differential, but additional since it is the result of contrario movements Parties.
We can therefore deduce more given examples than the most comparable relevant rotary machines, and particularly post rotary machines when made to piston, the rotational induction rotor cylinder motor, when realized with connecting rod straight. In this motor, the force is only differential, and in addition (effect of connecting rod is obliterated by the use of sliding rod.
summary These three fundamental flaws would explain the little power of these machines, and would open doors to a set of new solutions that would end up determine the best position of the crankshaft and other elements.
Our solutions by staging and poly induction show that it is possible to correct advantageously these gaps. A third type of solution, original and extremely advantageous in many ways consists of the solution by clockwise blade movement and cylinder rotation, whose dynamics have been shown in the first part of this work. In this part we will generalize this dynamic and show the relevance of this generalization under the name rotativo-circular machines. (Fig. I7) In the next part, we will go further, generalizing a dynamic of our first work that can be done centrally and independently, especially in methods by poly induction and by inductions, and that its way realization confused this time with the cylinder, in the rotativo engines circular, is certainly the.
realization which cuts off all the errors of design already commented, and who is the realization implementing the deep nature of these machines.
Summary of this first part In summary of this first part, we can therefore state that nature deep rotary therefore would be contrary to that of piston engines.
In standard engines, it is quite easy and obvious to realize of the veracity of this statement, since one can easily compare standard machines to their derivatives dynamic, rotor cylinder machines and one can see enough easily or have passed the elements.

In rotary machines, the. same finding is much more difficult because these machines have been made by use, by experience, and that by therefore, the story mechanics designed them from the start in an inverted way, in the absence of benchmark representation to gauge this counter orientation. Poly induction and staging Induction allow this understanding. So we worked as if, in the engines piston engines, standard engines were invented after rotor cylinder.
In summary, and as surprising as it may seem, one must understand that in the engines rotary in their standard form, which plays the funny central crankshaft is comparable to a rotating link, or a subsidiary crankshaft arranged centrally and that the crankshaft reality is realized externally, concealed and confused with a component peripheral, and compressive. blade.
Second part Horizontal reintegration of the rod effect: Motion machines clokwise% ylindre rotational, and horizontal dynamic generalization: rotating machines circulars or rotativo-orbitals We now know that the three previous shortcomings are in the. times present in all Wankle machines. Not only is there an excessive lowering of the parts constituent of a prime mover, by the confused realization of some of they, but also that this confused realization is in the opposite surplus, in that it is not, as in the case of sliding link motors, Ia. connecting rod that is realized in a confused way with the party compressive, but the crankshaft, and in post-differential surplus, which decreases the power of the machine.
The motive power is thus cut off vertically horizontally. Those are, simultaneously realized, these entrenchments and inversions of the parts that are the causes deep of the. failure to realize the explosive power of the machine.
Moreover, as one will have noticed, even if the mechanics with staging and poly induction correct to a large extent the fundamental shortcomings of the prior art already stated, they do not are not themselves perfect. The mechanics by staging will offer very certainly some resistant to marketing. We will oppose than to control the displacement of a blade supported by the rotation of two crankshafts superimposed, may indeed cause some very material difficulties. Moreover for the poly induction, we can contrast that the use of three subsea crankshafts for a blade does not represent a economy compared to that, in a standard engine, to use three pistons for a crankshaft.
Moreover, showing that the position of the crankshaft confused with the blade is not relevant, the question of whether to bring the position of it as master crankshaft master, as in piston machines is the best provision for rotary machines.
Observation from the master crankshaft of inductive poly machines And realization of the birotative movement clak ~ .vise machine ~ g18) Note from the start that we have shown the sequences for a tour of mechanical Clokwise, first, second and third level in the first part of this book. In Ia this part, we will provide more in-depth theoretical explanations, We will generalize these achievements and we will determine in a rational way the rules of composition of mechanical assemblies to adequately support them parts compressive In response to the objections and questions raised above, a new type of observation will be relevant, type of observation that will be made possible by the realization mechanics of the method by poly induction.
In poly induction machines, the rotation of the master crankshaft corresponds to a rotation equal to the relative velocity of the blade. It is assumed, in this type observer, an observer positioned on this master crankshaft, and observing, as in the cases previous behavior of the cylinder, the blade and, in addition to the crankshafts subsidiary. We must deduce that even if for us, outside observers, this master crankshaft is in rotation, for the observer being positioned, waiting for its constant speed, the frame reference will give very different results. Indeed, the observer will see clearly the components of Clokwise circular ring rotary motion in its entirety Indeed, considering the movement of the blade, the observer will note on the one hand that the rotational positioning movement of this one is circular, and otherwise that aspect immutable orientation, that is to say that the orientation of the latter does not vary not, despite the circular action of his center. Like clockwise that turn, the figures of it always remain in the same angle, either perpendicular. That is why we called this specific blade movement, Clokwise movement.
Conversely, when the observer directs his gaze towards the cylinder, he does not will see him more as we see it from (outside, ie as a fixed element, a fine element but rather as a rotationally activated element in the opposite direction of the movement positions) circular of the blade. The observer will therefore face virtually, the first expression of Rotary circular rotating machine, blade movement machine clokwise / cylinder rotational (Fig. I 8) Another construction to achieve the Clokwise movement, and to show that it comes from the poly induction die, unknown to Wankle t these predecessors, is to grip the crankshaft of a poly inductive machine, by example in a vice and activate the remaining elements. We will see then that the. pale product very exactly the clokwise movement and that the cylinder produces the rotational motion at contrario. (Fig. 18) Concrete realization of the clokwise machine The Clokwise realization of the machine will be produced when one realizes material way the observations of (observer as previously positioned.
It follows from these explanations that the most obvious practical realization of the machine will be issued a revitalization of the very mechanics that made it appear. One can indeed imagine, from this observation, that since the crankshaft is motionless compared to the observer, it will be immobile, and can therefore be realized in a confused way with the side of the machine. Secondary crankshafts will be equipped induction gears and will be mounted rotatively in the side of the machine. They will be gathered by a means such as third gear, ensuring the similarity of their rotations. The blade, which will be climb on these vriplets will therefore perform a strict circular motion without movement Orientational, a movement called Clokwise. The gear uniting the gears Induction will be (dynamic support gear, and will be additionally coupled to the cylinder, which will provide the retrorotation. (Fig. 19) The same procedure can be performed for machines retrorotative type but using a dynamic support gear of internal type. note that clokwise moving machines of post-rotating figuration realize, a movement contrario compression parts, and figuration machines retrorotative realize, when they are mounted at the initial degree, a movement in the same direction. We return later on these types of criteria most important to machines drive.
Specificity and originality of the clokwise movement and the rotatàvo dynamics circular.
If we continue the understanding of the engines as we have initiated, will realize that the clokwise blade movement machines are original and important, for several reasons, both mechanical and theoretical. These machines correct in all the defects and deficiencies of the n ~, chines rotating fart previous, and this is understandable since this one Exceed the normal categories of these machines to achieve both the qualities of piston machines and turbines. As we will show later, the specific movement in Clokwise can be obtained by an important set of combinations of mechanical.
However, the previous embodiment, by fixed polyinduction already allows understand what follows. The movement in clokwise has the mechanical and theoretical originalities following major.
(Fig. 17) A) the machine, unlike any machine of the prior art is, dynamically, perfectly birotative. Indeed, as can be seen, the blade has no rotation orientational. It is neither post-rotating nor retrorotative. She has one derotation from at the crankshaft very exactly located between the rotary post derotation and rétrorotative. She is therefore perfectly birotative, so it has a sianilary nature not machine rotary machines of the prior art, but rather to that of poly turbines. By its nature, she will always require two inductions to operate correctly the paxties.
B) The machine does not realize consequently, unlike any machine of the year.
prior, no counter-thrust on the blade. Similarly and even in a way greater than that of a piston, the thrust is achieved not only over the entire surface of each face of the blade, but also perfectly distributed on each side of the points poly support inductive inductors of these (Fig. 2tl).
once for all to compare advantageously the thrust of rotary saddle machines engines piston.
C) the machine, unlike any rotating machine or postons of art previous, and similarly to the turbines, the blade movement cdokwise, as well as the parts mechanics do not produce any acceleration or deceleration of any of the parts D) the machine distributes the stages of the poly induction or inductions this time horizontally, which cuts off any vibration in the machine E) the curvature of the cylinder will cause its retrotation, and this retrorotation will make an effect similar to the effect of piston engine connecting rods, and a: force additional to the machine.
F) the parties render horizontally the minimum number of parts constitutive to realize the machine in its driving nature.
G) finally, blade and cylinder are in contrario movement, which we do not found at no place of the prior art, except for our achievements of induction machines simple, made pistons. and rocker pistons.
Rotary rotary vane motors in clokwise movement therefore have both, qualities of piston engines, rotary machines of orbital motors and turbines, while only having few of their faults complies; fs.
Indeed, if we compare these machines to piston engines, we see that the pale of these machines accept a thrust evenly distributed as in the engines to pistons sees that any point of the blade and therefore of its surface, travels to the same speed of a In some ways, it can even be said that the thrust is greater than that engines to pistons, since the blade is directly connected to the crankshafts, makes the angulation of the non-existent link will result in a lack of friction and expense energy caused by against negative spurts Moreover, if we compare these machines with rotating machines, we see that they can to use the same figurations, and consequently to create chambers of combustion In addition, the rotational # of the parties may allow the use of light valves Finally, if we compare these machines to the turbines, we see that like turbines, except when done with the help of polycammed gears, all parts without exceptions travel at a constant speed and that there is no acceleration and deceleration of any mechanical or compressive parts.
It is therefore a kind of prime mover located at the confluence of machines motor of categories totally different from the prior art, which recovers the most qualities essential of each of these but recover little of their defaults. The thrust should give them the power, the figuration a minimal number of pieces and rotativity a maximum velocity and longevity and unequal motor machinery ~ g 21).
It should be noted that the geometric dynamics of the poly induction contrary, as we have shown it to Wankle's, is the dynamic that allows to realize a just cutting and valid movements in the composition of the planetary movement of the blade, in two specific movement, and by the. continue to render them horizontally by the dynamics clokwise / rotational cyündre.
If our reasoning is well founded, it will allow us to respond now to the question that we had previously left in suspension. We have shown that designs Wankle geometrics and prior art thinkers had reversed the composition of parts by placing the crankshaft in a manner confused with the. pale, of peripheral way and planetary, which deprived the machine of all its. driving substance. We have subsequently restored a vision So to speak "piston" of the machine by making it by crankshaft master and secondary, wondering if it was really the most relevant.
In the light of what we have just shown, it appears that the provision more relevant is to realize the machine horizontally, realizing the crankshaft way confused, this time with the cylinder, As surprising as it may seem, then, while the dispositi ~ n less pernicious for piston engines are those of rotor cylinder machines, it turns out to be for rotary machines, the most relevant Clnkwise moving blade machines and rotary-circular machines eh general generalization In the. next section we will endeavor to show that machines Rotativos Circulars constitute a specific type of specific machine, realizing so to speak engines in their horizontal plane, as opposed to the vertical plane which we have showed existence in the first part.
To do this we will show mainly that rotary machines circulars can be produced with all existing inductions, in Ia. extent that one specifies the notions of serai transmissions, induction rising and falling.
We will then show that they can receive all types of blades from standard machines.
We will then show that they can establish different degrees of realization by dynamics.
We will then show that a correct understanding of these machines requires to distinguish their material, virtual and Real aspect. Finally, we will show that (all of these generalizations will allow us, by the. combination of both vertical and horizontal, of produce a synthesis of the global and relevant criteria of any driving machine.
More specifically we will deal with the following points Mechanical generalization a) Clokwise movement by central induction.

b) the methods by serai transmission considering them as an induction spree center to center, horizontal induction c) induction induction and induction induction and induction methods horizontal d) and will show that stepped induction combinations can be produced horizontally, and allow the support of the compressive parts of machinery rotativo-circular Figurative generalization e) that every rotativo-circular machine possessed all variants of any other machine, namely that it applies 4) just as much to post-rotating machines as retrorotative, 5) that they apply to these machines of any number of sides 6) they apply to rotary machines, such as poly turbines 7) that they can be produced also accelero-deceleratively 8) that they can also be produced with combinations of simple blades cylinders, single blades, standard blade poly faces, blade structures Dynamic generalizations 9) that they can be realized in degree, by clokwise blade movement of first degree, second degree, these degrees can be achieved horizontally or vertically IO) that they can have various degrees of differential mechanics retro and post rotary, and on the contrary II) that, when carried out on the contrary, they can achieve both figures Material, Virtual, and Real Cylinder I2) What can, like static cylinder machines be performed in parts bifunctional compressives These additions will allow us to globalize our entire company and show 13) that all of the possible machines can be arranged in ranges color 14) that the determining characteristics of all machines can be specified a very broad set of generic criteria, encompassing the criteria for art prior IS) that several semantic difficulties of the prior art can hear correctly specified: suitable mechanics for dynamics to rotor cylinder, meaning of the machinery I 6) That not polycamation mechanics can also be adapted to contain the standing forms of retrotrotative machines 17) that they can be performed in center-proximal inversion, by cylinder clokwise / rotary blade Mechanical generalizations the Clokwise movement by central induction.
One must note right now another very interesting characteristic of dynamic clokwise. In it, every point of the blade exactly describes the movement clokwise, and even the central point of the blade. Therefore, the blade can be supported by its center. In addition, it is important to reiterate the character and perfectly birotative nature of this movement. Starting from these two ideas, Pon will find that, to ensure support by the center of pale in motion Clokwise, fon will be able to use any induction resulting from an observation by the crankshaft, in taking care to realize however original gear ratios of support and induction ensuring bimechanics, either gear ratios of support and induction of one on one.
Indeed, in the prior art, as we have said, we mean always turn the pale in such a way that it has a distinctive orientational character, post rotary or retrorotative.
Therefore, the gear ratios are always carried out either by support gears bigger, during retrorotative achievements, evening by support gear smaller ones, for post rotary achievements. Clockwise achievements of blades and induction ratio of a on a that require their support are not are not in the order of thought initiators of the prior art. This reporting requirement, original to the implementation of the Clokwise movement can be explained by the fact that to achieve a non rotation orientation of the blade, it is necessary that it undergoes a retrorotatïon perfectly equal to the post rotation of the crankshaft. Since the central crankshaft of these machines is equivalent to crankshafts subsidiary of the poly induction concentrated in one, and that all inductions are possible for this one, same methods apply here, respecting the above mentioned. one can therefore realize the orientation support of the blade by intermediate gear, by hoop gear, by active central gear, and so on, in respecting the clokwise report one on one. By the way, the use of single-inductive induction simple is impossible, which shows the originality of this machine. It takes to realize the movement clokwise, by this induction, use the. method will be transmittive of it, method by which the retrorotation of the support gear will speed up the orientation reversal of the pale at the speed equal to that of the crankshaft. (Fig.22) So we know now that it is possible to realize the movement clokwise of pale by poly induction faxe, the induction gear being driven into the same meaning by via an external gear, internal, by chain, or even we can realize the clockwise blade movement by central induction of one-on-one ratio.
But like stage machines and poly induction machines, the machines to Clokwise motion restore the levels of rotativity needed for a full motor action and whole. Like poly turbines, by their very nature, Clokwise movement are second-rate machines since they always require two inductions, this time horizontally arranged. It is necessary to proceed, in a supplementary way at the helm retrorotative, or post rotary, depending on whether it is post rotary machine or retro-active, from rotational cylinder.

To do this one must first specify three notions which are those horizontal induction or served transmittives, then of rising inductions and inductions down. (Fig. 18 b) Induction served-transmitting or horizontal inductions We have shown on several occasions the importance of the transmissions, these allowing to modify the initial figures of the machines, or to make these machines capable of rendering Their retrorotative and post rotary power of the same blade.
It can be said that there are mainly two types of service, transmissions accelerative or decelerative, and inverse transmission.
It was also said that each of the serni transmission could be produced with gears standard, external or internal, or gear gears. (Fig.23) In circular rotary machines, it will often be necessary to realize in a confusing way Inverse and accelerative serai-transmissions. This will happen mainly when the action of the cylinder will be activated by activated relative to that of the eccentric. Since the cylinder acts to contrario of the blade, and at a different speed from it, it will take a served transmission realizing at once both these necessities.
The inductive signaled inductive poly induction is very simple from this aspect.
It's about having rotatively in the block of the gear machine says gears inversion. It will be provided subsequently, as necessary, the tree of the crankshaft of a external type gear coupled to these gears, and will provide the cylinder rotational machine of an internal type gear. This gear will be the same coupled gears inversion. The result of such an arrangement will be a condensed way of perform the antirotation and the speed reduction of the cylinder relative to that of the crankshaft.
Note that in some opportunities, the speed of the parties may be equal, and in other rotational cylinder will be superior. It will also be possible to use gear gears. one will couple one of gear gears at the crankshaft and the other at the cylinder. We will couple these two gears by through a doubled inversion gears, taking care of choose one of the two gears with one dimension superior to the other. Each of these gears is coupled with the crankshaft or cylinder gear. We will get both antirotation this of these and the necessary speed difference required. (Fig.23) Generalization: we state that all Inductions can thus be processed into served transmission, and for this reason, the transmissions may be the purposes of these to be aptly named horizontal induction. We will find, in our patent applications prior art, as well as in patent applications that were preceded by present several examples, all of which meet the present definitions.
Mohtayate and descending Induction Rising inductions are understood to be all first-order inductions of the prior art than our art and higher degrees, whose support gear is disposed of central way, and whose induction gear is arranged at the periphery. For example, inductions by mono induction, by hoop gear, by poly induction are inductions rising.
Conversely, if we have a support gear, this time in periphery, be fixed rigidly on the crankpin or, for example, on the crankshaft blade of a machine, and that starting from this gear, one activates a central gear, one by induction down. The use of these two inductions in combination in a machine standard can allow to create a blade support different from the axis of traction which him will be activated by the blade. It would be there, at the limit of a method by serai transmission Elisha. (Fig. 23) In the case of circular rotary machines, one can on one side of the pale, activate the movement in Clokwise of it, and of felt side, fix to the blade a support gear peripheral, and by the use of an induction, for example by gearing hoop, train the cylinder rollback. (Fig. 23) The three main methods of supporting rotativo machines was circulating from first degree to clockwise motion As we have shown for stepping inductions in height, since exists more of about fifteen induction of first degrees, and that each can be combined with a second induction of first degree, this one being however peripheral, one has a total strong impressive of inductions.
Da la. same way, if yours accepts the simplification we have previously produced at the effect that any transmission will be a horizontal induction, or in other words a induction neither rising nor descending, but rather fired on the same center, or on herself, and therefore any induction can be transformed into serai transmission, and other by Circular rotary machines always need two induction confused and coupled, we realize that there is again an impressive number of combinations induction possible that it would be difficult to list in full.
A rational and synthetic regulation of the organization of these will not have to expose all, and both to encircle properly. This rule is this The combined support of any circular rotary machine can be realized using, as combinatorial part, ~ g. 24) a) the blade, (b) the crankshaft, c) or the induction gear of cylinder, each of the inductions uplink, descending or will be transmittives being combined with this same element as one's will have determined.

To better understand the reason for this last statement, it is enough to take the idea that the cylinder movement and that of the blade must be perfectly coordinated and synchronized.
Therefore, their inductions must also be, which means that they must have a dependence characteristic of one to another. In other words, he will have to be at least one of the parts of their respective action, which is shared, who is the same for both inductions. These pieces will be either the blade or the crankshaft, the gear of induction.
Combinational interdependence by blade.
General rule, it will realize (interdependence of the systems through the pale activating, as we have previously shown, the Clokwise movement of the blade by one of the induction, with ratio of one on one of the support and induction gears, and active, conversely the cylinder, again from payroll, by a downward induction, having on the blade a peripheral support gear, and on the cylinder rotational one induction gear. (Fig. 24) In this way, when the blade is activated by the crankshaft, by the use of its induction rising, it will activate the cylinder, and conversely when it is activated by the cylinder, by the resort to its downward induction, it will activate the crankshaft Any induction can therefore serve as rising or falling induction.
Combinatorial interdependence by the crankshaft In the methods of combination of induction by the crankshaft, one will realize from the crankshaft a rising induction of one on one that will ensure the correct movement in Clokwise of the blade. Moreover, it will link as shown previously cylinder and the crankshaft through a serai reverse-accelerative transmission. By therefore the movement of the blade and cylinder will be fully coordinated. To realize this type of induction, we can use, for the blade, any induction, and for the cylinder of all serai transmission. Several combinations are therefore possible. one will consult our work, in antecedence, and our previous work, to take cognizance of several examples to this effect. (Fig.24,55,56,57) Combinatorial interdependence by blade support gear.
As has already been shown, it is necessary to produce the report of the support gears and blade in an order of one to one to ensure the Clokwise movement of it. By elsewhere, we know that it can, to the extent that we modify appropriately the report of size of the support and induction gears, one can dynamise the support gear of induction, making it also transmittive, without modifying the filming reports orientation of the blade with respect to its initial dynamics. It is therefore possible, from crankshaft to carry out a retrorotative management and will be transmittive of f support gear of a rising blade induction, which we realized at several in our works In the case of circular rotary machines, it will be necessary to motivate the gearing of dynamic support in such a way that while allowing the respect of the features one on of movement Clokwise, it activates, being fixed there rigidly the retrorotation of the cylinder, therefore fon can say that the same will be transmission, will activate the support gear dynamics of the blade, and that this dynamic blade support gear, will, in a confused way gear of cylinder induction. So the two systems will be, in a broad sense, connected by the same transmission, and in a restricted sense by the gear, serving Support gear to one and induction gear to another. (Fig. 24) As before, more configurations are possible, since there is several serai transmission, but the logic will remain the same.
Figurative generalization Clokwise moving machines of post rotary and retr ~ rotating blades.
Although of original dynamics, recalling as we said the qualities engines to pistons and turbines, circular rotary machines use the new way the figures geometries of the blades and cylinders of the prior art. Rotating machines circulars Clokwise blade movement is therefore equally feasible type of figuration retrorotative than post rotary. However, it should be noted that their dynamics is different in what, while Clokwise post rotary motion machines realize a movement of contrario compression parts, retrorotative type machines, make a movement of blade and cylinder in the same direction. (Fig. 25) Circular rotating machines with blade movement in Clokwise and number of sides.
As we have already observed, the figurations of the compressive parts of machinery circular rotativo are similar to those of standard rotary machines, when these are carried out in first degree. It must therefore be specified that all the figures of retrorotaive machines or post rotatives can be realized in mechanical rotativo circular, to pale in clockwise movement. Indeed, for example, in a post cylinder machine triangular and blade in four sides, the blades will always have Clokwise movement and the cylinder will be always antirotational. Similarly, in retrorotative figurations, the pale in three sides will have a Clokwise movement in the same sense as its strictly rotational cylinder.
(Fig. 25) Circular rotary machines with blade movement in clokwas and machines birotatives The machines of the polyturbine type, including the cylinder and the pale structure of compression have been invented by Wilson and we provided the proper mechanics when the cylinder in was fixed, can also be performed in their rotativo-circular form.
In these cases, Subsidiary crankshafts, with the addition of geometry rods, will not strictly that circular action, which will conduct the squareoidal losango of the structure paddle. Their induction gear will be coupled to the cylinder gear which, rotationally will complete the system. It will be noted here that even though the induction crankshafts and the cylinder have no acceleration deceleration, the structure pale, more complex, realizes its oscillatory aspect, aspect on which we will return later for any machines. (Fig. 26) One must also note, as we will see later that several degrees of circular rotativo dynamics will be possible for all machines, including poly turbines.
Circular rotary machines with blade or cylinder movement acCéléro decelerative One can, as for any machine, to use in the assembly of the machines circular rotativo polycammed or polycapped derivative gears, which will produce changes in the forms of cylinders resulting in accelerated decelerative movements of the parts. One gets will serve as similar to those we have already described in our turbines differentials, which the cylinder will be supported by polycammed gears, realizing a action support strictly circular, but accelerated-decelerative.
For example, we can decide to keep the rotational movement of the cylinder its regularity but give the Clokwise movement a certain irregularity decelerative. one will thus modify the cylinder and we will realize a dynamic thermodynamic superior, as when this is applied in standard machines. In machines circular rotativo, f on can inversely realize the movement of the rotational cylinder in accelerated decelerates. (Fig. 27) Circular rotating machines with Cl ~ kwise blade movement: blade types Circular rotary machines can be made with the three types of blades can also be used in standard machines.
First, it will be possible to use a combination of single blades cylinder and produce explosions either between each of them and the cylinder, or between them and the cylinder. (Fig.28) From these two ways the combustion chambers may be common hearths, which will have the effect of multiply the crankshaft reach by two. This will increase considerably compression ratio and realize these machines with a gas stewardship diesel.
Of course, we can realize these machines with multiple blades faces, ie standard blades, or as we have previously determined with blade structures, (Fig.
28) Circular rotating machines with blade movement in Clokwis ~ and number of degrees, The Clokwise movement in its most natural state is realized by movement position) of blade circular. It can, as we have also shown in the first part, be non circular, by rectilinear example. (Fig. 29b) It can also, when the scope of the central crankshaft is wide, fit into a cylinder movement not rotational, but itself planetary. In these last two cases, it is necessary to increase fane degrees inductions to realize the machine (Fig. 29c, d) The Clokwise rectiligo blade movement requires effect a staging d, induction. In addition, planetary driving also requires a degree higher induction to simply rotational driving. .

Circular rotary machines with blade movement in Clokwise and movement oscillatory symmetrical and contrario of pale One can also realize oscillatory Clokwise blade movement with recourse to polycammed inductions. In fact, reports of one on one will remain maintenus for a turn, but with the use of polycammed gears, the movement perfectly fixed Orientation will now be variable, alternatively. (Fig. 30,31) This will make it possible to realize the odd-cylinder machine figures and to blade movement contrary units, and to realize the oscillatory nature of the poly turbines.
Circular rotating machines with blade movement in Clokwise and movement of cylinder Clokwise and Rotational Blade We have previously shown that it is possible to carry out machines with blades fixed and planetary cylinder. In these cases, the figure realizes is a figure virtual corresponding to the actual induction of the machine. For example, a type figuration triangular, in which the cylinder is planetary and fixed blade, requires machine mechanics rotary post figure three sides of the blade on both sides of the cylinder. This means that the fagure appearance retrorotative is the virtual figure of the post rotational real figure, in complementary position.
In the same way, Clokwise figures can also be reversed from center in periphere.
To achieve these inversions in a perfect way, it is necessary, as in the case of standard figures, arrange the figurations in their complementary sense, and use the mechanical support of the real figure and not the vatic figure. (Fig. 33) Thus, one can realize machines possessing a Clokwise moving cylinder dynamics and a dynamics of blade perfectly rotatonic. Of course, as before, this cylinder can to be a whole of single cylinder, in standard polyfaciated cylinder, or in structure palmar-cylinder (Fig. 26) Likewise Clokwise cylinder motion machines can be realized in bifunctionality, these cylinders of one being simultaneously used as blades of others.
(Fig. 56) These procedures allow for powerful turbines or gears of type two times or backflow.
Dynamic generalizations Circular rotativo machines and dynamic degrees We have shown previously, circular rotativ ~ machines can be increased degrees by changing the stroke of the center of the blade, while keeping intact Ia fixity of (aspect orientation of the blade of the machine. The degree of the machines is thus to say it was increased figuratively, not dynamically. The next loans will have for object than show that rotativo-circular machines can be increased by degrees this time of dynamic way. So we'll expand the notion of Clokwise motion machine by that of rotary-circular machines We will see in the next comments that the dynamics Clokwise are not only practical point, and this in relation to the qualities we have already stated but also, from the theoretical point of view. We will show in ej ~ '"and since they constitute an axis of major segmentation to achieve the delimitation of dynamism of the machines and to realize the understanding of the engines on a completely different plan, from the angle degrees of dynamism. These understandings will make it possible to create a plan ranges rotary machines, and to correct several errors in semantics of machines thinkers of the prior art, while encompassing them in a theory much more general, possessing much more powerful machine characterizations and effective.
The next remarks will show that we can realize dynamics similar in rotary machines of the rotativo-circular type, only in the mechanical piston cylinder with pistons which we have previously exhibited as an example.
Indeed, so far, we have only commented on rotary machines circulars at movemern of pale in Clokwise. It is possible, however, to make machines with the movement of pale will not be. One can for example assume a machine whose blade movement, a blade of two sides will move in a cylinder on one side, this cylinder being however no fixed, but rotational (Fig. 33) It will be considered in this first case that the blade to a retrorotation him to achieve three faces. The feedback of the cylinder will compensate the figures. one will then find that one can realize the machine in such a way that the blade and the cylinder act in the same way. The push then, between the parts will only be differential.
Conversely, we can assume, for the same type of figure, a movement rétrorotationnel slower blade, and a rotational post movement of the cylinder allowing to fill that alteration. (Fig.34) Again, but this time post actively, pale and cylinder will act in Ie same meaning, but differentially with respect to each other.
Finally, we assume the fixed cylinder mechanics, (34) or the force achieved is neutral, and the dynamic movement Clokwise, (Fig. 34) in which the movement of the blade and cylinder are on the contrary, thus developing a lot of energy. In the last place, we can, as did Wankle, realize strictly rotational blade and cylinder (Fig.
34) So we see that for the same figure, five very different dynamics are possible.
Comprehension To better understand the rationality of the last examples, we will state a formula that can subsequently be applied to any machine. We'll say that this formula is the mechanical dynamico regularization formula, or counter part formula cylindrical. This formula can be stated as follows.

In any machine, one can for the same figure of pale cylinder, move the next place of compression in front of it or delaying it compared to the standard next compression, this standard place being realized when the cylinder of the machine is fixed. Against part, a mechanical regulation will be carried out and the cylinder dynamically be moved so far.
Let's give an example. We know that during a standard dynamic, for example of pale triangular and cylinder on two sides, we can measure the difference angulation between various blade highlights, corresponding to the locations of explosions successive, and that in this case, we realize an angle of one hundred and four degrees. In the engine triangular, one hundred and twenty degrees separate each place of explosion. (Fig. 34, 35) One can determine for a figure, freely any new place of perpendicularity to the eccentric of the successive surface of each face of the blade. By Therefore, this planned point new expansion will not achieve by standard fangulation provided for the new blade recovery. For example, if one wishes to realize the new point of compression no not to one hundred and eighty degrees, but rather to sixty degrees, we will realize that it lacks the a movement of a hundred degrees in order to be realized in a standard way.
So we will have to compensate will therefore have to compensate for this difference by regularization mechanical in applying the angulation difference of this new maximum expansion point and that standard expansion cylinder. Therefore, it will be realized here at cylinder one retrorotation of one hundred and twenty degrees.
As we see, if this point is prior to the standard explosion point, it will have to be compensated by a retrorotation of the cylinder, equivalent to the same angle separating these two points. By elsewhere, if it exceeds the standard explosion point, f print at the cylinder a post rotary action whose angle will be equivalent to this difference for maintain.
For example here, if we intend to produce the next explosion two hundred forty degrees, fon will calculate an additional sixty degrees at the standard position. The cylinder so will post actively be activated sixty degrees. However, this rule alone fails to perform a correct and complete rendering of all the mechanical possibilities in the material. For good to understand the types of rotativo-circular machines thus created, it is necessary to appeal to the notion retrorotativity of the blade.
As we have already mentioned, in any rotary machine, the blade has a action retrorotative with respect to its eccentric. We also determined that the retrorotative action more or less pronounced allow to determine if the machine was post or retro nature mechanical. In the two previous examples, we will have noted that we have, ahead or by delaying the moment of explosion, increased or decreased the speed of derotation of the blade of Ia machine. Analyzing these examples in more detail, realizes that when the blade of the machine reaches its next compression after only sixty degrees, she thus realize six explosions per turn. The retrorotation will be accelerated to such an extent that will have to use a retrorotative type induction, for example a mono induction with internal support gear and external induction gear. In the second case, the backwash speed will remain low and the machine will remain post rotary type.

The year thus sees that, for the same figuration, the dynamico alterations mechanical machine make it go from rotary post to retro rotary.
It is here that once again, Ia. mechanical clokwise movement of blade is important, since its dynamic, perfectly birotative nature makes it possible to consider it here as a segmentation terminal of the most important. We can still give an image of this birotativity of the machine in Clokwise, saying that the blade does explosions to the same places that his inverted figure, for example here triangular. The Clokwise is therefore an important mechanical hinge. Indeed, we can accelerate derotation of any blade post rotary, without changing the nature, to the Clokwise limit point. Yes we accelerate more the retrorotation of the blade the machine becomes retortative.
Figurative and mechanical proofs.
Mechanics is certainly the best proof of belonging to a machine class or at a other.
Here in Clokwise mechanics, mechanical achievements, in a ratio a for one are well a proof of the perfect bimécanicité of the machine. It does not pour on the side post machines inductive, or retro inductive. When using mechanics of this so, especially in mono, induction, it is necessary to correct them by served transmission for the make a bi rendering mechanical. Similarly, if we consider the definitions of blade movement by report to that of the crankshaft, observed from the outside to define the character post or retro rotary machines, we realize that again, the blade does not rotate in the same direction as its crankshaft nor in opposite direction, since it turns only positionally.
As for the capacity of retrorotative dynamic realizations, fion can Ia understand in that, as we have said, in the retrorotative machines, the derotation of the pale compared to his crankshaft is more accentuated than in post rotary figures. In understanding that this is the consequence, for the same blade of a larger number of cylinder sides and Therefore of a greater approximation these, we understand that this rapprochement, same product artificially, it also requires an accelerated pay rollover and a mechanic rétrorotative.
If one strictly observes the course of the movement of the blade of a rotativo machine circular whose blade has been accelerated beyond the dynamic biratative clokwise, one will find that it decreases a virtual figure d ~ erente of the figure materially, this time rétrorotative.
It must therefore be clear that the mechanical achievements of rotary machines circular account of these points and the need to take account of virtual of the blade for determine the proper blade blade mechanics, and the nature of Bette machine.
We will come back later to these notions of material figures and virtual and will show that it was also added that of Real Figure. But before that, it is necessary that deal with another important subject, that of differential movements and Conversely Differential movements and contrario as compressive movements or engines Important differences can be determined between the various machines movement rotary-circular, which this time are not related to the post rotativity or the retrorotativity, but rather in connection with the realization of these machines in their form compressive, or in their motor form.
Still there the Clokwise movement machines will be of use and notable relevance to define this statement. In fact, in this section it is necessary to conclude in clearly stating that if machines with rotary-circular motion can be subdivided into classes of machines, they may also perform another subdivision, more relevant, either in compressive or motor machines.
The following can be stated. Any machine whose place of next compression will be sated between the place of standard compression and the place of compression Clokwise, will have an action to contrario of the compressive parts, which will assure him a motive power.
(Fig. 45, 47, 4, 2)) We can also state the following, any machine whose next place expansion is posterior to the Place of next standard expansion will see its action compressive complemented by a cylinder action in the same direction. (Fig. 47,49) The machine will therefore remain post rotary, but will become rotational-circular and in its Campressive nature, since the resulting force will be that differential.
In the end, the following can be stated. Every machine donates it movement of retrorotativity will be accelerated beyond the clokwise movement, and which by therefore will realize his place of next expansion before the place of next expansion of this machine will become no only retrorotative, but also will lose its capacity in contrario, and will become differential. The machine will therefore be a rotational-circular differential.
Indeed as in the piston cylinder rntor machines that we have previously exemplified, rotary-circular machines can be subdivided into class of motricity, the opposite classes, and the differential class anterior or posterior.
If one intends thereafter to realize a visual image of the set of these possibilities, one will determine the following hinge points (Fig.49.2) a) the fixed position, (unison: this is the representation strictly figurative machines of varying degrees, when not in motion b) The fifth position: this is the first compression position when the machine is made by fixed cylinder, planetary blade c) the third position: this is the position of first compression of the dynamic decelerative d) the. octave position: this is the position of the pieces when all Ie movement when the.
next compression position is at the same point as that of unison It will be possible later to create areas of rotating circular machines.

So we will find a) between the unison position and the Clokwise position, the type machines d ~ erential ~ has atérieures b) between the Clokwise positions and the fifth straight position, the rotary machines-circular on the contrary c) and between the standard fifth positions and the octave position, the dynamic rotating-posterior differential circulars It should be noted that here we make these distinctions for post machines presses. We will show that these distinctions apply, by regularizing them, also obviously to retro-rotating machines, and planetary cylinder / fixed blade machines, or birotatives.
These distinctions are still insufficient to fully describe any machine. In the next section we will show how, with the help of virtual figures and Real figures, we can complete this last table, and make a correct rendering of more complex machines.
Material figures and figu ~ e e vàrtuelles In our last examples we applied a general rule of regularization of moving next explosion to counterbalance this change positions) material by a correct rotational activation of the cylinder. We will have noticed that we have randomly selected the new compression position, and in addition That we have made the corrections statically and only for this new compression.
It will be noted, however, that even though the rule we have given is applicable to any new position, the realization of the machine obtained will cause problems when these new positions will achieve more complex angles. For example, for a machine standard, if the new compression is found at thirty-seven degrees, this will take several turns to the machine before returning to the original position.
In addition, it will also be appreciated that certain new positions that have a semantico mechanical value. The most obvious, for example for a machine of a type given rotativity, for example post rotary, consists in giving a blade given, the new compression position of its counterpart, for example here retrorotative.
For example, since we know that a blade of two sides can just as feed a cylinder post rotary one side, or retrorotative three sides, we can take a blade of two sides and cylinder one side post rotary, and determine the point of next explosion at the same points only in a triangular retrorotative motor. We will make up for this change by one rotationalization of the cylinder, mechanically organized in the same way as for Ies Clokwise movement machines. (Fig.35.4) So we realize that the mechanics supporting the blade is exactly the same that mechanics of a triangular retrorotative machine, and that for this reason, if one follows the displacement of the pale, one realizes that it describes exactly this form. Otherwise, since the cylinder is rotational and that this arrangement was obtained by the change of position new compression of a post rotary machine, the material figure of the blade and the cylinder will remain post rotary.
Let's give a second example, this time starting from a retrorotative form, more precisely triangular blade and square cylinder. Normally, each new compression of this machine happens to all four comes ten degrees. (37.3) We can hear however to determine this new explosion at a hundred and eighty degrees. According to the rule given previously, it will proceed to a regularization by a post activation of the cylinder of four came ten degrees, the difference between the degrees of these two positions, standard and projected.
In doing so, it will be noted that control of the blade must be ensured by the same mechanics as that of a post rotary blade of triangular blade machine and cylinder of two arches, in however retaining the crank span length of the material form.
This will be confirmed by an observation, in isolation, of the action of the blade. By elsewhere, the rotation of cylinder makes it possible to keep the material cylinder of the first machine.
It can therefore be seen that it is absolutely necessary and concepts, able to allow us to account for these situations. Therefore, we will call the shape of blade and cylinder before alteration, material form, or material figures.
Moreover, as the shape described by the blade alone makes it possible not only to prescribe the mechanical but also to determine the location of such accessories, candles, places power and output, we will say that the shape of the blade and visually realized cylinder will be called figure or virtual forms.
We can then give other examples that are not simple against party. one can for example realize a blade figure of two sides, cylinder of one, post rotary, in one virtual four-sided revolving cylinder machine, explosion at all ninety degrees. It will be possible to produce a post rotary machine of triangular blade, whose explosions will do at all sixty degrees, thus realizing a retrorotative machine to virtual cylinder of six sides. We will take care to consult our patent application in antecedence for take in There are several other examples on this subject. (Fig. 35-50) Let us simply note here, the originality of the motion machine Clokwise of this point of view. The movement of the blade is realized in effect as if we had wanted make the explosion exactly in the same places as its counterpart not by mechanical but rather reversal, mirror, that of the triangular motor, or every hundred twenty degrees. The retrorotation of the blade is therefore accelerated, and the retrorotation of the cylinder is produced in result.
In summary, we can therefore enact the following that rotating machine tuft circular is composed of a material figuration and a virtual figuration and that the mechanics of the blade and the positioning of the elements and accessories can be made according to this virtual form.
Linked virtual figure and independent virtual figures As we have seen, in the standard figures, with fixed cylinder, a even pale can be activated in a cylinder on one side more, in the case of machines retrorotatives, and on one side less, in the case of post rotary machines. The machine realization having both a material form and a most obvious virtual form therefore consists of make a machine of a given cylinder shape and material blade, and of a cylinder shape virtual part counter-rotating. For example, we can make a blade machine two sides, turning in a material cylinder on one side, hence post rotary, and a virtual cylinder of three quoted, giving it its retroactive substance. We will still be able to realize a blade of three sides, turning in a cylinder of two, this machine being therefore of rotating post figuration material, and sultanate a blade machine of three sides rotating in a virtual universe four sides, reminiscent of the retrorotative machine. (Fig. 35.5, 37.3) It is important to note here one that one of the originalities of the machines virtualo-material consists in that in their virtual aspects, these machines are not subject to the rules of sides. Indeed, the machine can be made in such a way that a blade, for example three listed, achieves a virtual cylinder of four, five, six sides, and so after. (Fig.38, 39.1, 39.2) These possibilities will give increased freedom for the realization of various rotary machines, since they will no longer be subject to a rule of rigid sides.
In summary, the standard pair of pale figures entail figures of odd cylinder and conversely, virtual figures introduce a freedom since the numbers and their Even or odd characters can all be used Material and virtual figures, versus Actual Figure Slinky Movements and Real Forms The last notions we have just described must now be put in correspondence with the notions of compressive and type machines motor, these the last being expressed, in rotativo-circular machines under the idea that we also have commented, differential machines and contrario machines.
In all the examples already given, we have only spoken of machines whose next compression will happen, for standard machines on the next face of the cylinder, and for rotativo-circular machines, on the next face of the virtual cylinder But this dynamic disposition deprives us of developments interesting.
Indeed, it will be understood that the contribution of rotativo-circular machines is to be able to with a cylinder of relatively low count, for example triangular blade and cylinder of two rated, produce a machine with a high degree of compression, and at the same time realize this machine with a high number of explosions, as if it were a machine several faces of blade and cylinder. For example, by making the machine with a cylinder material of two sides and a virtual cylinder six sides, we get six compressions per turn, so that we would normally only get two.
Moreover, as we have shown, we will have to retroactivate the blade of this machine beyond the point of birotativity Clokwise, and therefore the machine will pass, no only post revolving, but also standard machine thrust simply differential, which will further reduce the power motor, and will realize in its dynamic form Compressive.
It is therefore important to realize the dynamics of the machine in such a way that it benefits the.
time of his material figuration, of his virtual figuration, but also of such that the machine not only keeps, but even increases its motor skills. he must therefore the machine can simultaneously perform contrario movements.
This is where the Sli ~ aky dynamic comes to the rescue, which we have prior to present, shown for piston engines. We will therefore use again once realize of our previous corpus, however to pistons, to give example of the next About.
As we have already shown here we can realize rotating a machine to pistons, under the idea of rotor cylinder machine. In the Slinky dynamic, he is to do work a single piston on the edge of the cylinder (fig.34) This type of achievement is impossible in the work of the prior art, since the mechanics to achieve this machine requires either a servo-transmission combined with a straight action obtained by poly induction, ie the use of polycammed gears, which will allow change the form of induction of first degree, or the speed of the rotor, so that induction and rotor can be combined. We will not dwell more extensively on these statements, for that which is the present purpose, and we will only mention that this procedure allows, compared to standard rotor cylinder machines, first of all to achieve cuts alternatively on each face of the same piston, and secondly to achieve of the compression "by jumps". the sum of all the compressions being done by therefore two turns, or more. (Fig. 41.1 and following) We can clearly see how figures that the piston acts in the manner of a Slinky, hence the name of this machine.
This solution can be otherwise understood by saying that compared to machines standard, one can produce successive explosions that do not match not to successions material or virtual successions. This type of achievement seems to At first sight impossible in rotating machines. In fact, this type of realization is not only possible, but also desirable.
One can indeed determine the location of new expansion at a location which is neither determined by the material material position of the latter when it is realized in its form standard or in the virtual position of the latter when gin consider the next expansion. One can indeed, as in the case of piston engines Slinky, produce this new compression by jumps, and to realize subsequent sequences of these jumps that will pass gradually across all faces of this new figure, in two, three rounds, or even more. This is Bette new way to achieve. following the compressions that we will have to establish new locations for candles, food systems and exhaust, and that is why we will say that the figure traveled by these jumps constitutes the Real figure of the machine. We will say this real figure, because it is on her that we will have to rely for actually realize the machine, ie, to correctly determine the locations of spark plugs, exhaust and fuel inlets.
~ J

From then on we will have for the machines a material figure, constituted by the figure of side ratios of blade and cylindre at rest, a virtual figure, which corresponds to the figure of realization of the number of faces and consequently the total of the machine, and the real figure, corresponding to the path traveled by the blade to achieve in totality number of faces.
It will therefore be found that for a material figure and the same figure virtual, several Real figures will be possible. If the number of faces of the virtual figures is high, some certaines of these real figures will realize their first compression, even successive, prior to point Clokwise. The machines will consequently be differential earlier, despite of these contributions. Some Real Figures will also have their first compression beyond the place standard of first compression. They will also remain differential, posterior, however.
But what really interests us is to consider that the place of the first jump, from the first material compression and non-successive virtual face will be realized between the place of first Clokwise compression and 1st place of first compression standard. The machine will then be contrario dynamic, and therefore in its Engine form and not in its differential form or Compressive.
As before, for the same material figure, several figures virtual are possible, and for the same set, several Real figures are possible. AT
as an example, it will be noted, for a figure of triangular blade and cylinder of two sides, a virtual figure in eight sides, and a three-sided jumping procedure, which will allow the pale to realize eight compressions in Slinky motion. (Figs 42 to 49) Care should be taken to read more closely our patent application filed in antecedence to this to take account for them multiple possibilities and varieties of this contribution. For the purposes hereof, however, it is of a absolute need to say why this type of figure is needed, and of realize that the contribution of these criteria of achievement and distinction are essential to machines Rotary-circular, This This contribution is necessary since it allows to reconstruct contrario figures in determining the point of the next explosion of any figure, independently of its material characteristic or virtual, This contribution will thus make it possible to start from material figures realizing a good compression, by example the figures three of two, to realize virtual figures realizing a number of appreciable explosions, for example the figures at eight, twelve sides, but in addition to doing so from a sequential figure with several Real faces, this resulting in that each explosion will be a contrario, since it will not realize the next explosion successive material or virtual, and is ~ inside Clokwise terminals / standard of production .
So it's important to note here that not only are the figures virtual are independent rules of sides of the material figures, but in addition that the figures Real, synthetic, are themselves partly independent of the material figures and virtual.
Mechanical processes of support This is for example what is produced when one increases the degree of a rotativo machine circular with clokwise movement by realizing for example a blade oscillatory, geared polycamées one on one. (Fig.35 a) The figwativernent was then increased degree of the machine.
For example, the degree of a rotary-circular machine can be increased by movement Clokwise of blade by realizing it with a cylinder either simply rotational but this this time planetary. This procedure can be very interesting if this cylinder is bifunctional, that is to say, if one intends to use it also as a blade exterior. This In particular, it will be possible for the surplus to produce retrore-clokwise way to contrario, this time by eccentrics to the contrary.
Against machines: machines with a cylinder and fixed cylinder, and cylinder Clokwiselpale planetary We must mention here that the forms of machines in their inverted state, that we name against forms are achievable, in the standard way by realizing the cylinder and pale in orientation contrary to the original orientation, and granting to the cylinder, the same mechanics than the original mechanics.
For example, a triangular machine shape, when the cylinder is is the planetary and the fixed blade, has an opposite orientation to a post rotary machine of three side of pale, two cylinder side and uses the same mechanics as this one. That is why, despite its shape, this machine remains post rotary. (Fig. 50) This is also why, the rotational cylinder can both be realized from bifonetionelle way, and on its outer surface realize the pay of a standard machine.
The same procedure is feasible for rotary-circular machines, and especially blade movement Clokwise machine, (Fig. 56,57) The machine can be realized the machine this time with a movement Clokwise of cylinder, orientation contrary to its initial position, and a movement Rotational blade. one can subsequently use the outer surface of the cylinder as a blade Clokwise of a system superior.
Let us conclude by saying that the chromatic scales already shown for the standard dynamics are also true for figurative counterparts. So, fon can place the machines in one sequence of dynamics, in rotational double at the zero point, in Clokwise of cylinder and then in planetary cylinder, and realize rotatvo-circular assemblies differential and contrario between these parties.
Semantic gaps in Wankle overcome As we have specified at the beginning of this book, Wankle rationalizes effectively retro-rotary and post-rotating machines of the prior art, when these they are made pale planetary and fixed cylinder. For these figurines, it is rather the two only mechanics that Circular rotary machines not in clokwise can be supported by the same technical processes that machines in motion clokwise. It is important here, however, specify that this will have a hybrid character, which will respect both the material aspects Virtual and Real Machine. Indeed, it is by the length of reach of crankpin or the eccentric that material figuration will remain efficient. .The mecanic chosen will include this length.
When the figures will be virtual, but linked, we will use the mechanical retrorotativity Orientation of the virtual figure. For example a figuration machine post rotary blade triangular and cylinder in two, will have a crankpin of standard length. But if this machine to a virtual form of pale square cylinder retrorotative machine triangular, the mechanics will retrorotative type.
In the case of machines with successive compressions of virtual figures, no in slinky but whose number of sides of the virtual cylinder is not related to that of the blade, we realize a induction corresponding to the virtual figure, taking into account angulation differences sides of the physical figure and those that should have a figure linked virtual. By example, a triangular blade figure rotating in a virtual figure of six sides will turn twice on her turn. So we'll give him a mechanic retrorotative using a half-size induction gear of the internal support gear.
In the case of slinky contrario machines, it will be necessary, as previously, everything keeping the length, calculate the retrorotation of the blade of such way of making jumps desired, most often performing all virtual scores on more than one tower. Therefore, in the case of even virtual figures, the actual figures will be usually in pairs, and conversely in the case of odd virtual figures, the actual figures will be peers.
Vertical and figurative planes of machines and horizontal and dynamic planes machines So we can summarize the first part of our work by saying that we have exposed for so to say the vertical plane of the machines, in other words the ways to raise the degree of spreading machines or other cylinder modification methods, such as use polycammed gears.
In this book, we show the machines can be modified in their degrees, but this time in a dynamic way. We show that the dynamics Clokwise, presented in first part has value not only by its immense qualities birotatives but also has a systematic value since it allows for a division between the machinery differential, anterior and posterior, consequently of type compressive, and machines of contrario type, whose Clokwise unit is the first representative.
So we have a vertical plane and a horizontal pan of development of machines. In the this section, we want to add that these two plans are not incompatible, one can indeed to increase figuratively the degree of a rotatvo-circular machine, as we can inversely to increase rotativo circularly a standard machine.

Wankle proposes that are lacking, always realizing, as we have shown counterforce harmful to the motor skills of the machine. At several other places, however this one seems to us to make an error by inversion or omission, semantically, which prevents it literally from systematize the plans of the machine. We think that all of these gaps here is corrected and the corrections made are part of a superior understanding machines.
We summarize these errors as follows A) with respect to planetary cylinder machines, there is an error of meaning and omission or contradiction of mechanization. Indeed, the correct meaning of these machines is complementary in the sense of their counterpart, and the mechanics must not be that of the figure, but that of the counterpart. A correct understanding of these elements allows, as we have shown, to realize the cylinder so bifunctional.
(B) In the case of rotary drum and cylinder machines, the meaning of these must to be reversed since according to the rule that we gave, Ia. next expansion being in the same place, the blade must make a hundredth twenty degrees, and the rotational cylinder must undergo a one hundred four came degrees. This reorientation of the machine makes it possible to consider it as the octave machine chromatic scales C) The rotor cylinder machine realizes a virtual figuration blade of machine square cylinder, and thereby becomes differential retzorotative, which lowers the motor skills. The understanding of this machine is incomplete, no only by the absence of a general rule, but also by the absence of a machine at Clokwise movement, and by the absence of the establishment of virtual figures and Reliable. Like the stations of Fixen, Cooley; and Ii ~ ialaird, this figure is a isolated realization, and is not systematized.
In addition, as before, there is a lack of mechanization of this figure, which would have shown this retrorotative character, and the need for semi transmission, or downward inductions.
D) knowledge of bi inductive, figurative figures, ie poly turbines, and dynamic, ie the Clokwise motion machines of blade or cylinder E) the absence of establishment or determination of mechanical levels of figuration or dynamics F) absence of mechanized accelerated-decelerate dynamics G) Lack of knowledge and use of polycammed gears, which allows the supports impossible machine figures at Wankle, such as turbines Differential, Slinky Machines, Blades and Cylinders endorsed, square and so on.
Determinations dis machines One of the qualities of the advancement of any theory, science, art or language is the increase the ability of criteria for determining the object on which or by which it is realized. one progressively moves from a world of signs to a more subtle articulated language and complex.
To preserve our main examples in the arts or science; can for example say that to analyze a sentence from the ancient melody one needed only few criteria.
This sentence was usually a psalmody with some intonation and some alternations of voice and silence, and with the limit some fretworks. From Mrs, from the point of view of harmony, the women were singing at (octave and it was thought it was the. even note.
It is otherwise to analyze a work of Bach, and subsequently of Beethoven, of Ravel or Rachmaninov. In the course of history, there has been an increase in musical processes intervening in the same musical phrase, and thus, an explanatory rendering of it requires the knowledge of these characters and their combination. The same is true of Science. The concept of weight in the. Ancient Cretia was established by the scale. In antiquity, there was little criteria for understanding a falling body. With Newton, a weight is connected to a of rational attraction. It falls not only at a certain speed, but also invariable, according to a set of criteria. With Einstein, we know that if this body is an atom, and that its speed is close to that of the lights, the rules of application of understandings to be enlarged and expanded in order to respect both these borderline cases, and to corroborate the. theory of Newton in non-cosmological spaces.
In the same way here, if we compare Wankle's work with that of inventors of art earlier, he realized that, from this level, Wankle's contribution was to bring new rational and generative criteria for understanding machines.
So indeed that for the inventors of the prior art, each machine at its figuration autonomous, and remains without mechanical modus vivandi relative to Orientational, at Wankle, we are witnessing the enunciation of rationalization criteria that are those of serialization breakages of first-degree machines, and mechanization.
It can therefore be said that Wankle finds criteria, one of figure and the other mechanics. The criterion of the figures allows a classification only in kinds of figures which we named post rotary and retrorotative.
When it comes to the criteria for orientational suspension, we see that in the order of criteria of the figures, on the one hand, namely that the proposed mechanizations are strictly retrorotative, or post-rotating, and secondly, they are limited to two, the mono post or retrorotative induction, and intermediate gear mechanics post or retrorotative.
Still relative to figures, fon can from Wankle determine logically the figurative situation of a machine of a class to that of a machine of the same class in comparing the number of sides according to the rule of sides, So we'll say that it's a machine in 3: 2, 4: 5, 7: these values corresponding to number of sides of the blades and cylinder.

From these criteria one can analyze standard machines. By example, for the case of commercial engines, it will be said that this is Engines 1) post rotary class H) of blade blades features 3: 2 I) of orientatiehmelle support method by mono post rotary induction, or reductive We can suppose, as a second example, the realization of a machine of a blade of the same number of sides but this time if cylinder in four sides. It would be so of a machine 1) Retro-active class 2) Characteristics of 4: 3 3) Orientative support method by mono induction 4) Retro rotary type support, or inversive As we have shown, it is possible to produce an almost unlimited number of machines that do not can be totally understood by the only criteria Restricted and restrictive of the prior art. We believe that a correct understanding of these machines requires set of criteria sometimes much larger.
These criteria are sufficient to include some of the machines, even first degrees Let's give some examples. If one supposes for example a machine of figuration 3: 2 but supported by hoop gear made in the form of a chain, the machine mechanics will remain unexplained, if one has for apparatus that the criteria of the art prior.
The machine will be determined as follows Pale standard cylinder 3: 2 Mechanic by hoop gear, in its chain form One can still suppose the realization of a machine with set of compression by blade units, in opposite directions, retrorotative and supported by mechanical hoop gear with third gear de-axing We will therefore determine this machine as follows at. retroactive class b. characteristic 2 X 3: 2 virtual vs. internal explosion in compression doubling d. hoop gear support e. bi rotating support Let's give another example.

In this example, a triangular type machine with a support staged, and in addition to accelerative decelerative action of the blade. The machine is therefore characterized the following way A) retrorotative class B) degree of rotativity 2 c) height d) Mono induction methods of master and hoop gear device or secondary e) curved cylinder e) mono induction by polycammed gears, accelerodereferential fj cylinder curved in forms and against forms Let's give another example. In this case, we make a machine whose Ia compressive figure comes from our generalization of Wilson's basic figure, and whose mechanical retrorotative with geometric addition is of ourselves The machine can therefore be described as follows A) birotative class B) compressive part by palic structure C) number of sides 6: 3 D) birotatural mechanics, E) by first degree mechanics by F) Modifying mechanics by and geometric addition Let's give a last example. Here we have a circular rotating machine at contrario, with blade and cylinder material three of two and Real cylinder of eight sides.
The machine is therefore type a) material rotating post class b) circular rotativo type contrario c) slinky dynamics d) of material figurations 3: 2 virtual jump of three Real 3: 8 e) mechanics by combinational connection by the support gear mechanical fj by serai transmission by cogwheels As can be seen, in addition to the mechanical structure before regularization, that is the mechanics by retrotrotation, there are no criteria belonging to the criteria of Wankle or his predecessors, and this one could not make a correct rendering of this machine.
The number of example machines being partially or totally determined by criteria not belonging to the prior art is almost unlimited.

It is almost impossible to list all the possible machines, which can be described by the systemic we see, very limited Wankle and his predecessors. The way to encompass all these possible machines is that of their determination from a support grid descriptive and rational of all the constituent characters of the machines, such Wankle has given the basis, and as we have completed them as we go works.
This grid of determination will include only generative criteria which can be applied to all machines, which will ensure to each of these criteria the generality necessary to allow consider as such.
These criteria are a) machine class, post rotary (Wankle, Beaudoin), retrorotative (Wankle, Beaudoin), birotative (Beaudoin) b) the number of counter-rotating cylinder blades (Wankle) post rotary (Wankle) Rotational Bi Beaudoin) c) first-degree mechanics used: mono induction (Wankle) intermediate gear (Wankle) hoop gear (Beaudoin) with third gears, drains, belt (Beaudoin) - by poly induction (Beaudoin) - Method by Serial Transmission (Beaudoin) - Hoop Gear Method (Beaudoin) - Intermediate Gear Method (Beaudoin) - Heel Gear Method (Beaudoin) - Internal gear method juxtaposed (Beaudoin) - Internal gearing method stacked (Beaudoin) - Central Post Gear Method (Beaudoin) - Engrenagic structure method (Beaudoin) - Unit Gear Method (Beaudoin) d) blade type: standard (Wanhle, Beaudoin, Fixera, Cooley);
in set of single blade and cylinder (Beaudoin) in palic structure (Wilson, Beaudoin, St-Hilaire) e) the type of regular dynamics (Wankle Beaudoin) fj decelerative accelerator (Beaudoin) g) the degree of the machine (Beaudoin) vertical figurative (Beaudoin) dynamic (Beaudoin) Mixed {Beaudoin) H) the type of second-degree mechanics by poly induction In double parts in tripla part (Beaudoin) with inking in the ends (Mulling) in triplicate descending inking part, by support in positioning in the centers sideways, or in intermediate parties (Beaudoin) I) the type of corrective mechanics allowing the achievement of degree obtained By coulisse (Beaudoin), by geometrical addition (Beaudoin) by oscillation (Beaudoin), by induction stage (Beaudoin) J) The type of machine type Pale planetary -cylinder fixed (Wankle, Beaudoin) Planetary Cylinder-Fixed Blade (Wankle, Beaudoin) Pale cylinder bi functional {Beaudoin) K) Standard Dynamics Type (Wankle, Beaudoin) Rotary Circular Retro Differential (Wankle) Beaudoin) or post-rotating (Beaudoin) Conversely (Beaudojn) 'clokwise movement (Beaudoin) and planetary movement (Beaudoin) L) The material degree (Wankle, Beaudoin) Virtual (Beaudoin) Real (Beaudoin) M) The type of compressive part with blade, (Wankle, Beaudoin) with pistons ( Beaudoin) N) Ä dynamic slinky (Beaudoin) O) The type of hardware figure used Figure Standard Cooley Fixen Wankle Beaudoin) Bombée {Beaudoin), rectangularized (Beaudoin) P) Counterpart figure Planetary cylinder / fixed blade (Beaudoin) Clockwise cylinder / Rotational blade (Beaudoin) Bifunctional figure (Beaudoin) COItCl (lSlOit At first glance, for many researchers, it is clear that répertoriations, rationalizations and mechanizations of Wankle offer themselves as a matter opaque, hermetic and insurmountable. The key elements are reduced to their greatest simplicity, and fon does not see that it is precisely this simplicity which, itself, is lacking.
As we frequently check, however, with time however, as for any theory and any system, we see some after the errors of appreciation, the mechanical and finally the rational contradictions and the various limitations of the company.
Gradually, as we will finish showing it here, these gaps and their corrections will make place to new perspectives, and the exceptions will gradually show their rules qualities hidden, generalizing so widespread as to result in new motor gear, much more perfect. We can therefore proceed to rationalizations allowing to understand more machine features, more machines, more mechanical, more than basic machine variant. In addition, the new units, correction concepts enable more reliable, more powerful machines, more fluids, and by Therefore, what is most important for all, machine units privileged, that we have named rotativo-circulars, realizing qualities of both piston machines, rotary machines and turbines, but without realizing the defects.
A bit like the music system or the physics system, the general theory of every motor machine did not develop in a single stroke, but rather his historiai of development, which goes from unison, octaves to fifth, seventh and so following, or a diatonic system gradually incorporating a chromatic system.
Similarly in physics, which only appeared as exceptions in the theory of Newton, turns out to be, from the point of view of cosmology, a new law.
So we can say that compared to Bach and Newton, we can say that Wankle threw the foundations of a first rationalization of rotating machines, its systematic just as much theoretical than mechanical has several gaps, mechanical and semantic.
These gaps, consistently overcome, will establish a machine system larger, and encompassing, this system having figurative dividing criteria, mechanical and dynamic superior, more malleable and varied, which, will. hatch both more types of machines complex, but also, surprisingly simpler and more effective.
The new system will not only offer more machines, but also machines achieving a better motor propensity.

10) Suggest adequate segmentation of machines

11) Suggest supports of the compressive parts by crank pins.

Brief description of the figures The figure shows the figures of the prior art, in terms of machines presses.
Figure 2 shows the set of first-degree methods, Wankle, as well as than those that we have prepared previously.
Figure 3 a) shows the main methods of degree increase mechanics that we have developed previously herein.
Figure 4 recalls, also from our first part, the three main types of bi machines inductive, namely, in a) the straight rod machine, in b) the machine poly turbine type, and in c) the blade machine in motion these / rotational cylinder.
Figure 5a shows that the. thrust in engines prior to Wankle We notice that these machines are effective, from the point of view of thrust, firstly because that their explosion come true at the top of the crankshaft rise and turnaround of the blade.
Figure 5b shows the two Wankle inductions, namely induction by mono Induction and induction by intermediate gear.
Figure 5c shows, as an example, the differences in piston engines standard, and connecting rod sliding.
Figure 6 shows the clarifications provided by the. present invention relating to induction by hoop gear.
FIG. 7 shows the precisions provided by the present invention relating to at induction by polycammed gears FIG. 8 shows the precisions provided by the present invention relating to at induction by served transmission.
Figure 9 recalls for the two figures of bases post and retro rotating, the corrections of form and torque previously brought by ourselves by addition of degrees by staging of inductions.
Figure 10 shows two types of observations leading to the realization specific induction_ Figure 11a shows the. method of observation by outside specific This method consists in observing, by an outside observer, the movement of a point specific to the blade in the course of planetary rotation thereof.

Figure 12.I presents, in a), that the understanding of the dynamics geometrical of the blade made by poly induction is totally contrary to that of art prior. In b of the same figure, we can see that, whatever the position of the centers of subsidiary crankshafts during In total evaporation, the explosive thrust on the blade remains, despite poly induction in double parts, always evenly distributed.
FIG. 13 shows the precisions provided by the present invention relating to induction by poly induction.
Figure 14 shows the. dynamic for a ride, such an arrangement. one note that here the induction have been placed in the sides of the blades, but that as we Pavons said. They could be placed anywhere on the blade.
Figure 15 in a) three dynamics of different piston engines. In (c), of the same figure, we see the staging dynamics that we produced first part of the. present invention. It shows that the blade is not mounted on an eccentric central, but rather on a staggering crankshaft whose second plays the role of rotating rod.
Figure 16.1 shows how, from a standard piston machine, a) we can produce between two dynamic compressive parts, here two pistons, actions in contrario in b, in same meaning, in c.
Figure 16.2 shows, from examples of rotor cylinder machines to pistons, how do can grasp the third fundamental deficiency of the machines of the prior art, this time dynamic..
Figure 17 is a reminder of the Clokwise dynamics of a machine rotating post figuration three-sided blade and two-sided cylinder.
Figure 18 shows by which type of observation we can see the Clokwise movement.
This observation was named, observation from the Moorish crankshaft of poly machines inductive.
Figure 20 summarizes the difficulties and mechanical weaknesses of rotary machines standard, consistent with the pre-stated deficiencies Figure 21 shows that the. Clokwise is halfway between dynamic to standard piston, rotary, orbital and turbine and rotor cylinder. It is why we named them rotary-circular machines, or rotativo turbines, or finally rotary-orbitals.
Figure 22 shows that any induction of first degree obtained by observation on the crankshaft, if it is performed in a gear ratio of support and gear of one-on-one induction, can realize Clokwise guidance of the blade by the center .
Figure 23 a) differentiates rising inductions and inductions down. The rising inductions are standard first degree inductions, or else as we have seen _ ...._._ ~ _ _._ .. _ _. _ _.__ in the induction stage the periphery induction, allowing to provide support orientation of the blade.
Figure 23b summarizes the two main types of transmission, accelerator-decelerative, and shows how to achieve them in a confused way.
Figure 24 summarizes the three main methods of machine support circular rotativo one can consider that circular rotary machines are the expression horizontalized machines with staged support structures already presented by ourselves. In B
of the same figure, the induction of the blade is achieved by a gear induction intermediate. In c of the same figure, the elements will be connected this time = by a same gear, which will serve the time dynamic support gear to the blade and gear or induction shaft at the cylinder Figure 25 specifies the contraria movements and in the same way for the motion machines Clokwise! Rotary cylinder post rotary and retro rotary.
Figure 26 states that even birotative machines, such as example polyturbines in a and b and the Quasiturbines, in c) are achievable at the machine way circular rotativo. In d), we also see that these machines are also feasible for everything number of sides. Here the rotativo-circular poly turbine to a structure six-sided palate in a triangular rotating cylinder.
Figure 27 shows that rotational-circular dynamics can also, from corrections already commented on ourselves, in particular by use polycammed gears, for standard machines, to be carried out in a accelerometers / décélératives. In these cases the curvatures of the cylinders will be changed.
Figure 28 shows that rotativo-circular machines can be made with different types of blades.
Figure 29 recalls our first dynamics on this subject and shows that the machines to Clokwise movement of blade can have various degrees, FIG. 3U shows that the polycamation of induction gears or support, can to be performed not to accelerate and decelerate the movement positions) the blade but for alternatively modify the orientational movement of the blade, making it so in Clokwise oscillatory Figure 31 shows that as for standard machines, fon can realize Ia machine with inversion of the dynamics of the compressive parts center periphery.
FIG. 32 shows that even inversely, the cylinder can, like the pale, to be in one single multi-ply piece, in a) several single-faceted pieces, in b) and in palic structure external. In c) Figure 33.1 shows the three dynamics per planetary blade! fixed cylinder, in a blade / cylinder rotational, in b, and blade in clokwise movement / rotational cylinder in c) Figure 33.2 shows that we can go further by varying the dynamics in such a way explosions and expansion in places different from those of previous figures.
Figure 30 gives other examples, this time with a blade of three sides and a cylinder of two, of the rule that we will call rotational counterpart rule.
Figure 33.3 shows for the same material figure of blade in three sides cylinder of two, as shown in a), previous differential dynamics in b, dynamic posterior differential in c.
Set of fagures relative to the rotanvo-circular or rotatrvo machihes orbital Figure 33.4 shows that another dynamic is possible, and that this dynamic allows to make a movement contrary to the cylinder and the compressive part, such we had it previously shown for rotor cylinder machines.
Figure 34 shows what will be called the counterpart rule cylindrical.
Figure 35 shows that this counterpart rule is general, and is applicable whatever the üeu new projected explosion Figure 35.4 gives a first example of a more complete dynamic allowing to do appear these figures that will be named, as opposed to the figures called material, figures virtual Figure 35.5 gives a second example of a physical and virtual figure.
Figure 35.6 summarizes the. following positions of a motion machine in Clokwise. As it can be seen, the originality of this type of machine is to describe a limit point between two areas of the chromatic range of rotating machines.
Figure 36 shows that we can inversely, decrease the number of sides of the virtual figure compared to the standard figure, which implies, to the extent that the compressions will be successive, that we will realize a differential virtual form later.
Figure 37.1 shows that therefore fon can by adding or subtracting on one side the virtual cylinder, transfer a post rotary machine, in machine retrorotative and vice versa Figure 37.2 shows that this is true for all shapes.
We have here, as for example, in a, a triangular blade machine, in b a blade machine square, in c) a blade machine in five.
Figure 37.3 shows that the achievements of synthetic figures are also true for retro rotary machines that post rotary.

Figure 38 shows that the realizations, for the same material figure, of virtual figures are not limited to the figures of a number of lower or higher sides of one.
Figure 39.I shows that in reality, one can realize, for the same figure material, all basic geometric figures as virtual figures.
Station Station 39.2 shows that this is true for all figures, and gives the example of a figure post-rotating material with square blade.
Figure 40 shows that one can realize the virtual cylinder of a machine by realization of each face thereof in a non-successive manner, by jumps.
For example, we can, for a post-type triangular blade machine rotating, realize this machine by locating each compression by hopping sides evaded Figure 40.1, gives the continuation, for a turn of all the positions of compression and expansion of pale. It is important here to make the following comments.
.
Figure 41.1 recalls the slinky dynamics for a rotor cylinder machine, this dynamic performing a jump race.
Figure 41 2 shows that, since the races of the non-successive faces are possible, the suites synthetic races, which we will also call real races, are multiples for one same virtual figure.
Figure 42. I thus widens the rule of construction of the rotativity of the cylinder enacting that we must take into account not the virtual figure, but the race virtual realization of this figure.
Figure 42.2 realizes a synthetic race, real, not successive, and of which the jumps are in such a way as to be in the contrario area of the. machine.
Here, we elect by therefore a virtual face each compression.
Figure 42, 3 shows the same real and virtual shapes, but, again once with a different synthetic race. Here the jump is two so the sequence is the next, I: l, IV
2, II: 3, V4, III5 Figure 43 summarizes the three previous figures and puts them in a way concise the race and (belonging to one area or another.
Figure 44 shows that some figures, whose number of sides is even and low enough, bring back lower figures.
Figure 45 shows various actual races of a virtual train station of seven rated for a figure post rotary material of three-sided blades. It can be found, from a seven for each f station, following the cuts.

Figure 46 shows various actual runs of a virtual figure of eight rated for a figure post rotary material of three-sided blades.
Figure 47.1 shows that the more the number of sides increases, the more the number of possible race increases, and consequently of races in contrario.
Figure 47.2 recalls that each material blade figure has its area specific and that more Ia.
pale aside, more to contrario is restricted.
Figure 48.1 summarizes the latest figures, and shows, in one figure that several figures are possible for the same hardware figure, and that several synthetic race are possible for each virtual figure.
Figure 48.2 shows, for a turn, this time, a material figure post rotary of four three sides of blade and cylinder, made on a virtual structure of ten sides.
Figure 49.1 shows, conversely, that several material figures are possible for a same virtual figure, and that each will have a contrario area preferable.
Figure 49.2 shows the chromatic scale of a machine with a hardware figure at blade of three sides, and cylinder of two. You can see the areas dü ~ erential previous, realizing when the explosion occurs before the clokwise moment of the machine.
Figure 50.1 shows the specificities of the mechanics of these machines.
Figure 50.2 shows, as with standard machines, the machines in clokwise can not only to be performed inversely, but also bi functional.
Figure 50.3 distinguishes, for all the achievements, the ranges color retro-differential differentials, differential post-rotating and contrario, for a machine that are themselves virtual.
Figure 51 shows the qualities of a virtual cylinder machine in eight and jump two, by consequently of movement in contrario.
Figure 52 summarizes the four types of mechanization possible for rotativo machines circular Either: a) by real mechanics of the virtual movement of the blade by serai-tranmittive mechanics of the rotational cylinder b) by real mechanics of the virtual movement of the blade by downward mechanical rotation of the cylïndre c) by mechanical will be transmittive of the blade by mechanical will be transmittive confused cylinder d) by mechanical will be transmittive of the, pale by mechanical downward of the rotational cylinder Figure 53 shows that each of these mechanical and served transmission can be standard, or of inductive poly type.
Figure 54 shows that we can increase the efficiency of machines differential pistons by making them with rotor cylinders or open top pistons.
Figure 55 is an example of circular rotary machine mechanization in which one employs a poly inductive transmission in a, and an induction inductive mono descendant .in B
Figure 56 shows some other combinations, among the hundreds possible.
Figure 57 shows that clokwise movement is also possible peripherally.
Figure 58 shows that the clokwiuse movement can be realized bi-functional, the outer cylinder, and the inner sub-blade being strictly rotational, and the blade in motion clokwise.
Figure 59 shows that it is possible to simplify machine segmentation by using U-shaped segments. In b of the same figure, show me how the machine with the use of a crankshaft rather than eccentric. In c of the same figure, it shows that it can realize the rotational blade of the machines to cylinder in clockwise movement by building it in the manner of a turbine blade.
Figure 60 shows three more additional mechanical combinations Figure 62 shows, in addition to the mechanical gaps already stated, the gaps order semantics overcome by our work relative to cylinder machines planetary, there is error of meaning and omission or contradiction of mechanization.
Detailed description of the figures Figure I (a) shows the main retrorotative machine figures of the prior art, including Cooley. In 1b, see the work of Wankle, Hetman, Fixen, who have mainly realized a modification of the basic forms in such a way realize the machines with segmentation this time on blades 1 as opposed to a segmentation on the cylinder 2, as in the machines of I, ari previous. In (b) same figure, one see the post rotary figures of the prior art at Wankle, they too segmented hard cylinders. In the second part of b), we see the figures of Wankle and from Fixen, in which, as in 2) these have rather arranged the hard segments the blades.
In 1 c, we see the two unique mechanics of Wankle for machines to pale planetary, namely not mono induction 3 and intermediate gear 4 In 1, d), we see the only dynamic variant for which Wankle has provided mechanical support. In e) we show the two compressive structures of prior art, after Wankle. This is Wilson's Polyturbine 5 and the Quasiturbine from St-Hilaire Figure 2 shows the set of first-degree methods, Wankle, as well as than those that we have prepared previously. In 7, find Ia method by mono Wankle induction, in 8 la. double-ended poly induction method, in 9, the. method by served transmission, in 10, the method by gear hoop, in 11, the gear method internally, in 12, the Wankle inter ~ dietary gear method, in 13, the method by internal gears juxtaposed, in 14, the gear method intermediate gear internal, in the unit gear method, at 16, the. method by gear heel, in 17, the central dynamic gear method, in 18 Ia method by structure engrenagique.
It's methods have all already been commented on by us before present.
We call them back because they will go into composition with others methods to support the compressive parts of the machines disclosed herein.
Figure 3 a) shows the main methods of degree increase mechanics that we have developed previously herein. This is the method by tiered combination of central and peripheral inductions, 19, of the gears method polycamé, 20 of the.
geometric addition method 21, of the poly induction method transmittive, 22 of the method by poly crankpins 23.
In b of the same figure, it is simply recalled that these methods have usually for result an increase in torque and an improvement in the curvature of machine figures, 24, 25.
In c of the. same figure, we recall the generalizations of sides that we produced some for the machines with palic structure, the Polyturbines. .
By these processes of increase of degrees by modification of blades, we have showed that one could increase the compression of retrorotative machines, the couple post-rotary machines We have also shown that we can realize rotary machines of various degrees, these machines, for example poly turbines, realizing new forms of cylinder more subtle and being supported increasing the number of induction.
We showed that it was possible to produce, with the use of polycammed gears, accelerated actions decelerative compressive parts, increasing by lâ. their effect oscillatory, and improving thus the stroke of the compressive parts and the shape of the cylinders being related. We have showed the rules of combination of mechanics in staging. We have generalized cylinder shapes of poly turbines. We have shown the effects of poly crankpin on rotary machines we showed that machines could be built in sets of unitary blades, blades in standard polyfaces, palic structures. We showed the dynamics perfectly CIoIzwise movement of rotating blades, and the rotational dynamics circular that this movement involved Figure 4 recalls, also from our first part, the three main types of bi machines inductive, namely, in a) the straight rod machine, in b) the machine poly turbine type, and in c) the blade machine in motion these / rotational cilinders.
Figure 5a shows that thrust in engines prior to Wankle We notice that these machines are effective, from the point of view of thrust, firstly because that their explosion come true at the top of the crankshaft rise and turnaround of the blade. 25.
Secondly, it is noted that the downward thrust on the blade 26 is with a armament of the latter to the cylinder, this armament making it possible to so to say an effect of the sink. 27 Moreover, it is precisely this armament that has been the cause of a usury premature segments, and that's why Wankle will have realized two methods of supporting pale making 1a possible segmentation on this one.
The figure S b, one shows the two inductions of Wankle, namely the induction by mono Induction and induction by intermediate gear. We will explain more abundantly, at during this disclosure the fundamental deficiencies that have contributed to the shortcomings mechanical effects of these inductions. For now let's just mention that each of them produces a high proportion of counter-attacks which are detrimental to Ia motility.
machine. In the method by mono induction, while the explosive push on front of the pale realizes a motor skills, 29, the push on the back part of the. pale produces a counter force 30, reducing the motor skills.
In intermediate gear mechanics, on the contrary, the. thrust into the meaning of rotation is performed by the back part of the. pale, 31 and thrust negative is produced on Ia front part. 32.
Figure 5c shows, as an example, the differences between piston engines standard 33, and sliding rod 34. While in the first case, one produces, in progress descent inking of the piston on the cylinder 3S, realizing what is common to call the effect of connecting rod, one notes that by using a rod-type connecting rod, one can lowers the number of component parts of the machine, and fon loses the said effect of connecting rod. In both cases may find that a first major deficiency of the two Wankle mechanics consists of what this one has, moving (anchoring the machine was losing f peripheral anchorage to (origin of the leverage effect of the explosion (explosion on the whole of the surface of the blade. .
FIG. 6 shows the clarifications provided by the present invention relating to at induction by hoop gear. In, we find the hoop gear mechanism in its shape original. An external type induction gear 36 is rigidly attached to cenire of the. blade, and a support gear, also external type 37, is rigidly connected to the body of the machine.
A hoop gear 38 is rotatably mounted to the gear support of such way of being both coupled to (induction gear.
(gear hoop, during rotation causes the retrorotation of the. blade.

... _. ~~ -...._ ... T_ .. _ _. _w .... ~

In b), we see that a third voltage gear 39 has been added, which allows both a misalignment of the attack of the hoop gear on I, induction gear, and also a plus powerful chord effect, preventing thrust before turning into retrorotation.
In c), the hoop gear is made in the form of a chain.
forward thrust on the blade is transformed again into 4I chord effect, which causes the post rotativity of the blade, surplus of the back thrust. Unlike the ~ Vankle inductions, the two outbreaks are so positive.
In d), the chain is made in the form of a belt 42 and produces the same effects. .
FIG. 7 shows the precisions provided by the present invention relating to at induction by polycammed gears As we have already commented several times, the gears polycamies 43 make it possible to produce several machines requiring acceleration and decelerations of the parts. This simply has the effect of that the realization gears, round, or themselves polycammed, with dentitions at distances variables of the teeth 44 will be able to produce the same accelero-decelerative effects.
Figure 8 shows the clarifications provided by the. present invention relating to induction by served transmission. It is simply to add that the served transmission apply to all forms of rotary machinery, including explosion machines at the top of the recovery of pale, and to all induction.
In these cases, the thrust on the active support gear 45 is in a straight line with the motor skills of the machine, and adds to it. push on the eccentric Figure 9 recalls for the two figures of bases post and retro rotating, the corrections of form and torque previously brought by ourselves by addition of degrees by landscaping inductions. It is clear that the induction stage, from a 1 to a 2, has allowed a lot better compression capacity 46. Moreover from b 1 to b 2, we see that the position of master and subsidiary crankshafts is much more favorable to a systemic deconstruction 47. The figure shows moreover in C that the application of the gears polycaxed to figurations whose segmentation is located in the corners of cylinders allows a blade softening and improved longevity of the segments. one will consult, at.
end of this presentation the proposed segmentations that we present.
Figure 10 shows two types of observations menam to the realization specific induction.
In the first type of observation, in a) that we laugh through the outside comparative the observer, positioned at (outside the machine, 49 is able to find that what defined post rotary machines is that in these the blade travels in the same meaning as the crankshaft but at a reduced speed 50, whereas what is defined is the retrorotative machine consists in that the. pale journey in the opposite direction of its crankshaft. 51 This is of that type observation that the mono induction method may have been constructed.
In b) of the. same figure, shows the observation by the vileârequirl. In this type of observation, the observation can be produced from an observer, this time positioned on the eccentric of the machine 52, will find that, that the machine is post rotary, or retrorotative, the blade always has a retrorotational action compared to that of the crankshaft 53, and that which differentiate the machines, from this point of view, is a difference of degree, in what the retrorotation of the retrorotative machine is more accentuated S4.
It is from this type of observation that all methods can be realized.
in which the induction of the blade is carried out with a view to producing a retro induction compared to that of crankshaft.
Figure 11a shows the method of observation by the specific outside This method consists in observing, by an outside observer, SS, the movement of a point specific to the blade being rotated planetary thereof. This type of observation is the base of understanding of the. method by poly induction. In a) fon can see that any point located on a line starting from the center of the blade at one of its ends S6, run a race similar to that of the blade, and slightly more obtuse. S7, moreover, if the chosen point is on the line starting from the center and connecting it to the center of one of the sides, S8, The race will be carried out similar to the first, but in the opposite direction of it S9.
Moreover, if the chosen point is located in an intermediate space at these two lines, either posteriorly 60, that is to say, 61, the forms realized by these points will she too similar to the first, but this time obliquely half way orientational ink the first, either after 62 or before 63.
In these observations, there will also be a constant between the realization of these curvatures, and this despite their specific orientations totally different. If we trace in effect a line between the lowest point of one of the figures, in y and the highest point of the other figure x, and that we follow later the course of these figures, it will be seen that Ie displacement of these points forming a line will be equidistant. All along the. realization of complementary figures. We can then realize, as shown in e), a poly two-part induction, in which secondary crankshafts 64, are rotatively mounted on a master crankshaft 6S, their crank pins being initially arranged such ways of realize these complementary forms. These subsidiary crankshafts will support the parties compressive. More details of these statements can be found in our patent Russian Machines energetics, number 200200979, May 4, 2001.
Figure 12.1 shows, in (a), that the understanding of the dynamics geometry of the blade performed by the poly induction is totally contrary to that of hart prior. Indeed, in a 1, we can see that we can express the geometric dynamics of the prior art, saying that the form of the desired cylinder is made from a circular motion fast geometric 66, made by (central eccentric, and by the peripheral embodiment, of a movement retrorotative circular, 67, made by the blade. The final form is subtractive, since the upper movement is negative, and subtracts from it. speed to movement central. This is The first fundamental deficiency of Wankle and his predecessors. In the poly induction, the dynamic realization of the projected form 69 is instead produced by a slow motion at center 70, and by a rapid and accelerated movement on the periphery 71. The form is created at from the addition of these two positive movements, hence the power of the machine.
In b of the. same figure, one sees that, whatever may be Ia. position of crankshaft centers subsidiary during their total rise, the explosive thrust on the blade remains, despite the poly induction in double parts, always distributed. Indeed, when the line formed by the two crankshafts is perpendicular to the explosion, 72, the pale is also divided, 73 of course. Of the same when these are angularly disposed, 74 the pale is still also divided, since the anterior and posterior parts are equal 75, and that the part central is well centered 76.
FIG. 13 shows the precisions provided by the present invention relating to induction by poly induction. In a) it is noticeable that poly induction can be achieved by any induction, each induction being carried out post-rotatively. In the example given in a) inductions subsidiary crankshafts are operated by gear induction hoop. 77 Dan la. poly double-part induction we pressed f idea that the stoppage of the previous induction during descent produced an armament of descent. In fon shows that one can realize the poly induction can be performed in triplicate part while retaining the downward anchorage by positioning the support points in the sides, 78 . Each crankshaft will therefore perform a vertical cylinder stroke 79.
In c, the. position of the support points is both in areas intermediaries 80 and, carried out in such a way that during (explosion, two of the crankshafts be perpendicular to the attack 81. One of the three crankshafts will be therefore still partially subtracted from neutral, the neutral point being divided between the two perpendicular crankshafts. he In addition, it should be noted that the displacement of the crankshafts will be oblique 82 and the inking will be in part a descent inking and is diagonal 83.
In d), it can be shown that the poly induction can be simultaneously double and triple part by realizing the inductions in an alternative way. In this type induction, we subtract, partially or totally some of the teeth of the support gear 84, or gearing in such a way that, except for the transition periods of effective inductions, only two inductions out of three work. Therefore, the effect of hinge around a inking point, specific to double-ended poly induction is here insured, so equally distributed for all the faces of the blade. When carrying out Ia power, inductions will be in double part, and the induction. more negative will be neutralized. This induction will be operated not by crankshafts but by its mere connection to the blade.
Figure 14 shows the dynamics for a lathe of such an arrangement. one note that here the induction were placed in the sides of the blades 85 but that as we we said it. They could be placed anywhere on the blade. It should be noted in addition that , as for all our inductions, this type of mechanic is valid for any, figure, rotary, and for all dynamics, such as planetary and rotational cylinder dynamics circular.
In this figure we note that, as we said above, gear teeth of support have been partially removed. Therefore, except in periods transients 87 only two inductions work 88. Therefore, the power is not simply derived from the rotation of the subsidiary crankshafts, but is surplus built at from the rotation of one set around the other, in partial stoppage 89.
Therefore, a mega-rotation is realized around this point of center, which one names descending, and produces a mega energy. This is what we call the Slinky movement.

The interest of this specification is to build a descent identical for each part of the blade. So we see, as a result of the figures that it occurs a relay between active and passive inductions.
Figure IS in a) three dynamics of different piston engines. In 1) we find the standard dynamics. In 2) we find the dynamics of the orbital type and in a3) the dynamics to rotor cylinder of our Canadian patent for this purpose titled Energy Machine II. In the first dynamic, we find the three constituent elements of any machine when we hear the to realize under its so-called motor form, that is, the. compressive part 90, here performed under the. form of a piston and a cylinder, the transmittive signal part 9I, here realized in the form of a connecting rod, and finally the mechanical part, made in the form of the crankshaft.
In the so-called orbital dynamics, the arrangement of several of these systems is different, since they are not on the same line, but rather on the periphery.
However each system is complete, and includes all the elements already described. 90,91,92.
In the machine rotor cylinder, however, the crankshaft is no longer active. This one has in effect was dissected, and alone its crankpin is made non-dynamically by an off-center fixed axis rigidly The side of the block. Unlike the orbital motor, the general cylinder of this machine is performed rotationally IOI around a central axis I02. Pistons and cylinders go through so different circumferences 103, which provide the expansions and cuts.
From the point of view of the constitution of the elements, we see that Ia realization of the crankshaft previous examples were made in a way confused with another element, here, the cylinder. he there was therefore a deportation of the central position of this one which results in a great loss of energy.
In c), of the. same figure, fon sees the dynamics by staging that we have produced in first part of the present invention. It shows that the blade is not climb on a eccentric central, but rather on a crankshaft stagger whose second plays the role of rotating rod.
All of these examples, in addition to the examples by poly induction jà
commented on the previous figures, lead us to point the finger at the second fundamental of Wankle and of his predecessors, which consists in having unknowingly moved the crankshaft subsidiary of the periphery towards the center, and to have realized the central crankshaft, as in the example more high mentioned, confused with a peripheral element, the blade, what constitutes the second fundamental deficiency of these machines.
Figure I6.1 shows how, from a standard piston machine, a) we can produce between two dynamic compressive parts, here two pistons, actions in contrario in b, in same meaning, in c. To realize contrario machines, one uses, coupled mounted pistons one in the other a crankshaft whose crank pins will be located in parts opposed. We will thus obtain an opposite action of the pistons one by report to the other.
Conversely, if we have the crank pins in the same dial and that with litters of different length, as shown in c, we will simply realize a differential action between the pistons.

Figure 16.2 shows, from examples of rotor cylinder machines to pistons, how do we can grasp the third fundamental deficiency of the machines of the prior art, this time dynamic. As seen in the example of a higher rotor cylinder machine mentionned, the action of the crankshaft has been completely removed. In our request for patent machine simple induction, we showed that we could revitalize this one, is retrorotativemement, post rotatively, and thus produce expansions and compressions to a rhythm greater than one per every cylinder.
In the present figure, we thus find the basic layout without dynamic of crankshaft already exposed. In b, of the same figure, it is assumed that the Crankshaft 104est reinserted in the figure, while maintaining the rotational movement of the 105 cylinder.
assumes that the crankshaft acts in reverse gear 106. We will therefore see a expansion more fast of the compressive parts, and a contrario action of the parts mechanical which will increase the power of the machine. In c), of the same figure, one suppose this cylinder to closed rooms. In addition, it is assumed that the crankshaft is trained in the same meaning as that of the cylinder, and moreover, but at accelerated speed 107, which will produce also expansions and compressions. We will see when the crankshaft act faster and joined the next expansion 108, as in the rotary engine it joined the next face 109.
On the contrary, it should be noted that, to be on the contrary, this dynamic is not that differential, since the force on the crankshaft is therefore built in support on a piece from of a room. This is very clearly the third gap in Wankle, the third gap fundamental, which consists in having carried out an action simply differential between the Crankshaft and Ia. blade. As we have already shown, the dynamics birotatives, by Induction and poly induction staging do not realize these shortcomings.
In the next figures, we will show that the birotative dynamics by compressive part in movement Clokwise also realizes machines without these three fundamental flaws.
Figure 17 is a reminder of the Clokwise 110 dynamics of a machine post figuration rotary blade with three sides and cylinder of two. In this dynamic we suppose a very specific blade movement in that its orientational aspect remains unchanged, observed from the outside during the rotation of its center, and that by Therefore, as for clockwise, despite the movement of the hands, (orientation of the figures do not change not. That's why we named this movement of Clokwise's pale movement.
In a machine, if we realize a blade with this type of movement, we will have to realize the rotationally cylinder 112, and in the more specific case of post rotary machines, contrary to the circular movement of the center of the blade.
Figure 1b shows by what type of observation we can see the Clokwise movement.
This observation was named, observation from the master crankshaft of poly machines inductive. This type of observation was obviously not possible inventors of art prior. In this type of observation, it supposes an observer the crankshaft master 113 of a poly induction machine. This crankshaft both its frame of stability, this one will find the following. First he will observe the movement in Clokwise of blades he observe, and that each part of it realizes a movement strictly circular, and not rotaxionnel.I l4. In the second place, when he observes the cylinder, it does not will be more for him, as for a fixed outside observer, but rather in motion, and read precisely in reverse movement to that of pale115's Clokwise movement We can still realize, mechanically and consfiructively the movement Clokwise rotaivo-cicular gripping in a vise I 15 Ie the crankshaft-master of a machine inductive poly and in activating the rest of the. machine. So, indeed, if we run (together, we will see Subsidiary crankshafts can still be activated and by therefore produce the Clokwise movement of blade, 116, and that (support gear;
not dynamic s, activate, bringing with it the reversion of the cylinder. 117. It is can therefore by this stratagem observe from (outside a perfect rotativo-circular machine of blade type Clokwise.
Figure I9 (b) shows, after deduction of the previous experiment, the mechanics basis for concretely realize the support of the machine in CLokwise. It's about a poly induction for so to say dynamically inverted. It is simply installed rotatively two crankshafts subsidiary 118 having support and induction gears combined 119 in the side of the Machine. The blade 119 is installed on the crankpin of these crankshafts. one then goes up rotatively in the machine an axis of the machine 120 to which we will fix the link gear collecting the crankshaft gear 121, and the cylinder 122. The movement Clokwise of pale will therefore entail the. rearrangement of the central gear and by way of consequence of the cylinder.
Figure 20 summarizes the difficulties and mechanical weaknesses of rotary machines standard, consistent with the deficiencies set out in (a), and shows that all these difficulties and gaps are overcome in the provision Clokwas.
The theoretical gaps mentioned above result in fact in very real difficulties the main ones of which are the following a) a negative counterforce on the. rear part of the blade being downhill 123 b) an unequal speed of systemic deconstruction I24 c) an overloading of the crankshaft, a third of a turn of blade, requiring a lap complete of it I25 d) increased friction derotation of the blade on its crankshaft, 126 caused by the use of an eccentric In summary, therefore, the blade only works positively on a part of its length, and this work remains unequally distributed. In addition, this work does a job whose resulting strength is diminished by the speed of the crankshaft and the great friction.
The machine is inefficient. In dynamics with pale in clockwise Icylindre rotational, All these Gaps are cut off and replaced by qualities.
The vn note a) a power over the entire length of the blade 127 (b) a descending rate of descent equal in all respects 128 (c) a noticeable decrease in crankshaft override: a number of three explosions by crankshaft revolution as opposed to two 129 d) a rod effect found by the turbine thrust on the cylinder 130 e) a systemic decontrol on the contrary between the cylinder and the blade 131 fj the absence of any acceleration and deceleration of any part 132 (g) the rotational cylinder may be equipped with a blade and cooling and realize the dynamic lights valves of the machine.
Figure 21 shows that the Clokwise dynamic lies halfway between dynamic to standard piston, rotary, orbital and turbine and rotor cylinder. It is why we named them rotary-circular machines, or rotativo turbines, or finally rotary-orbitals.
First of all, it should be noted that circular rotativo motors with a blade in Clokwise have a push frank and even on the blade, not only similar but even equal to that engines to pistons 133. Then, it must be said that these machines derive their figuration geometric rotary machines of the prior art 134. It must then be added that these machines, unless they are deliberately produced with polycammed gears, have, like the turbines, none acceleration or deceleration of both mechanical and compressive parts, 136 . Then, as in contra-piston piston cylinder machines, the combination induction has been made Ie crankshaft horizontally, which implies that the crankshaft was not placed in periphery, but centrally but also that the parts are contrario, 137 . Finally, the down the piston is quite vertical and peripheral, and reminds that orbital motors in only one blade 138.
It is almost true to say that this new machine possesses qualities of all these machines gathered without possessing the defects.
Figure 22 shows that any induction of first degree obtained by observation on Ie crankshaft, if it is performed in a gear ratio of support and gear of one-on-one induction, can realize Clokwise guidance of the blade by the center . In 1, has 2, a 3, we find respectively induction of first of ge by gearing intermediate, by gear hoop, by gear heel, all mounted with reports gear one on one. This gear ratio shows, in addition to the action perfectly equal on each part of the blade, the birotative aspect of blade machines Clokwise, an aspect that can be found in other figurative forms only in the poly turbines, and in straight link engines.
In 22 b, it is shown that mono induction, or inductions by poly inductions must, as any induction of which one would not have changed the ratio of the gears, be carried bags their form will be transmittive 139, in such a way as to cut off their propensity either retrorotative, post rotational ..
Figure 23 a) differentiates rising inductions and inductions down. The rising inductions are standard first degree inductions, or else as we have seen in the induction stage the periphery induction, allowing to provide support Orientation of the blade. As we can see here, in I40, we have a rising induction of type mano induction. We define an induction as a descendant as far as it goes opposite of an element in periphery to activate a lower element or central. In these cases, it is the upper gear, usually of the blade that becomes the gear support Induction 141, which is that lower gear, most often of Tax central is the gear induction 142 of this axis and elements, commonly the cylinder which are attached. In the present figure, for the sake of simplification, the downward induction is also a mono induction induction, but it could be a poly induction, an induction by gear hoop or other inductïon.
Figure 23b (1) summarizes the two main types of transmission, decelerative-accelerometers, and in b 2 shows how to realize them in a confused way.
One can realize the acceleration or the deceleration of pieces by serai transmission made with using an internal and external gear 143, or by the coupling of two gears to one double gear 144 of different sizes. By the way, we can perform the inversion either by gear gears 145, or by external gear combination 146.
As these two mechanical actions will frequently be necessary in the rotary machines Circulars, it will be advantageous to carry out these reverse transmission accelerative way confused, as in bl, or in b2.
Figure 24 summarizes the three main methods of machine support circular rotativo year can consider that circular rotary machines are the expression horizontalized machines with staged support structures already presented by ourselves. By therefore one will always need, for the realization, two inductions in combination, which very often of type will be transmittive. So we define the transmission as inductions turned on themselves, from center to center. We will understand, waited number of induction of first degree we have foun ~ i, and the induction number will be transmittives, that Possible permutations are vast and can not be presented here. It is Why us we will give the generative rules of combination of these inductions.
The logic of these rules is the following. It will be understood that one of the inductions will control the rotation of the cylinder and the other the Clokwise or planetary motion of the pale, and that by therefore these two induction must be perfectly synchronized. They must therefore communicate by a third party. will allow coordination. The methods of supports rising, descending or by transmission will be possible by a party common, either by the blade, the crankshaft, the support gear. In the part a) of this figure, l, we thus find an example of the first type of combination. By a side, the blade is supported by a hoop gear method, report one on one in ensuring movement Clokwise. Moreover, on its second side, it is equipped with an induction downward assuring the rotation of the cylinder axis. The two systems are therefore combined by the blade.
In b of the same figure, induction of the blade is achieved by induction.
in gear intermediate. It communicates with the crankshaft, moreover, from this same element, a transmission link will be connected which will activate the cylinder. Blade and cylinder will therefore converge because coupled with the same element that is Ie crankshaft.
, .....,,, .. ",, .n-, vv ~ rm ...,.: -... ~ w,.. ~" ~, rP .., ~, .. y - _ ~
, az ° z ~, ._-.-, ". w, -e- ~? ~". ~ es ~ ay., s, ~~;,. ......
., Y ~ wscca e .- ~ my ~, ~ a: ~ unu: ~ "oo ~ .aa .. ~, .., .........."... ~ ".. __._.__.-._ ~ _ _..__..__._.._-In c of the same figure, the elements will this time = connected by a same gear, which be used for. both dynamic support gear to the. blade and gear or induction axis at cylinder. Indeed, we can see that the blade is activated by a mechanical semi transmittive, and that its support gear is dynamic. Moreover, if we realize the retrorotation of cylinder, from the crankshaft, one can use a semi Inverse transmission, realized in a totally confused way with the first, which allows us to say that the gear cylinder is an inductance gear, is the same gear as the dynamic gear of blade.
We now understand better the interest of the assembly by poly induction presented to our first figures of assembly. In this realization the rising induction of pale is exactly here.
same, in the opposite sense that (semi-transnational and inverse induction of cylinder, which makes the number of rooms very small. At the very end of this exposed, other examples all of which respect the same associative idea of funds, namely that the parties inductive are necessarily linked by one or other of the components mechanical machine, blade, crankshaft or support gear.
Figure 25 shows the contrario movements and in the same way for the motion machines Clokwise / rotational cylinder post rotary and retro retentive. Similarly it shows that Clokwise blade movement machines are achievable for any figure of machine In a) tone to the machine of post rotary figation of blade in three sides, cylinder in two.
In b) we find the triangular retrorotative machine. It is noted that in the case of machines retrorotative, the cylinder remains rotational, but works on the same side that the movement Clokwise of pale.
Figure c) shows a clokwise movement of four-sided blades and rotational contrario of cylinder in three Figure d) shows a machine with Clokwise blade of trais quoted, but this times in cylinder of four, therefore retrorotative figuration. Cylinder and blade so work in the same meaning.
In e) ton sees a rotary post figure with Clokwise blade of five sides, and a cylinder in contrario movement of four sides.
In f), a retro-active figure with movements in the same direction, of Clokwise's pale four sides, cylinder of five.
Figure 26 states that even birotative type machines, such as example polyturbines at a and b and Quasiturbines at c) can be realized at.
machine way circular rotativo_ In d), you also see that these machines are also feasible for everything number of sides. Here the poly rotatvo-circular turbine to a structure six-sided pie in a triangular rotating cylinder.
~ O

Moreover, if we observe the sequences present in a) and b), we note that , as for standard machines, various levels of rotativity can intervene for a same machine. In the palic structure is not rotational, it simply carries out its losango aspect squareoid alternately, and is completed by rotation of the cylinder.
In b, we note the two crankshafts supporting the palic structure are strictly rotational, which forces the realization of the alternative passage losango-square of the. pale structure to to be realized through a certain rotation, not planetary however. This rotation is completed by the rotation of the cylinder.
Figure 27 shows that rotational-circular dynamics can also, from corrections already commented on ourselves, in particular by use polycammed gears, for standard machines, to be carried out in a accelerometers / décélératives. In these cases the curvatures of the cylinders will be modified ed.
Figure 28 shows that rotativo-circular machines can be made with different types of blades. In a), we find the standard blade figures.
In b) the compressive structure consists of unitary blades with movement Clokwise acting in combination with the cylinder to form compression between them same and outside or between themselves and the cylinder in the center of the machine. In the latter case, the compression realized by this set will be double the normal compressions and the machine can by consequently calibrate a stewardship of diesel gases.
In (c), it is simply a reminder that the compression structure can also be structured palic, as shown in the previous figure.
Figure 29 recalls our first dynamics on this subject and shows that the machines to Ciokwise movement of blade can have various degrees, In a) the blade without orientational action, and therefore has a movement clokwise, the action positional thereof being circular. In b) the blade has an action Clokwise and positional rectilinear, In c) it has a Clokwise directional action and quasi positional triangular .. Finally in d) its orientational action remains Clokwise, but his action positional, since the crankshaft is more elongated, is coupled not to an action of the cylinder simply rotational, but to an action of the planetary cylinder.
All these machines are therefore the same machine generation, sometimes increased degree by the rectilignization or a geometrization here, by triangularization of the race the position of the blade, that in B and C, sometimes by an increase in degree of the cylinder.
All of these dynamics of different degrees, shows that the rotativo machines Circulars form a category of machines with characteristics generatives that are own. In all these cases of machines, the master crankshaft is confused with cylinder.
In the. figure 30, it is shown that the polycamation of the induction gears or support, can be achieved not to accelerate and decelerate the movement position) of the blade, but to modify alternatively the orientational movement of the blade, the thus making Oscillatory clokwise. This is possible by a gear relationship of support and induction always in a report of one on one but, this time, of nature polycarnée.
In addition, in this figure, it is shown that one can by set of blades unitary realize the compression of machines with odd cylinders. Here, while fane blades is compression, (other will be in depression, we will also notice the action counter oscillatory blades.
Figure 31 shows that as with standard machines, it can be realized machine with inversion of the dynamics of the compressive parts center periphery. In Therefore, here it will be the cylinder will be in Clokwise motion and the blade in rotational motion. he It should be noted that, as we will show more abundantly at the end of the present invention, the orientation of parties will be complementary and that the mechanics will be that of the counterpart hardware A second consequence of this inversion will be that the figures post rotary thus produced, in addition to, requiring retrorotative mechanics, will realize dynamic in the same sense, whereas the retrorotative figures, as shown in b, will realize dynamics on the contrary.
Figure 32 shows that even inverted, the cylinder can, as the.
pale, to be in one single multi-piece piece, in a) several single-faceted pieces, in b) and in palic structure external. In c) Figure 33.1 shows the three dynamics per planetary blade / fixed cylinder, in a blade / cylinder rotational, in b, and blade in clokwise movement / rotational cylinder in c) Figure 33.2 shows that we can go further by varying the dynamics in such a way to make explosions and expansion in places different from those of previous figures.
In a) a standard blade dynamics in two cylinder sides in one.
In b), the blade of this machine does not realize a movement Clokwise. Here the explosion is done in three different places, bl, b2, b3 and not to one as in Ia standard dynamics.
Conversely, in b) the figure shows that we can assume, for the same type of figure, a retro-rotational movement more of the blade than in b, but faster that a) a rotational post movement of the cylinder to fill this alteration.
The explosion is will here therefore in cl and c 3 Finally, in (c) we assume the fixed cylinder mechanics, or the force achieved is neutral Figure 30 gives other examples, this time with a blade of three sides and a cylinder of two, of the rule that we will call rotational counterpart rule.
Figure 33.3 shows for the same material figure of blade in three sides cylinder of two, as shown in a), previous differential dynamics in b, dynamic posterior differential in c. In a, the moment of explosion is in a 1 In b explosions successive are in bl, b2, b3, b4, and in c, cl, c2,, c3, c4. will note in b, as in c, that the g ~

cylinder moves in the same direction as the blade, one retrorotatively, and the other post rotatively, and that's why we'll say these type dynamics compressive. It is why we say that the. machine only produces a differential force between these parts.
However, as the place of the next compression will be exceeded that of the next standard compression, we say that this machine is differential later.
Set of figures relating to rotativo-circular or rotary machines orbitals.
Figure 33.4 shows that another dynamic is possible, and that this dynamic allows to perform a contrario movement of the cylinder and the. compressive part, as we were previously shown for rotor cylinder machines. Each figure corresponds to the sequence of successive compressions of the machine. It will be noted in fact in this figure a movement planetary plane of the blade and a retrorotational movement of the cylinder, and that by Consequently, these two parties are making a move which will be Engine, or contrario.
Figure 34 shows what will be called the counterpart rule cylindrical. This rule shows how all these mechanics of different appearance are understandable to from a same logic. This rule can be stated as follows: for any machine d, a number of sides given, it exists, when it is standard, planetary and cylinder fixed, a number of degrees of rotation of the eccentric for each place of new expansion.
Any decrease in this number of degrees will have to be offset by counterpart by a rotation or a rotation of the cylinder. In other words, the cylinder will he likewise to find himself, with respect to the blade in a position identical to that which he would have had without these alterations.
Let's give an example. It is known that the explosion in a standard machine of three-sided blade e1:
cylinder two will take place after one hundred eighty degrees of filming the crankshaft. But if we determines that the next explosion will have a link at only 120 degrees, we will have to calculate the difference of the angles corresponding to the standard explosion, and that of the new explosion projected. We arrive here at sixty degrees of months. So we will have to make a regularization mechanical and print the cylinder a sixty degree backward rotation. If fon to realize the Following the explosion, we arrive at the movement clokwise.
Figure 35 shows that this counterpart rule is general, and is applicable whatever the place of new projected explosion. For example in a) the place of new projected explosion is at one hundred degrees, eighty degrees below the standard place. The mechanical regulation It will therefore be necessary to print a cylinder with a retrorotation of eighty degrees.
In (b) the projected area of new compression is 270 degrees, ie four twenty ten degrees of more than the standard place. The regularization rule will therefore dynamic correction of the cylinder by printing a post rotation of ninety degrees.
Figure 35.4 gives a first example of a more complete dynamic allowing to do appear these figures that will be named, as opposed to the figures of material, figures virtual. In the first case, the. actual figure is post rotary type to pale on both sides, the whole turning and realizing a virtual figure retrorotative to triangular cylinder.
~ l As we have shown in the previous figures, it is possible to realize the place of new compression at any new angle, and of the cornger by a cylindrical regularization.
However, since this is a motor machine, it is important to specify for these new machines, types of mechanics that will be used to support blades, and cylinders, as well as the locations of the mouths of entrances and exits gases, same as fixing candles or other accessories. To do this, it is therefore of relevance observe the behavior of the blade, regardless of cylinder.
In doing so, it will be seen that the attribution of a new explosion linker will force necessarily a dynamic representation of the blade different from its material figuration. This new figuration, for the reasons we have previously given can be established in such a way that it can be performed in one, two or three turns.
It will therefore be found that in determining the place of the next explosion of such so that new projected angle can be a fairly simple fraction of three hundred sixty degrees, by example of one in three, one in four, in five, six, fon will allow the blade to make a figure virtual equivalent to one of the basic figures of rotating machines.
In (example here given, we project an explosion every hundred years degrees. And to realize therefore the. pale in such a way that it achieves this figure virtual, here triangular, everything by realizing the dynamic regularization of the cylinder.
We must therefore distinguish the material figures from the figures virtual. In this example, as we have said, the blade and the material cylinder, realize a past-type figure rotary blade on both sides, cylinder on one side, as shown in a). In B, we see that the figure virtual that the blade will realize will be that of a triangular motor. moult exactly the same mechanical that this retrorotative figure indeed, the blade will move from identical way.
To compensate for this planetary rotation figure of the blade, we will activate the material cylinder by adjusting each angle and at each moment according to the procedure set out in previous figure.
The cylinder will therefore turn by two thirds of turns for each third of a turn.
blade. This procedure allows to realize the machine with a retrorotative mechanics, and simultaneously with a real post-ratative figuration, whose compression will be better.
As can be seen, blade and cylinder rotate in the same direction, this who makes the simply differential machine, here later.
Figure 35.5 gives a second example of a hardware and virtual figure. one must realize the machine with a specification of the virtual figure, since, as it is will see, on the one hand, the mechanics will be that of the virtual figure, and on the other hand, the position of candles and starters and outputs of the machine will also be realized respecting the virtual figure.
In this example, the material figure will be that of a post rotary machine with triangular blade and double cylinder arc, as shown in a) However, as shown in b) la. figure virtual will be that of a retrorotative machine.

As we (have already mentioned, if we heard the thing from the point of view mechanical, one could instead say that the material figure is the second, since the mechanical to support the blade will necessarily be that of the figure Virtual. As previously, if one adjusts to each phase of its unwinding the cylinder with angulation corrected, it will get a rotational cylinder, which will allow the conjunction real figures and virtual, which will be called the synthetic race. A material figure of post rotary machine of triangular blade with double-arc cylinder will be performed simultaneously with the virtual form of a triangular retrorotative machine. As in the first case, this figure lie in the area of previous differential machines.
Figure 35.6 shows the rest of the positions of a motion machine in Cloïcwise. As it can be seen, the originality of this type of machine is to describe a limit point between two areas of the chromatic range of rotating machines. At this point, we finds the peculiarity next that the number of blade sides is identical to that of the cylinder virtual. Explosions or compressions are indeed, for example here, on each side of a virtual triangle for a virtual blade. We see for each figure in a and b, that the number of sides real of the pale is equal to the number of sides of the virtual cylinder, which constitutes originality of the machine, this one not being realizable strictly.
Figure 36 shows that we can inversely, decrease the number of sides of the virtual figure compared to the standard figure, which implies, to the extent that the compressions will be successive, that we will realize a differential virtual form later. Here, therefore, a post rotary real shape machine with triangular blade is produced and double cylinder arcs, so as to virtually realize a post rotary machine of a only side. This realization allows, for all practical purposes to subtract the crankshaft, do not realizing the parts compressive than strictly rotating.
Figure 37.1 shows that therefore it is possible to add or subtracting on one side the virtual cylinder, transfer a machine post rotary, in machine retrorotative and vice versa. Right here, the same post rotary triangular blade machine can become a machine post rotary synthetic cylinder on one side, or synthetic retrorotative, to virtual cylinder of four sides.
Figure 37.2 shows that this is true for all shapes.
We have here, as for example, in a, a triangular blade machine, in b a blade machine square, in c) a blade machine in five.
Figure 37.3 shows that the achievements of synthetic figures are also true for retro rotary machines that post rotary. In a) we can see a post rotary machine realize a retrorotative form of virtual cylinder, while in b, we see a machine material retrorotative, realize a rotating post cylinder shape Virtual.
Figure 38 shows that the realizations, for the same material figure, of virtual figures are not limited to the figures of a number of lower or higher sides of one. Here, we performs, for example, a rotary post machine of triangular blade with a virtual form of cylinder of five sides.

In the column of (a) we can see the list of explosions, and one may find that the pale is compatible simultaneously with the real form and the virtual form of the cylinder. In the column of b, one can see the various moments of passage, in which the blade tips passes simultaneously in the spikes of the real and virtual cylinders. Here, the retrorotation of the blade is accelerated, which produces a rotation of it in the same direction as the cylinder, and for that. the machine is located in the area of differential machines earlier.
Figure 39.1 shows that in reality, one can realize, for the same figure material, all basic geometric figures as virtual figures. For example, here, for a post machine rotary triangular blade, we can achieve, as we already have shown, a figure with a smaller number of sides, that is to say posterior differential, or with a bigger number of sides, ie triangular, square, hexagonal and so on.
Figure 39.2 shows that this is true for all figures, and gives the example of a figure Rotary post material with square blade.
Figure 40 shows that one can realize the virtual cylinder of a machine by realization of each face thereof in a non-successive manner, by jumps.
For example, we can, for a post-type triangular blade machine rotating, realize this machine by locating each compression by hopping sides evaded. In the this example, the dynamics of the blade are organized in such a way that it not only make a figure virtual in eight sides, but moreover it does not make it pale by faces successive, corn rather by jumping two sides evaded at a time. The blade will therefore realize here approximation of his figure through the following sequence of faces: I, IV, VII, II, V, VIII, III VI.
Figure 40.1, gives the continuation, for a turn of all the positions of compression and expansion of pale. It is important here to make the following commentaries.
The first is to mention that the realization of this virtual figure allows several explosions per turn, which will normally be feasible only by an eight-sided figure, and who by therefore would not give only small explosions. The second is to say that in doing so, one manages to place each successive compression in the contrario zone. Indeed, if we observe the unfolding of the sequence of the blade and the cylinder, we note that they work in sense opposite, which ensures the machine, by a contrario force, an important motive power. A
third observation is to note that the movement of each of the compressions and expansion is alternative, and is comparable to the movement in Skliny, or to a movement in mufti Clokwise successively, movements already commented by ourselves for the machines piston, and which finds here its realization for the rotary machines. This movement assimilable to a movement in successive Clokwise allows more expansion towards the center than in the standard rotary machines, of which f expansion pivots around center before realize it.
The expansion, here, in addition, will not take quarter-turn holes, as in the rotary machine, but only a quarter turn. The machine can easily be realizes type four 3rd time by choosing the even sequences for the explosions and the sequences odd for evacuation and admission or vice versa.
Figure 41.1 recalls the slinky dynamics for a rotor cylinder machine, this dynamic performing a jump race.

Figure 41 2 shows that, since the races of the non-successive faces are possible, the suites synthetic races, which we will also call real races, are multiples for one same virtual figure. For example, ci, we show that various race virtual of the blade allow to realize a virtual figure of five sides for a figure post rotary material three-sided blade.
In the following figures, we will show that according to the synthetic race chosen for same real and virtual figures, we make strong machines different, since some of them will be in the area of differential machines previous, others in the area contrario machines, and others in the area of differential machines posterior.
Figure 42.1 thus expands the rule of construction of the rotativity of the cylinder enacting that we must take into account not the virtual figure, but the race virtual realization of this figure. As soon as the difference in degree of the first compressions clear material and virtual, and the angle thereof, will be applied to the cylinder.
In the example of this figure, the virtual figure of five sides is carried out so successively, which forces the displacement of the blade and the cylinder into the same sense, and realizes an earlier differential machine.
Figure 42.2 realizes a synthetic race, real, not successive, and of which the jumps are realized in such a way as to be in the contrario area of the machine.
Here, we elect by therefore a virtual face each compression. As shown in b, the machine follows the sequence, I: 1, III: 2, V: 3 II: P 4, IV: 5 We must therefore characterize the machine according to its criteria of real form, virtual form, and synthetic sequence. We can say that this machine is P type 3/2; 5 ; 1: contrario, this which will agree to mean that the machine is a rotating post of three listed on two, of virtual cylinder of 5 sides, and jump from one side evaded. We can even specify contrario ..
Figure 42, 3 shows the same real and virtual shapes, but, still once with a different synthetic race. Here the jump is two so the sequence is the, following, I: 1, IV
2, II: 3, V4, III5 As we can see, it is not so much the virtual form that will come define the area of machine, but the synthetic race on this form. Here, the race synthetic makes the first explosion located in a zone in deca of the explosion point when of realization standard, and prior to the zero point, the machine is therefore differential posterior, and as we can to note it, since the cylinder and the blade act post rotatively in the same meaning, the power is reduced, since there is a mechanical contradiction with Ie one way that must to have an explosion.
Figure 43 summarizes the three previous figures and puts them in a way concise the race synthetic and the belonging of an achievement to one area or another. .
In has one has a successive race, whose first compression is in the differential area earlier, gs In b, the synthetic race realizes a chromatic machine said to contrario, and will be Motor category.
In c, the. machine performs a synthetic race including the first compression is in the area posterior differential. The machine will be compressive.
Figure 44 shows that some figures, whose number of sides is even and low enough, bring back lower figures. For example here, the. virtual figure in six sides, allows a sequence of successive faces in a) In b, however the sequence with a jump, makes us fall back on the Clokwise dynamic, while the sequence with two jumps in c), makes us fall back on the standard dynamics.
Figure 45 shows various actual runs of a virtual figure of seven rated for a figure post rotary material of three-sided blades. It can be found, from a seven for each figure, following the compressions. As before, the first races synthetic will give rise to earlier differential machines, the sequence with two sides evaded will give rise to a machine of contrario type, and the other sequences, of machinery posterior differential.
Figure 46 shows various actual runs of a virtual figure of eight rated for a figure post rotary material of three-sided blades. As in the figure previous, fon can distinguish synthetic races that will give rise to machines differential, earlier, or later, or contrario machines, the latter producing the motor effect.
Figure 47.1 shows that the more the number of sides increases, the more the number of possible race increases, and consequently of races in contrario.
Here the. virtual figure of fourteen to fourteen sides for a real figure rotary post from blade to three sides.
Figure 47.2 recalls that each material blade figure has its area specific and that the more the the more the contrario area is restricted.
Figure 48.1 summarizes the latest figures, and shows, in one figure that several figures are possible for the same hardware figure, and that several synthetic race are possible for each virtual figure.
Figure 48.2 shows, for a turn, this time, a material figure post rotary of four three sides of blade and cylinder, made on a virtual structure of ten sides. The race synthetic by jumps of three faces makes it possible to realize the. first compression and explosion, and following, in a contrario part of a machine. As we can to see one realizes 10 compressions for each half turn of the blade, and third of the turn of the cylinder, by therefore, if the.
machine is performed in four times, ten explosions per turn of blade, which corresponds to a V-piston engine of twenty pistons, nearly three txfns old V
8, or two good old V 12.
Figure 49.1 shows, conversely, that several material figures are possible for a same virtual figure, and that each will have a contrario area preferable.

Figure 49.2 shows the chromatic scale of a machine with a hardware figure at blade of three sides, and cylinder of two. You can see the areas dü ~ erential previous, realizing when the explosion occurs before the clokwise moment of the machine. One can see the areas so-called posterior differential, realizing when the moment of explosion is later than standard explosion time. Lastly, we can see the areas to contrario, realizing when the place of first explosions is realized between the places clokwise and standard.
Figure 50.1 shows the specificities of the mechanics of these machines. one can usually say that these machines can be activated by mechanics similar to mechanical Circular rotary machines with clokwise movement, and taking into account however to realize the movement of the blade so that it produces movement at a time the actual figurations and hardware, if the machine is produced in Slinky and virtual and hardware if it produces the successive compressions.
In both cases, we will realize the crank pins worn machines of such way that their length is equivalent to that of the material figures, when realized as a standard, and also in such a way that they realize the filming and retrorotation of the figures virtual or real depending on the case.
For example, in the case of mechanization of Figure 42.2 and Figure 33.4, will realize the machine with the same crankpin lengths as the rotational material figure of pale three side and cylinder of two.
Moreover, we will realize the orientational mechanics of figure 42.2 with the help of a retro-mechanical mechanism, imitating that of a five-sided cylinder machine, increases by number of additional degrees to be filled by the triangular shape and not square of the. blade.
In both cases, it should be noted that by doing so the poly is greatly improved.
induction, and increasing the scope of it, which has the effect of making even positive the back part of the movement of the blade, which will not remain thus in simple blockage, but will act dynamically.
Figure 50.2 shows, as with standard machines, the machines in clokwise can not only to be performed inversely, but also bi functional.
Figure 50.3 distinguishes, for all the achievements, the ranges color retro-differential differentials, differential post-rotating and contrario, for a machine that are themselves virtual. This chromatic scale consists of the main points following, ie rotating cylinder and blade machines, cylinder in Clokwise, planetary rotor cylinder machines. Interphases between these pooins constituted the parties differential, contrario, or differential later of these machines.
These findings constitute a definite advance in the knowledge of these machines, which earlier consisted of only two polar possibilities, the octave point, and the standard point, that we will say the fifth point. The addition of the clokwise point, which we will say third point, allows no only to constitute the areas of these machines, but also to realize a progression rational between them, as in the range of colors, the range musical diatonic, or in other ranges. The parties do not understand each other any more successive, discretionary and g7 .M ..? ., n ~, ~ ..,., wa K.-e .. .z, ~, "_,,.,. ~. ~ m ~ .-- ~ .. ~ ~. ~~" w Y ~~, e_ ~~ 5 _- .. ~~ ~~ m -.. .. ~ .. ~ ~~ .... ...- ~ w ~ .._ isolated, but rationally, by their relations to the same fundamental, the zero point. Of more, at the point of dynamic vt ~ e, the realization of a machine according to its race synthetic, therefore, not only simultaneously virtual and real, but moreover, by jumps, allows you to draw ranges of melodic relationships that give the machine its living, a more dynamic deep, less mechanical and more real, rationally speaking, and in the Hegelian meaning or Cartesian of the term. In these cases, mechanical logic resembles the arts, since it allows make connections of understanding from material data, which finally are more real that same data.
Figure 51 shows the qualities of a virtual cylinder machine in eight and jump two, pax consequently of movement in contrario. As we can see here, the parties work at contrario. Secondly, as in the Clokwise movement machines, the connecting rod effect is achieved by the rotation of the cylinder. Third, as we can note in c, the end of the expansion is quite vertical compared to (expansion of a machine standard, which better respects the amorphous explosion.
Figure 52 summarizes the four types of mechanization possible for rotativo machines circular, either in a) by actual mechanics of the virtual movement of the blade by mechanical servo-tranmittive rotational cylinder, in b) by mechanical real virtual movement of the blade by mechanical downward rotation of the cylinder, in c) by mechanical transmittedactive mechanism of the blade by mechanical served transmittive confused of cylinder, in d) by mechanic transmittedactive transmission of the blade by mechanical descendant of the rotational cylinder Figure 53 shows that each of these mechanical and served transmission can be standard, or of inductive poly type.
Figure 54 shows that we can increase the e ~ cience machines differential pistons by making them with rotor cylinders or perforated upper pistons. Of the same way one can open the rotational cylinder to the fixed outer cylinder. Of this manate the.
compression is done from three parts, and the power on the blade is from Then performed in bearing on the outer cylinder which subtracts the contradictory effect of the push strictly differential.
Figure 55 is an example of circular rotary machine mechanization in which one uses a poly inductive transmission in a, and an induction inductive mono descendant .in B
Figure 56 shows some other combinations, among the hundreds possible.
It is therefore important to note that these induction assemblies are copies. all induction of these may be replaced by any other induction, according to the case, standard, will be transmittive, rising or descending. In al, we have a used transmission inductive poly commander Ia retrorotation of the cylinder, performed in a way confused with a poly induction fixed bl, commander I, action clokwise of the blade.
In a 2, we have a poly inductive action of the blade, and in b 2.1 an action mono descendant inductive cylinder In b2.2, the action controlling the cylinder is served transmittive with gears.
gg ...___ __, ~ _.__ .., .., ~, ....> .., ","".., ~~ _, ~.""" ....... y ~. ~,. ,, ",. ~ ... ... ~~.
... _...... ~ .. ~ ... ~ ...... "~. ~ .o ~ ... v. =. ... ... .._... ._-..., T_ .. .. ._ _ . . _ ....
not In a 3, the action will be transmittive paly inductive command both the cylinder and gear dynamic support of the rising poly induction blade, in b 3, At a4, the rising poly induction of blades causes a poly induction descending cylinder in b 4 .In a 5, an induction will be transnüttive gears gear drives simultaneously cylinder and the rising induction support gear will be tranmittive by gear hoop in b 5 In a 6, the split transmission serves both the cylinder and gear dynamic central df rising induction by dynamic central gear in b Figure 57 shows that clokwise movement is also possible peripherally.
Figure 58 shows that the clokwise movement can be realized bi-functional, the outer cylinder, and the. under inner blade being strictly rotational, and the blade in motion clokwise.
Figure 59 shows that it can be carried out so that the machine segmentation rotary by the use of U-shaped segments, 300 inserted into the spikes blades, such ways that their terminal portions 301 touch each other, or again, what about 2, touch on a central circular segment 302 .. In I 3, we see that these U-shaped segments can also be arranged in the cylinder, so that both otherwise the blade. In these cases these will be supplemented by segments 304 reminded the form of the race of the pale, arranged in the sides of these In b of the. same figure, we show how to realize the machine with the resort to crankshaft rather than an eccentric, by opening the blade in such a way as to let the crankpin crankshaft and refermanr extrusion by a party additional blade 505 In c of the same figure, we show that it can realize the blade rotational machinery cylinder in motion clokwise by building it in the manner of a blade of turbine. The entrance materials 306 by the center will therefore produce a first rotation from the blade to the a turbine, and the substances escaping from it will cause the cylindrical parts clokwise of it.
Conversely, if the substances are inserted externally 308, the.
turbine will then act as a strong material concentrator 409, and as a propellant.
Figure 60 shows other possible mechanics, which fall under, again a times rules of compositïon already shown. It is therefore important to repeat that these induction assemblies are exemplary. Any induction of these may be replaced by any other induction, according to the case, standard, will be transmittive, rising or descending Here, in the three cases, induction rising is a polyinduction. In a, the induction gears 400 are supported by their support gear 401 and are coupled to a second series of gears which will be Peripheral support gears 402. The crank pins, 403, supporting the blade 404, will therefore be coupled to the induction gears by the use of this second series gears. These the latter will retroactively activate the 405 cylinder induction gear.
~ 9 In b, the poly induction activates the blade, 406 and is connected to a sexi gear transmission reversive 407, activating the cylinder. In c, the original cylinder gear 408, is coupled to a 408 internal gear, which will realize the cylinder so planetary.
Figure 62 shows the semantic gaps overcome by our work in relation to planetary cylinder machines, there is error of meaning and omission or contradiction of mechanization. Indeed, the correct meaning of these machines is complementary to sense of their counterpart, and the mechanics should not be that of the figure, but that of against part. A correct understanding of these elements allows, as we have shown, perform the cylinder bifunctionally.
With regard to machines with blades and rotational cylinders, the meaning of these it must to be reversed since according to the rule we have given, the next expansion being in the same place, the blade must make a hundredth twenty degrees, and the rotational cylinder must undergo a one hundred and four came degrees. This reorientation of the machine makes it possible to consider it as the octave machine chromatic gems K) The rotor cylinder machine realizes a virtual figuration blade of machine square cylinder, and thereby becomes differential retrorotative, which lower Ia motor skills. the understanding of this machine is incomplete, no only by (no general rule, but also by the absence of a machine at clokwise movement, and by the absence of the establishment of virtual figures and Reliable. As before, there is an absence of mechanization of this figure, which would have shown this retrorotative character, and the need to be transmission, or downward inductions.
This figure is out of his chromatic fields and remains isolated, differential previous, without mechanics. Like most attempts in terms of machinery rotating, it evokes the machine in the compressive and non-motor capacity, what gives it an inferior power, even to standard machines.
L) fine knowledge of inductive figures, figurative, the poly turbines, and dynamic, ie the Clokwise motion machines of blade or cylinder IVI) the absence of establishment or determination of mechanical levels of figuration or dynamics N) the absence of mechanized accelerated-decelerate dynamics O) the absence of chromatic fields Prior Canadian patent applications for this application titrated ROTARY OR POST ROTARY MOTOR MACHINES AND BI
ROTATIVES (second part: concluding generalization) are the following I) Retrorotative, post-rotating and birotative engines ( conclusion) number 2, 442, 3S I, 1e September 24, 2003 2) Retrorotative, post-rotating and birotative engines ( conclusion second part) number 2,460,217, January 26, 2004 3) Retrorotative, post-rotating and birotative motor machines conclusion, third part) number 2 458,162, February 13, 2004 4) Retrorotative, post-rotating and birotative motor machines conclusion, interpretative additions) number 2,466, 987, April 26, 2004 5) Retrorotative, post-rotating and birotative engines generalization of circular rotary machines: chromatic ranges) number 2,466, 985, May 17, 2004 n,. ~~, ~, ~ .. ~ w .rv ~ n.1 _T .. ~, rvr .. ~~~,. ~ m. ~. ~ ... Hw ~. ~, ..

Claims (53)

claims 1 Any machine which simultaneously realizes a compressive figuration material type rotating, retrorotative or birotative, a virtual figuration and a synthetic figuration, this machine can be located on the chromatic range of machines rotary with the exception of retro-rotary and post-rotating type machines whose material figures, virtual and real are identical, mechanized by mechanics of the same natures respectively retro-rotating and post-rotating, when the mechanical are for these cases Strict case, mechanics by mono induction and by gear intermediate, attributable to Wankle. 2 Any machine of dynamics of the standard compressive parts, whose mechanical by hoop gear is produced with a third gear allowing the disorientation Support and induction gears in connection with the hoop gear. 3 Any machine of dynamics of the standard compressive parts, whose mechanical by hoop gear is produced with the use of a chain or belt in replacement of the hoop gear 4 Any machine of dynamics of the standard compressive parts, of which the mechanical by poly induction is produced, when the three-sided blade with the use of more of two crankshafts supports, these being arranged outside the lines connecting the center and the corner of blades Any machine of dynamics of the standard compressive parts, whose mechanical by poly induction is produced with a so-called alternative poly induction, realizing alternately the induction of two subsidiary crankshafts by mechanical, and another induction by simple attachment to the blade, this being possible by partial retrenchment or total of teeth support or induction gears 6 Any machine of dynamics of the standard compressive parts whose mechanical by poly induction is produced an induction of each subsidiary crankshaft by one of all first degree inductions already listed by ourselves 7 Any machine of dynamics of the standard compressive parts whose mechanical by poly induction is produced by polycammed gear, these gears being produced by bringing together and alternative removal of their teeth, this producing the effects decelerative accelerate research. 8 Any machine called circular rotativo, whose retro-rotating action of the blade has been modified in such a way as to produce a place of next expansion different from that of his position standard, and produces a virtual figuration different from the figuration material, the. counterpart this modification is carried out by a rotational dynamisation or planetary cylinder 9 Any machine as described in, known as Clokwise blade movement, of which movement Oriented blade, observed from the outside, is zero, and whose cylinder is rotational, this dynamic realizing a place of new compression identical to its rotating counterpart. Rotary circular rotating machine in Clokwise movement of post type rotary, of which the cylinder is rotated inversely. 11 Any circular rotativo machine with Clokwise movement-type blade retro rotary, of which the cylinder is rotated in the same direction 12 Any machine as defined in 1, 8, 9, including support mechanics Parties compressives is performed with the use of two or more of the following :
- a rising induction - a descending induction - a serai transmission activating the cylinder or / and the gear of support for blade induction 13 Any machine as defined in 12, including rising mechanics generally but not limitatively is one of the following mechanics: by mono induction, by gearing Intermediate, by poly induction, by hoop gear, by double internal gears, by heel gear, by gear structure, by unit gear, by central active gear 14 Any machine as defined in 12, including the downward mechanism, is defining as a mechanics whose support gear is dynamic and peripheral, habitually placed on the blade, and the induction gear is central and activates the cylinder, is usually but not limitatively is one of the following mechanics: by mono induction, gear Intermediate, by poly induction, by hoop gear, by double internal gears, by heel gear, by gear structure, by unit gear, by central active gear Any machine whose transmission is invertible, and most often inverivo accelerative, and that is achieved - from reversing by coupling of external gears, and acceleration by coupling internal and external gearing - from gear gears, and double gears, gears 16 Any machine as defined in 1 and 15, whose mechanical activating the parts compressive blades and cylinder are combined and synchronized by their coupling to one and the same element either - the blade - the eccentric, or the crankshaft - the support / induction gear 17 Any machine as defined in 1, which will take place next expansion a place different from, before or after the standard place, and difference will be filled by a mechanical counterpart dynamizing rotationally or planetarily the cylinder. 18 Any machine, as defined in 1, whose action of the blade will realize simultaneously a virtual cylinder shape, this shape can be retrorotative or post rotating its place on the chromatic range. 19 Any machine machine, as defined in 1, including inductions and will be transmission can be achieved in a combined way, with the result that the support gears of one will be the same gears as the induction gears of the other, or vice versa. 20 Any machine as defined in 1, including the place of the next explosion is on the face successive of an earlier virtual figure instead of the next explosion Clokwise, this machine being then called rotary-circular differential anterior 21 Any machine as defined in 1, including the place of the next explosion is on the face successive of a posterior virtual figure instead of the next explosion standard, this machine then being called rotary-circular posterior differential 22 Any machine as defined in 1, including the place of the next explosion is on the face sequence of a virtual figure is posterior to the place of next Clokwise explosion, and before the next standard explosion, this machine being then so-called rotational circular to contrario 23 Every machine whose mechanics is the mechanics of the virtual figure of the machine , this, ie the mechanics of the stroke of the blade relative to the fixed body of the machine, and not relative to the material figuration of the compressive parts. 24 Any machine whose blade mechanics will correspond to the shape virtual cylinder that it produces, and which will be realized by the corresponding induction to this form, of standard way, or semi transmittive, 25 Any machine as defined in 1, including the places of the next compressing the form will occur by jump, thus requiring more than one round of the machine to achieve all the faces, and thus allowing a place of next compression to contrario, despite virtual figure with more sides than the material figures, figuration carried out by the ensemble compression sequences being called Real Figure of the machine. 26 Any machine whose blade is mechanically activated by a mechanical corresponding to the actual figure of the machine, 27 Every machine having a physical figure, a virtual figure and a real figure, of which the places of next expansion are prior to the Clokwise place thereof, between this one and the standard place, and posterior to the standard place, thus realizing, as the case a machine with a figure Differential real anterior, contrario, or differential posterior. 28 Any machine as defined in 1, whose compressive structure material will be retrotrotative, post rotary, or birotative, of type Polyturbine or tiered polyturbine .. 29 Any machine, as defined in 1, whose blades shall be - standard type, - as a combined set of single blades - in palic structure Any machine as defined in a, whose degrees will be increased - by vertical elevation of degree, - by planetaryization of the positioning of the blade, by accelerated / decelerative realization of the cylinder, by accelerated / decelerative or oscillatory realization of the blades. 31 Any machine whose dynamics of the compressive parts have been inverted, from center to periphery, as well as carried out in opposite directions, these machines being supported by the mechanics of their forms before inversion 32 Any machine as defined in 1, whose cylinder is planetary, and the blade is fixed, the cylinder being activated by the mechanics of the opposite nature figure 33 Every machine in the cylinder is moving Clokwise and the blade is in movement rotational, this machine using counter part mechanics 34 Every machine whose cylinder is in planetary motion and the blade in mouvment rotational Any machine peripherally and orientally inverted, whose movement of parts will be anterior differential, posterior differential, contrario. 36 Every machine in which one of the compressive parts is bifunctional, realizing both a cylindrical function of one of the compressive systems and a palic function of the second system. 37 Any circular rotational machine with clokwise blade movement, comprising in composition - subsidiary crankshaft rotatably mounted in the side of the cylinder and provided gear, and supporting the blade, these crankshaft having the same race since combined with the same third party, - a blade mounted on these crankshafts whose movement is a movement Clokwise a central axis of the machine to which is attached a gear coupling the gears of subsidiary crankshafts, as well as the rotational cylinder.

Crankshaft gears playing both the role of gears induction induction rising, and supporting the downward induction of cylinder, and Conversely, the blade gear acting as an induction support gear rising of blade and of induction of the descending induction of cylinder. 38 Any machine comprising a composition - a blade, governed by an induction will be transmittive, - an induction will be transmittive, including three gear gears crankshaft and the support gear, the same serai-transmission driving the cylinder, fixed at same axis as the support gear, the semi gear transmission of support of the blade and the cylinder induction being consequently confused. 39 A machine comprising a composition - a blade governed by an induction, exemplarily but nono limitatively a mono induction, - on its other side, a descending induction, for example also a mono induction governing the cylinder. 40 Any machine in motion Clokwise, whose positional action of the pale is no circular. 41 Any machine as claimed in I, the segmentation of which is conducted - by U-shaped segments angularly arranged in the points of such way that their end parts rest on complementary U-shaped segments - by U-shaped segments angularly arranged in the points of such way that their end parts are supported on a circular complementary segment arranged in the side of the blades 42 A rotary type machine whose eccentric is realized in the form of a crankshaft, the blade in which it will be arranged so provided with an extrusion allowing its layout and of a piece of completely later fixed closing this extrusion and eventually blocked by any standard process. 43 Any machine claimed here, used as a pump, motor, compressor, machine of capture, compressor, artificial heart. 44 Any machine whose blade mechanics is made in such a way as to achieve, through length the material aspect of the figure, and by its mechanics Orientational, the virtual form intentioned. 45 Any machine whose blade mechanics is made in such a way as to achieve, through length the material aspect of the figure, and by its mechanics Orientational, the virtual form defined, through a real synthetic journey defined 46 Any machine with induction cylinder mechanics descending in departure of the blade 47 Any machine with induction cylinder mechanics will be transmittive in departure from the eccentric 48 Any machine with induction cylinder mechanics will be transmittive in departure from the dynamic blade support gear 49 Any machine in which the reach length is relative to the figure material and the mechanical, semi transmittive or not, relative to the virtual or Real figure. 50 Any machine whose cylinder rotationality allows angulation equivalent, according to the mechanical counterpart rule, unlike angulation of the new blade position in total expansion and standard position. 51 Any machine having at least one of the descriptive parameters following a) having a first degree induction of the present inventor b) having a descending induction c) having a rising induction served transmittive d) having a cylinder induction will be transmittive e) having an oscillatory blade action f) having an increase of degrees by addition of induction, by polycamation g) possessing a horizontal combination of inductions 52 Any clokwise movement machine, or slinky whose blade or cylinder are increased degrees. 53 any machine possessing in addition to the material character a character virtual, or virtual / Real