CA2421097A1 - Combinational guides for poly inductive machines and synthesis of guide levels - Google Patents

Abstract

The object of the present invention is to add a few additional support methods for poly inductive machines, with simple blades, with palic structure, with horizontal pistons, these machines having already been commented on by ourselves in our previous work relating to these subjects. In particular, there are a few ways of driving the blade by blade hoop gear, by intermediate heel or side gear, or by geometrical mono induction. The second part of the invention that all the methods already listed by ourselves can be produced in stages so as to produce birotative or meta rotary machines. Lately we will show some specific figures trained by the composition of these methods for machines with single blades, machines with palic structures of poly turbines type and differential piston semiturbines.

Description

D ~ VUIgatlon The first part of the present invention is ~. specify some additional support methods. In our previous work, we showed that we could activate a blade of a poly machine inductive from a so-called hoop gear uniting the blade induction gear the support gear, these gears being rigidly connected respectively to the side of the blade and to the side of the machine . (Fig. I) A first embodiment of the present invention is simply to specify that the hoop gear can be connected rigidly to the blade. From then on, it will be the crankpin gear of crankshaft which will be free. (Fig. 2 a) We can then camer them fixed support gears and the blade hoop gear, and so modify not only acceleratively but also depending on the distance relative to the center of the machine, the path of the blade (Fig. 2 b) It will be noted that, for a machine of retro rotary type, the th procedure is achievable, but by increasing the feedback of the blade gear by the retro rotary action of the support gear, which is obtained by various means including that of semi-transmission, such that already commented by us.
A second support method specified herein will be the use of an intermediate gear either at the heel of the crankshaft either on its side (Fig. 3 a and b) By this method we succeed in doing work a blade, even post rotary, from a gear external type induction, which allows the blade support By a crankpin, as opposed to an eccentric, reducing the friction and increasing the ease of oiling the machine. Die more producing the machine with reverse gear on the side, we Corrects positively the attack on the blade, which is no longer in drag.
A third method, also already used by ourselves in our poly turbines, and which we must generalize, is that of mono induction with geometric addition, or concisely said pus, rnono induction geometric.
We know that we can produce various forms of racing by mono direct induction. For example a triangle, or a squareoid, by a crankpin located directly on the gear (Fig. 4 a) Furthermore, we also know that we can produce these shapes, with gear sets different, plus geometric values. This is what produces our side theory. (Fig. 4 b) Thus, replacing the blades with connecting rods of geometry, the desired shapes are produced. This idea to already been developed by ourselves previously, and the present purpose is simply to generalize it as a support method.
Indeed, we know for example that each point of the triangular blade of a rotary machine is able to produce for example a square perfect. Therefore, by replacing the blade with a connecting rod geometry, itself, like the blade ruled by one of the various mechanical guides already listed by ourselves, we can attach the end of that c- to each center of the compressive parts and thus produce an appropriate control surface. (Fig. 4 c) A fourth method also consists simply in providing a precision relative to a method already exposed by ourselves.

(Fig. 5 a) Indeed, we previously showed that we could, to change the speed of movement of the blade relative to that of the crankshaft use gears as we said gears eccentric and polycamed. This part of this consists just to point out that these gears can have a shape acute, in such a way as to maximize their effects to certain moments determined on the blade. (Fig. 5 b) The second part of the present invention is also a generalization of ideas already commented on by ourselves.
We have indeed shown in my previous work that the races blades and palic structures of the post and retro machines were imperfect, causing little torque in one and little couple in others. To resolve these issues we have submitted three solutions, all aimed at producing, for each machine an aspect birotative, simultaneously realizing all the qualities of these machines. These solution have all made it possible to correct the cylinder shapes, making, in post rotationally modifying the retro-rotating forms, by modifying retro post rotary forms, and adjusting the forms birotatives of poly turbines in a more post rotary manner. (Fig. 6 a, b, c) In addition, these corrections we will have allowed to produce shapes exaggeratedly post rotary or retro rotary, thus making possible high compression post rotary and retro rotary machines (Fig. 6 d, e) In these latter embodiments of the invention, it will be noted that one can, depending on the desired effect, use each poly induction level equally many post or retro rotary mechanics. Similarly, it will be noted that you can perform the basic movement at the first level, and corrective movements at the second level, as one can choose carry out corrective movements at the first level, and general movements at the second level. It should be noted that if we uses two poly induction of the same kind, either post rotary or retro rotating, we arrive at more sophisticated meta forms.

It will be noted that all these machines mounted in mechanical double will have a predominance post or retro rotary according to their origin, or again according to the amplitude of the most engaging mechanical form of their movement. Likewise they can be carried out to increase Ia piston rise, as if to enlarge the crankshaft arm according to the utilities.
As we have already shown previously, the blades of post, retro and bi-rotating machines can be governed by several ways, which ways have been described by ourselves prior to this document and which may be listed as follows 1) mono induction

2) poly induction

3) by semi transmission with and without pinions

4) by hoop gear ) by intermediate gear 6) by double internal gear juxtaposed 7) by polycame gears 8) by stepped poly inductive gears 9) by equidistant gears 10) by gear structure 11) by cam 13) by hoop and intermediate, off-center 14) by eccentric polyinductive ) by angular hoop gear 16) by unitary poly induction 17) by hybrid polycamera gears 18) by externalized poly induction 19) by dynamic mono induction 20) by geometric poly induction 21) by double differential poly induction 22) by heel-center gears 23) by side side gear 24) by blade hoop gear I, 'there is attached a memorandum in order to facilitate the prior understanding of these methods, which are all more precisely defined in our previous work.
It is easy to understand that since one or 19 other of these methods can be combined in staging ~ another of these methods to produce basic shape corrections in such a way produce the anticipated machines, so we will have one more possibility of four hundred methods and possible assembly by machine.
fuzzy so we will limit here to just give a few examples of them. So we will comment on the machines made <from - two ono inductive supports (Fig. 7, a) - a mono inductive support and a poly inductive support (Fig. 7 b) - a single inductive support and a hoop or double support blade hoop support {Fig. 7 c) - one mono rotary inductive support and the other post rotary (Fig.
8 a) - one post rotary mono inductive support and the other retro rotary (Fig.
8 b) - a support by hoop, and a mono inductive support (Fig. 8 c) - a hoop support and a blade cam support (Fig. 8 d) - one support by mono geometry and one support by mono induction, including an eccentric gear (Fig. 9 a) - A stepped hoop support (Fig. 9 b) Double rotary post (Fig. 9 c) Poly induction support and hoop support intermediate (Fig. 9 d) A poly induction support and poly cam hoop (Fig. 10 at) Of course all these figures are only examples. Indeed, as we have already mentioned, their combination will result in more than four one hundred and twenty possibilities that it would be impossible to list here in a way Detailed.

All these figures and methods can be understood under the same idea that the combination of mounting methods achieves forms of machines whose cylinders have been corrected in such a way as to produce maximum torque and compression, which do not produce the basic forms left in their natural state. We will say first and second level poly induction depending on whether they realize the basic form or its correction, increasing or decreasing thus its amplitude.
In the first case, in fact, there is a third section of this invention more specifically applies to poly type machines differential turbines and semi turbines ~. horizontal pistons. and will allow in the first case, to increase the compression of the rotary rotary, and in the second, that of post rotary, just as we will succeed in producing the elliptical shape of poly turbine type machines by post induction (big. 10) As in our previous work, polycamed gears can make several of these stations with fewer parts. Note that the blade support without eccentric, but rather ~ t by a gear fixed support and a free gear rotatably mounted on the crankpin of the crankshaft will allow, if the blade and support gears are polycams, not only to accelerate and decelerate the movement of the blade in a controlled manner, but also to raise and lower it level also in a controlled manner (Fig. ll) Lately, it will be noted that since the pointE; machine blades poly turbine type will already cover a twist stroke, all of these combined mounting methods will drive them correctly. (Fig. 25, 26) Likewise the methods here listed will be able to support the blades by their center, which describes a square shape, up to the oval or to the circle (Fig. 29). In the latter case, the methods in combination listed herein will be effective. We give here an example a blade center support by geometrical mono induction.
In the final analysis, note that the use of two poly inductions anti-rotating one another supports a workpiece the same digital aspect that the piece that one of the induction would have supported, since it respects both the equidistance between the points of the two races. So we can build multis post or retro rotary for the same rotor cylinder. This way of doing things will allow produce off-center cylinders and therefore a series of mirai consecutive machines. (Fig. 24) The purpose of the next remarks will be to show that the generalizations previously made also apply to others types of machines, namely poly turbines and metaturbines. Indeed we can state that the combinations of guidance methods apply to all classes of machines. In the case of poly turbines. There will always be two. In the case of metaturbines, we will always use three of them. According to number of methods coming in combination to support the blades one will say that it is poly turbine and meta turbines Lately we will show that hybrid cylinder machines ball, can also be supported by combinations of three types inducti on.

As we have already shown, polyturbines are machines that we could say level two, because they require, in composition two induction methods to support the tip of their palic structure, and that it is of cylinder with post prominence rotary or retro-rotating prominence. We have shown, in fact, that the bi rotary aspect of these machines allowed support structures just as retro as post rotary.
In both cases, it is necessary, when it is intended to support the machine by the points of attachment of the blades, to produce supports involving two levels of support. In the methods the simplest retro-rotary and post rotary ones we add in fact, either with the retro rotary mono induction or with the double post induction rotary, a geometry rod which modi ~ e the course of the elements of such a way of realizing the specific aspects of it. This allows make cylinders wider than if they had been produced by mono induction, what poly turbine cylinders require. (Fig. 25) Generally speaking, basic methods require the addition of geometric parameter with basic inductions.
The purpose of this is to show that, as with single blades, a generalization of mounting methods poly turbine type machines can be understood in that it requires the combination of two types of support, among the set already listed.
We can therefore use a poly induction unit, combined with a geometric aspect (Fig. 26 a), or a hoop structure, combined with a single induction (Fig. 26 b), or finally, a retro rotary structure combined with a post rotary structure (Fig. 26 c) As in the case of single blade machines, the combinations are many and it will be understood that these examples are here sufficient, which does not limit the present generalization.
It should also be noted that, as we have already shown, the blades machines with palic structures can also be supported by their center. The simplest case, which realizes an elliptical cylinder, is, that the use of a retro induction performing a fitness run carréoide. (Fig. 27) However, as we have already noted, this shape is more realistic, from the point of view of the central stroke, in these pump type realizations as in these motor type realizations.
We can indeed note that during the last moments of the rise of the pale, the center of it went down, which facilitates the climb. The appearance pump is therefore fortified. In contrast, however, when the descent, the center of the blade makes a brief ascent, which is a wrong, from a motorological point of view. (Fig. 27 j We have already proposed, that the preferable cylinder shapes for this type of machine was those with double bends, recalling that, in more extensive, V'lankle engines. By this shape of cylinder, we allows, when the expansion begins, not only to the part offensive, but also at the center of the blade to begin its descent, which results in a better quality couple. To make this shape of cylinder, we have shown that a post type poly induction inductive, or in combination of induction were preferable. One other way, a polycircuit retrorotwtive poly induction also realized these desired shapes, which has already been assembled by ourselves. .
If one intends to govern the blades by their center so as to achieve There are several possibilities for these types of cylinders. First, it will be to modify the direction of the initial squareoid of the center stroke of the blade (Fig. 28, 29), the tips of this squareoid co ~ ncid ~ nt with the middle of the blades when the palic structure is in its square shape, by opposition to its diamond shape.
We can also simply return to our very first works on rocker piston machines, and offer a circular seam.
In this case, despite the roundness of the stroke of the blade centers, the speed of realization of these races will be non-constant, that is to say, alternately accelerating and decelerating, which will cause the approximation and distance of the blades. In this case, the methods of guides already present by us even by ourselves to govern the differential turbine blades may be used. We will be able indeed to use the methods by poly induction, retro or post rotatïve, engaged on slides, annihilating thus vertical aspect behind the scenes of inductive poly cams. We can, on the other way, use a poly induction by polycamed gears, the blade tips then being perfectly supported in circularity and alternative gears. (Fig. 30,31,32) As in the case of the semi turbines, the supports may as well be of the type retro or post rotary.
In addition, let us mention that in general, the o can govern the center in the same way as the poins, for example by double induction, by rectilignocircular induction, taking only care to adapt these support structures taking into account what makes the difference and the originality of the travel of each blade of palic structure in the time compared to that of blades of single blade machines. In the machines with single blades, the races of the central parts of the media blades run in opposite and equidistant races to that of points located on the poïntes, and that with the same number of sïnusoïde per turn. (Fig. 33) what makes the peculiarity of structural machines palic is that the points located on the middle centers run races with a ratïo of sïnusoïde double that of the poïntes. It is which produces the pivoting aspect of each of the structural blades palici. In its simplest version, for example, while the points act in two parts, the centers act in four parts. In rotary motors for example, the points act in two sides, and the side centers also in two sides, although opposite All of these considerations take us to another level of our presentation, in which we intend to show, that as in the case machines with single blades and machines with palic structures, so-called metaturbine machines, i.e. with irregular cylinders, not only a set of precise poly-induction irois, but three inductions taken from the already mentioned index previously. What makes them special, therefore, is what always use three inductions in a combinatorial way We have already shown that this was verified for certain examples.
For example, we can build a metaturbine with a retro induction, plus a geometric value, in the form of a geometry rod, and finally produce with the input of gears polycamés. (Fig. 33) The purpose of this section of the present invention is to specify that, as before, the use in combination, this time of three guidance methods among those already listed by ourselves, will result in the realization of metaturbines. As before, the list of possibilities, here of level three, that is to say, involving three inductions is very broad, and cannot be listed descriptive here. We will consider the analytical aspect as valid description. We give, however, as an example (Fig. 34) that a post rotary mono inductive induction, combined with an induction retro-rotating, and augmented by a geometry rod. This combination will realize the machines with irregular cylinders, augmented.
On the other hand, considering on the contrary cylinder machines irregular, but this time diminished, balloon-like (Fig. 35), we again will have to use induction combinations to achieve the complex stroke of the blades of these machines (Fig. 36,37).
In the two simplest cases, namely those of balloon cylinders with two and three sides, almost rotating, and almost triangular, we see that the seemingly simple stroke of the blade is actually very complex. Yes we only look at the race from the center of these blades, we see that we can realize them with either simple mono-inductions, or with mono induction with geometry rods. But above all in the case of the triangular cylinder cylinder machine, this supports central cannot ensure the control of the blade. Note that for the in the case of simple plastic pumps, for example, a cam would be sufficient (Fig. 40) but in the case of an engine, more support as ;; urê is necessary. Now if we examine the course of points located on the pale m, between the points and the center, we see, in both cases, e. the complcxity of the race. (~ irg. 36, 3 ~) We can however deco ~ nposcr this fgurc, and see that it can be built with the help in each case of two mono induction combined with one another and additions of a geometry rods.
(Fig.38) So we will say that these seemingly simple machines are level three machines, which is the same level as the meta turbines.
Of course level four machines are possible, and would receive the same generalizations as above, rr ~. but we believe that their commercial realism> nc would not be interesting.
Brief description of the stations Figure 1 is a cross section of a m ~ poly inductive cinc â
hoop type blade guide Figure 2 shows in a) that the hoop gear can be used as blade induction gear and Iui rigidly fixed, to be then supported by two or more support gears. In b) the gears are polycamé; ~
Station 3 presents a poly inductive machine, the method of mounting is by gear or intermediate gear assembly sideways Figure 4 shows that the use of poly-cam gears in a poly inductive machine can be made with polycea gears acute, thereby increasing the effects thereof Figure 5 shows that the basic figures, retro shapes, post rotary or imperfect birotatives of poly turbines can be improved by accentuations and lightening of their forms, so as to make them perfectly bi rotary Figure 5b shows, on the contrary, hyper post rotai machines ~ ivées or retro-rotated Figure 6 shows that the geometric mono-induction method is a separate guidance method Figure 7 repeats a mounting of double mono induction staged, that that already shown by ourselves in our previous work, the second induction correcting the form of the first, the result being a form purer, more bi rotary Figure ~ is a first generalization example of this, or a poly induction is staged on a mono induction Figure 9 is a second example, where we find in a) a poly stepped induction by hoop gear, and in b) by blade hoop, these two poly induction mounts respectively on mono induction Figure 10 shows a mono induction of retro induction type mounted on a retro induction Figure 11 shows n morio retro rotary induction mounted on a morio induction post inductive Figure 12 shows a post rotary induction mounted on a hoop gear induction Figure I3 shows a poly induction by blade hoop gear mounted on a hoop gear induction The station 14 shows a single induction by polycamed gear, mounted on an induction by mono induction of geometry Figure I 5 shows two mounted hoop gear controls one over the other.
Figure 16 shows two mono induction juxtaposed, one controlling the center of the blade, and the other, crossing it, controlling the orientation of it Figure I7 shows two tnono induction juxtaposed, one port: and the other retro rotary, located on the same side of the blade, one controlling the center of it and the other, crossing it, the orientation of it.
Figure 18 shows a post rotary induction mounted on a poly induction Figure I9 shows an induction by gears ~. fixed axes, mounted on a poly induction. Here, the support axes of the gears become rotary, by the play of this second induction Figure 20 shows a mono induction by polycamé gear on semi transmittive induction Figure 21 shows a blade hoop gear induction, mounted mounted on a semi transmission.

Figure 22 shows a sl; ruciurc mono inductive controlling the cf, ntre of the pals and a superimposed internal gear pan structure controlling the orientation of it.
Figure 23 shows an internal induction type c governing lc center of the blade, associated with mono induction and poly-type controlling the orientation thereof.
Figure 24 shows the ca: ~ where the blades are activated by double complementary mono inductive movement. Ccttc way dc faine will produce off-center cylinders and therefore a consecutive mini machine series Figure 25 is a resumption of two retro rotary guidance methods ct post rotary already exposed by us memc as a method of supports palic syructures of poly turbines.
Figure 27 shows that the; elliptical cylinder of poly type dc machines turbine promotes, from the point of view of the center of the blade, the appearance compressor thereof at the expense of the engine aspect Figure 28 shows that the double bending figure allows the contrary the descent simu.tanéc, during the orcc dc expansion ~ of the offensive part of the blade and its central part Figure 29 shows that this figure can also be produced by a central blade support, when the race would collapse from the start of the descent. The forms of racing would vary from cal ~ éoide to fc ~ rrne circular.
Figure 30 shows that in these two cases, the support methods already shown by ourselves applying to our felt turbines differential also apply to polyturbï ~ ies. This figure represents the first of them, that of poly induction-slides.
Station 31 shows the second of these methods, in which we combine the centers of the blades ~. ono induction involving idealized a ~ rec using polycamerous gears Figure 32 generalizes the support methods of the blade centers as being the same as those of the tips, but with a sinusoid twice as fast. This figure presents only two examples.
Figure 33 recalls a level three support method for meta turbines Station 34 shows an example of the present generalization applied to metaturbines. We use here an induction ~. gearing hoop, in polycamé, added with a geometry rod.
Figure 35 a ~ shows two .fi res of balloon cylinder, two: and three sides, and levels three, in b, as well as a piston figure , wink. We can see the stroke of the centers of the blades and pistons of these machines.
Station 36 shows the course of points located on the line of the lines of the blades.
Figure 37 shows their geometrical decomposition, in two levels of races and a level of geometry.

I, af station 39 does not have a deu ~ i ~~ no sorting exercise supports combined for a machine ~. tria balloon cylinder ~~ gular Figure 41 shows that in the case of certain uses, such as small plastic pumps Orientation: ionel of the blade can be made by a cane or by the blade itself ~ n ~ e on the c ~ li ~~ dre Figure 42 recalls that the n ~ th machines can be used only as pornp ~; s, compressors g rnaches of capture, but also as hydraulic and wind machines, in the as we adapt the design of the blades f, a figure 3 shows that one can easily seal the pay transmittive of the ca ~ mpressive parts by a rotatable piece rr ~ or ~ tées ~ provided with circular seals of ~ tanch ~; itéa Detailed description of the figures Figure 4 shows that the use of poly-cam gears in a poly inductive machine can be made with polycamerous gears acute, thus increasing the effects thereof. In the case of machines post rotary, the tip of the gear will reduce the slowing down of the pale in a timely manner. lC7 in the case of post inductive machines, at on the contrary, the decrease in length between the center and the tip will increase the speed of the blade in its arc, and decrease it in these corners. These effects are already commented on by ourselves in our previous work on Polycamed gears. This does not effect than showing that we can exaggerate these effects more, using acute polycamerous gears.
Figure 5 shows that the basic figures, retro shapes, post rotary or imperfect birotatives of poly turbines can be improved by accentuations and lightening of their forms, so as to make them perfectly bi-rotary. This figure recalls that basic cylinder and blade stroke shapes of post machines rotary, retro rotary, and bi-rotary poly turbines can be improved by bringing them closer to more perfect birotate forms. one can achieve these effects by polycamerous gears, as shown previously, but also by poly induction layers!
second poly induction, smaller, correcting the shape of the first. These corrections have already been shown by us in our previous work, in which we have shown that a mono stepped induction can correct the curvatures of a first mono induction. This has rather the effect, as we have already mentioned in our disclosure to generalize to all support methods already exposed by ourselves the application of these in staging, allowing to correct the shapes of these.
Figure 5b shows, on the contrary, hyper post rotary machines or retro-rotated. These types of machines are produced when the shapes are corrected not in the direction of their regularization towards bimrotative forms, but, on the contrary in the direction of their hypertrophy.
In a, we suppose by set a post rotation mounted on a post rotation, and in reverse b ~ reverse rotation, mounted on a retro rotation.
Figure 6 shows that the same shapes can be obtained by direct mono induction, or by mono induction added with geometry rods. In the latter case, the ratios of the gears are changed, and the connecting rods can act as a lever.
FIG. 7 reiterates a mounting of double mono induction staged, such that already shown by ourselves in our previous work, the second induction correcting the shape of the pregnière, the result being a shape purer, more bi rotary. Here we see that a first mono induction I, controls the stroke of the center of the blade, which will no longer be circular, but for example here almost: triangular. This race will to push the blade deeper towards the cylinder, when the explosion. A stepped support gear 15 is then arranged rigidly on the crankshaft at the height of the crankpin. The gear blade induction is coupled to it, and as a result of the retro rcstation of the blade eccentric, it will undergo a movement slowed down by compared to this and contrary to that of the main crankshaft, which is the desired effect. This time, however, the movement of the blade; will be amplified, creating an important comp ession, mé in a mac ~ hïne rétrorotative. For a better understanding, We will take care to read our work on this and.
FIG. 8 is a first example of generalization of the present, or a poly induction I is staged on a mono induction II. As in the previous example, a stepped support gear 15 is fixed rigidly on the crankshaft pin. Poly inductive assembly II
is coupled to the induction gear 17 of the my lower induction and is therefore rotated by it. This drives the gears poly induction induction 18 and their cams 19 in post rotation. The blade, being supported by these cams, therefore undergoes the both poly induction of hase I and level II cam corrections Figure 9 is a second example, where we find in a) a poly stepped induction by hoop gear, and in b) by blade hoop, these two poly induction mc> nting respectively on mono induction As before, the stepped support gear 15 is fixed to the crankshaft crankpin and stepped induction, are based on both the rotation of their cams or crankshafts driven by induction lower and combines it with this support, to result in a movement of pale corrected.
Figure 10 shows a single induction of retro induction type I
rides on a retro induction II. Here the stepped support gear is internal type 20, and as previously connected directly to the crankshaft crankpin at its center 21 Figure 11 shows a retro rotary induction rnono mounted on: r a mono induction post inductive. The particularity of this assembly consists in that the blade induction gear is not like previously supported on a stepped support gear disposed on the crankshaft, but rather directly on a gear arranged in the side of the machine 22. In. this case, since the stroke from the center of the blade has been eccentric and is no longer circular, the support gear 22 of the stage, or the induction gear 2, or both, will be of polycame type. These elements are also discussed in our Previous work. The effect of this is to generalize them to all guide methods already listed by ourselves.
Figure 12 shows a post-rotary induction II mounted on a induction by hoop gear I. The same comments apply to these Figure 13 shows a poly induction by hoop blade II gear mounted on a hoop gear induction I

FIG. 14 shows a mono induction by polycamed gear I, mounted on an induction by mono induction of geometry II
Figure 15 shows two hoop gear controls II and I
mounted one on top of the other.
Figure 16 shows two mono induction juxtaposed I and II, have controlling the center of blade I, and the other, crossing it, controlling its orientation II. In this arrangement, one must assume that the poly induction governing the orientation of the. blade is made up ~ r to a end of an induction gear is connected to the induction gear blade by an empty axis, this axis being rotatably mounted on the rr ~~ aneton of the crankshaft 28. The gear of the blade eccentric 29 and this eccentric 29 are then rigidly assembled and mounted around. of the axis of rotation of the first two induction gears. The blade 31, provided with a blade induction gear 32 is disposed on the eccentric and coupled to the blade induction gear.
The assembly allows the control of the orientation e the blade despite the non-rotating stroke of its center.
Figure 17 shows two juxtaposed mono induction, located in the same side of the blade, one controlling the center of the blade and the other, the crossing, the orientation thereof. How this maci ~ ine works st similar to the previous one, except that one of the two mono juxtaposed and staged induction is retro rotary type, using a internal gear. As before, the induction gears of the upper tier will indeed be connected by a hollow axis mounted on the crankshaft pin. The induction gear and the eccentric of blade are then rigidly connected and rotatably mounted on this axis of rotation. As before, this set allows control directional of the blade despite the non-circular travel of its center.

Figure 18 shows a post rotary induction ~ I mounted on a poly induction II
Figure 19 shows an induction by gears with fixed axes I, mounted on a poly induction II. Here, the support axes of the gears become rotary, by the play of this second induction. The blade is fitted with a hoop gear and is mounted on the axle gears fixed internal, but in external movement FIG. 20 shows a mono induction by polycamÉ gear; I on a lnduCtlon seml tranSll '~ lttlVe II
FIG. 21 shows an induction by blade hoop gear I, mounted on a semi transmission. II
Figure 22 shows a mono inductive structure controlling the center of the blade I and a structure by superimposed internal gears II
controlling the orientation of it.
Figure 23 shows a ~ r ~ ono induction of internal type I governing the center of the blade, associated with polycame II type mono induction controlling the orientation of it.
Figure 24 shows the case where the blades are activated by double complementary mono inductive movement. This way of doing things will produce off-center cylinders and therefore a consecutive mini machine series Figure 25 is a resumption of two retro guidance methods rotary I and post rotary II already exposed by ourselves as combined support methods of the palic structures of poly turbines Figure 26 shows that by generalizing level two guidance, that is to say of two inductions in a combinatorial way, one can realize in many ways the supports of palic structures, including present example, a mono inductive post rotation I, combined with a mono induction retro rotat ~: ve II.
Figure 27 shows that the elliptical cylinder of type machines poly turbine promotes, from the point of view of the center of the blade, the appearance compressor thereof at the expense of the engine aspect. Indeed, we can see that at the start of the expansion, central parsia of the blade is forced to go up 40 instead of going down. As opposed to this however, at the end of compression it goes down 41, which makes it easier Figure 28 shows that the double bending figure allows the contrary to the simultaneous descent, when the expansion of the offensive part of the blade 43 and its central bet 44 Figure 29 shows that this figure can also be produced by a central blade support, the stroke of which would collapse as soon as the descent. The forms of racing would vary from earreoid 45 to the form circular 46.
Figure 30 shows that in these two cases, the support methods already shown by ourselves applying to our turbines Differentials also apply to polyturbines. This figure represents the first of them, that of poly induction -slides. Here, the circularity of the movement of the blade centers is ensured either by 4 ° 7 crankshafts, or by a circular central cam 48 sure which they are supported. As for their speed alternately accelerative and decelerative, it is obtained by nono induction 49 engaged in slides 50 arranged on the blades. These behind the scenes cancel the vertical aspect of the movement and retains only the lateral aspect, Figure 32 generalizes the support methods of the blade centers as being the same as those of the tips, but with a sinusoid two times faster. 1 ~ '' ar example here the blade centers are supported in aj by double induction attached by link rods 54, and in b with the use of hoop gears. 55 Figure 33 recalls a support method of the Meta Cross level turbines. Here three levels of induction are condensed in the way next. First of all, we find a retro rotary induction 56 . Then, this ~ is poly cameo type. 57. Lately, this is supplemented by geometry 58 rods The f station 34 shows a ~ fxen'.ple of this generalization applied to rnétat ~ rbine; ~. We use here a mono induction type post rotary 59, combined with a retro rotary induction 60, and completed by a geometry connecting rod 61, supporting the blade 62 Figure 35 shows two balloon cylinder figures, on both sides a) and three sides in b), as well as a station in Slinky pistons in c).
We can see the stroke of the centers of the blades and pistons of these machines 63.
Figure 36 shows the much more complex course 64 of pi ~ ints located on the line of the tips of the blades.
Figure 3 ~ rr ~ on their geometric decomposition, in two levels of races 65 and a level of geometry 66.
Figure 38 shows the combinatorial sets allowing to realize adequate supports for these blades. We see that they put in eon ~ pairing two induction 6? .6 ~ and a geometric addition 69, this which allows to classify these machines con ~~ not being e level three, and in generalize mounting methods. in the exemplary case of the cylinder in balloon shape ~. double arc, a first mono rotary induction ~ is completed by an induction n ~ ono rotary post rotary IT, and by a rod of geometry III. here, during the rotation of the crankshaft 7ID base, first level induction gear is driven retroactively 71 The second level induction gear 72, coupled to the second level support gear 73, is entered ~ born, thus as the connecting rod 75, in post rotation 75. The end of the connecting rod therefore travels the desired course. IJne induction additional, at a similar point or at the center: ~ re of the blade will complete the whole induction.
Figure 39 shows three-level induction combinations similar to support the blade of triangular machines balloons.
Figure 40 shows the differences in the relationship between racing various points of simple, opposite but equidistant blade machines, and poly turbine, of uneven number of sinusoids and therefore not equidistant.
I, a figure 41 shows that for small machines, a simple eccentric 76, coupled ~. anchor points 77 can sure ~. guarantee the appearance blade orientation Figure 42 recalls that the same machines can be used not only as pumps, compressors, collection machines, corn also, as hydraulic and wind machines, in the n ~ esu: re where we adapt the design of ~~ ales. Same, as we have moreover already mentioned in our previous works, the machines proposed can be used in combination with turbines And we can achieve with these combinations. In summary, we therefore see, in all of the latest talk that we can understand the notions of retro rotativity, post rotativity and birotativity of two main ways, depending on whether we are talking about the shape of the cylinders obtained, or depending on whether the ~ n speaks of the most mice part of the blade pale. we know that geometry motors ~ ankle are machines post rotary, while the triangular oomrang motors are of retro-rotating geometry. ant to poly turbines, they are of geometry bi rotary. when we consider these appellations from the point of view mechanical, we will say that post inductive mechanics produce post rotary machines, as mechanical with semi transmission, or still with hoop or intermediate gear are bi inductive. sleep than mechanical, for example with double internal gears, juxtaposed or staged, are retro rotary mechanics, rnê ~ ae applied to post rotary stations.
I, a figure 43 shows that one can easily seal the parts transrnittive of the compressive parts by a rotating part mounted, fitted with circular sealing joints

Claims

claims Claim 1 A poly inductive type machine whose blade is activated by feedback in relation to its crankshaft, this feedback being obtained by an inductive mechanical assembly Claim 2 A machine as defined in 1, comprising in composition - a crankshaft, have a sleeve fitted with a gear complementary blade induction, - a support gear arranged pole in the machine crankshaft crankpin in such a way - a blade, fitted with an internal hoop blade gear, and mounted in the machine by this gear arranged so as to couple the two support gears all of these parts being mounted so as to drive the blade in the opposite direction of its crankshaft during rotation Claim 3 A machine as defined in 2, including the rigid support gear is replaced by a retro-controlled support gear driven by semi transmission itself coupled to the action of the crankshaft Claim 4 A machine as defined in 2 and 3, using gears polycamed and eccentric in such a way to modify not only the blade speed relative to the crankshaft but also its variance of its deep in the cylinder Claim 5 A machine as defined in 1, comprising in composition - a machine body fitted with a cylinder - a crankshaft rotatably mounted in the machine, and fitted a gear or a set of intermediate gears - a gear or set of intermediate gears, mounted rotatably on an axis disposed on the crankshaft sleeve in such a way the machine support gear torque to the blade gear - a blade fitted with an external type induction gear, this blade being mounted on the crank pin or the eccentric of crankshaft, so that its gear is coupled to the intermediate gear all of these parts causing the movement of the blade in the cylinder, contrary to that of the crankshaft, and this from a observer positioned on the crankshaft itself Claim 5 A machine as defined in 4 whose gear or set intermediate gear is on the crankshaft heel Claim 6 A machine as defined in cry 4, whose intermediate gear and or set of intermediate gears are located on the side of the sleeve crankshaft Claim 7 A machine as defined in one, including the support gears and induction tubes are polycamed, the polycams of these machines having acute aspects Claim 8 A machine as defined in I, of which the uductio of the blade is produced by an induction composition, the blade centers being motivated by a type of induction and the orientation thereof being produced by a second Claim 9 A machine as defined in 8, using in composition positional and orientational blade a combination of two or more of the following support methods:

12) mono induction 13) poly induction 14) by semi transmission with and without pinions 15) by hoop gear 16) by intermediate gear 17) by double internal gear juxtaposed 18) by polycame gears 19) by stepped poly inductive gears 20) by equidistant gears 21) by gear structure 22) by cam 13) by hoop and intermediate, off-center 14) by eccentric polyinductive 15) by angulated hoop gear 16) by unitary poly induction 17) by hybrid polycamera gears 18) by externalized poly induction 19) by dynamic mono induction 20) by connecting rod of geometric geometry 21) by double poly differential induction 22) by heel-center gears 23) by side side gear 24) by blade hoop gear Claim 10 A machine as defined in 1, 8, 9, the two induction of which are located on the same side, the axes of each of them crossing one the other along their length, and being crossed by the crank pin of the crankshaft, so that the machine is well seated on each side Claim 11 A machine as defined in 9, 10, 11, the second gear of which support is said stepped support gear is arranged on the nanchon of the crank shaft Claim 12 A machine as defined in 9, 10, 11, the second gear of which support is also located in the side of the machine, causing a blade support or induction gear, or both poly cameo shape Claim 13 A machine, as defined in 1 whose oscillation in the direction of the depth is obtained by polycamation and blade hoop gear Claim 14 A machine as defined in 1, 8 and 9, comprising in composition several equipped with rotary machines in composition, the blades of each of them being supported by a double guide, as listed in present Claim 15 A machine as defined in 1, of the poly turbine type, this machine being supported by points located on the lines of coptic centers by poly inductive means of first, second third level Claim 16 A machine as defined in 15, the attachment points of which blades by means of poly induction are slides, and therefore whose travel safety is produced in support of the blade centers on crankshaft pins or on a cam or circular center.

Claim 17 A machine as defined in 15, using induction involving polycamerous gears, the attachment points of the blades to induction using crankshaft crankpins Claim 18 A machine as defined in 1, of the balloon cylinder type, of which the orientational aspect of the blade is provided by cam or by the cylinder himself, acting as a cam.

Claim 19 A machine, as defined in 1, used as a compressor pump , capture machine, hydraulic machine, wind turbine, artificial heart or other underlying application, or in combination with a turbine, like semi jet engine Claim 20 A machine as defined in 1 whose mechanics are prominent retro-rotating, regardless of the predominance of its form