RU2330963C2 - Rotary-type machine (versions) - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: invention relates to rotary-type machine. The machine incorporates an external support assembly with a cylindrical space accommodating two movable compressing parts, both having a cylindrical and a blade part. The cylindrical part runs about the blade thus making a rotary motion par, while every tip of the blade part strikes a circular figure for one entire cycle of the aforesaid machine. The centers of the said circular figures are equidistant and arranged on the periphery at an equal distance from the center of the aforesaid cylindrical space, while the blade part effects a circular motion in the same direction during the entire stroke and thus making a rotary and reciprocating motion. It is shown that, mechanically, the rotary properties of the machines may be exploited in horizontal plane thus allowing a differential or opposing motion.

EFFECT: production of rotary-circulation machines with differential dynamics or opposing motion.

41 cl, 80 dwg

Description

The text of the description is given in facsimile form.

Claims (41)

1. A rotary type machine having an external lodgement with a cylindrical cavity in which two compressive parts complementing one another are dynamically located, each of which has several sides, namely a cylindrical part and a blade part, these parts together realizing compression chambers and the number of compressions per one cycle is equal to or greater than the number of sides of said blade part, the cylindrical part is rotatably located in said cylindrical cavity and has an annular shape with a circular outer m profile and an inner hole selected taking into account the shape of the blade part, the blade part being installed in the said inner hole of the cylindrical part, and said complementary compression parts are interconnected and synchronized using a mechanical induction system, one of the compressing parts directly or indirectly connected with the output power shaft, characterized in that the said cylindrical part rotates around the blade part, thus describing the rotational movement, then each of the vertices of the blade part realizes, for one complete cycle of this machine, a circular figure, the centers of these circular figures being equidistant between themselves and located on the periphery and at the same distance from the center of the cylindrical cavity, and the blade part performs circular movement, while maintaining one and the same orientation for its entire course and thus performing a rotational translational motion. 2. The machine according to claim 1, characterized in that the blade part has a retrotation rate equal to the rotation speed of the eccentric, and this blade part is connected to the said cylindrical part. 3. The machine according to claim 1, characterized in that the dynamics of the compressing parts is realized in the opposite way, with the cylindrical part realizing a translational rotational movement, and the blade part realizing a rotational movement. 4. The machine according to claim 1, characterized in that the number of sides of the blade part per unit exceeds the number of sides of the cylindrical part, thus realizing this machine in its postrotative form. 5. The machine according to claim 1, characterized in that the number of sides of the blade part is one less than the number of sides of the cylindrical part, thus realizing this machine in its retrotative form. 6. The machine according to claim 1, characterized in that the blade part is implemented using a plurality of blade parts, each of these parts having its own mechanical induction and each of these parts acts together and synchronously with said cylindrical part. 7. The machine according to claim 1, characterized in that the blade part is formed by a set of straight segments connected in a non-rigid manner using their ends with the possibility of forming a flexible blade structure, called the blade structure, driven inside the said cylindrical part. 8. The machine according to claim 7, characterized in that the movement of the vertices of the said blade structure is an alternating rectilinear movement. 9. The machine according to claim 1, characterized in that the support of one of the compressing parts is set in motion together with a mechanical system containing additional induction, implemented in combination with the initial induction, translating the rotational movement of the compressing part into planetary motion or translating simple planetary motion compressing parts into a complex planetary motion. 10. The machine according to claim 1, characterized in that it forms several systems of compressive parts into a stepped structure, the cylindrical part of one of these parts can serve as its outer surface, as the blade part of the external system of compressive parts, and also serve as its internal surface as a cylindrical part in the internal system of compressive parts. 11. The machine according to claim 1, characterized in that the compressing parts are rotated in opposite directions when they are observed from the outside. 12. The machine according to claim 1, characterized in that the movement of one of the compressive parts is uneven and implements alternately accelerations and decelerations, which can, in the case when this compressive part has a planetary movement, give this movement an oscillatory character, and these accelerator - Slow motion can be implemented using the so-called multi-cam gears. 13. The machine according to claim 1, characterized in that the reference gearing of the mechanical induction of one of the compressing parts is dynamic. 14. The machine according to claim 1, characterized in that the mechanical induction holding the blade part is one of the following inductions: mono-induction, a mechanical system using an intermediate gearing, a mechanical system using multi-induction, a mechanical system using alternative poly-induction, mechanical system using ring gearing, a mechanical system using chain ring gearing, a mechanical system using double internal gearing, mechanical system using heel gearing, mechanical system using gearing, mechanical system using single gearing, mechanical system using central active gearing, mechanical system using inhibited polyinduction, mechanical system using subtractive polyinduction, moreover, these inductions are implemented either with a fixed central support gear either with dynamic and central reference gearing, or with peripheral reference gearing. 15. The machine according to claim 1, characterized in that the induction of the compressing parts share a common element, and this element is an eccentric, or dynamic reference gear mesh of planetary induction, or a blade. 16. The machine according to claim 1, characterized in that the power output shaft is either an eccentric shaft holding the blade compression part, or a shaft holding the cylindrical compression part. 17. The machine according to claim 1, characterized in that it can be used as a compressor machine, a catching machine, a pump, a moving machine, a turbine, a mechanical part of a mechanical turbine, artificial heart or a wind engine. 18. The machine according to claim 1, characterized in that the blade part has an aerodynamic curvature, which allows for the implementation of the transportation of various substances in the machine in the direction from its periphery to its center, from its center to its periphery, from one side of it to the other. 19. The machine according to claim 1, characterized in that the valves and spark plugs are installed on the rotary part or on the blade part. 20. The machine according to claim 1, characterized in that the locations of the valves, spark plugs and other auxiliary devices of this machine are located in the function of material figures and the sequence of implementation of the compression phases. 21. A rotary type machine having an external lodgement with a cylindrical cavity, in which two compressive parts complementing one another are dynamically located, each of which has several sides, namely a cylindrical part and a blade part, these parts realizing compression chambers together, the number of compressions in one cycle it is equal to or exceeds the number of sides of the said blade part, the cylindrical part is rotatably located in the said cylindrical cavity and has an annular shape with a circular n the outer profile and the inner hole, selected taking into account the shape of the blade part, and the blade part is installed in the said inner hole of the cylindrical part, and these complementary compressing parts are interconnected and synchronized using a mechanical induction system, one of the compressing parts directly or indirectly connected with the output power shaft, characterized in that the said cylindrical part rotates around the blade part, thus describing the rotational movement, then when each of the vertices of the blade part realizes, for one complete cycle of this machine, a geometric figure defined by a certain number N of consecutive petals, the center of this geometric figure coinciding with the center of the cylindrical cavity and the number N exceeds two. 22. The machine according to item 21, wherein the part of the mechanical induction, providing the possibility of realizing the positioning of the blade part, is determined as a function of the compressing parts, while the part of the mechanical induction, which provides the ability to control the orientation of the blade part, is determined as a function of said geometric figure. 23. The machine according to item 21, characterized in that the ratio between the speed of rotation of the blade part and the speed of rotation of its eccentric is in the range from 2 / X, where X represents the number of sides of the blade part, to 1/1. 24. The machine according to item 21, wherein the said geometric figure with N petals, described by the blade part, is created by the sequential implementation of the sides of this figure. 25. The machine according to item 21, wherein the compression order in the cycle is implemented by moving the blade part in accordance with the geometric figure, realizing the petals of this figure in a non-sequential manner, and the entire set of petals of this figure is realized as a result of more than one rotation of the blade parts. 26. The machine according to item 21, wherein the dynamics of the compressing parts is realized in the opposite way, and the vertices of the cylindrical part realize the aforementioned geometric figure, and the blade part implements rotational movement. 27. The machine according to item 21, wherein the number of sides of the blade part per unit exceeds the number of sides of the cylindrical part, thus realizing this machine in its postrotative form. 28. The machine according to item 21, wherein the number of sides of the blade part is one less than the number of sides of the cylindrical part, thus realizing this machine in its retro-rotational form. 29. The machine according to item 21, wherein the blade part is implemented using a plurality of blade parts, each of these parts having its own mechanical induction and each of these parts acts together and synchronously with the cylindrical part. 30. The machine according to item 21, wherein the support of one of the compressing parts is set in motion together with a mechanical system containing additional induction, implemented in combination with the main induction, translating the rotational movement of the compressing part into planetary motion or translating simple planetary motion compressing parts into a complex planetary motion. 31. The machine according to item 21, wherein the compressing parts are rotated in opposite directions when they are observed from the outside. 32. The machine according to item 21, wherein the reference gear engagement of the mechanical induction of one of the compressing parts is dynamic. 33. The machine according to item 21, wherein the mechanical induction holding the blade part, is one of the following inductions: single induction, a mechanical system using an intermediate gearing, a mechanical system using polyinduction, a mechanical system using alternative polyinduction, mechanical ring gear system, mechanical ring gear system, double mechanical system internal gearing, mechanical system using heel gearing, mechanical system using gearing, mechanical system using single gearing, mechanical system using central active gearing, mechanical system using inhibited polyinduction, mechanical system using subtractive polyinduction, moreover, these inductions are implemented either with a fixed central supporting gear HAND or dynamic and central support toothing or with a peripheral toothing reference. 34. The machine according A.25, characterized in that the mechanical induction holding the cylindrical part, is one of the following inductions: a mechanical system using single induction, a mechanical system using an intermediate gearing, a mechanical system using polyinduction, a mechanical system using alternative poly-induction, mechanical system using ring gearing, mechanical system using chain ring gearing, fur dual internal gearing system, mechanical system using heel gearing, mechanical system using gearing, mechanical system using single gearing, mechanical system using central active gearing, mechanical system using inhibited polyinduction, mechanical system using subtractive poly-induction, and these inductions are implemented either with fixi ovannym central support toothing or dynamic and central support toothing or with a peripheral toothing reference. 35. The machine according to item 21, characterized in that the induction of the compressing parts share a common element, and this element is an eccentric, or a dynamic supporting gear mesh of planetary induction, or a blade. 36. The machine according to item 21, wherein the power output shaft is either an eccentric shaft holding the blade compression part, or a shaft holding the cylindrical compression part. 37. The machine according to item 21, wherein the induction of the blade part is the so-called downward induction, characterized by a rigid arrangement on the blade part of the peripheral supporting gear engagement, and this gear engagement indirectly or directly induction gear engagement, and this gear the induction engagement is rigidly located in the center of the cylindrical part of the machine or on the axis of this cylindrical part. 38. The machine according to item 21, characterized in that it can be used as a compressor machine, a catching machine, a pump, a moving machine, a turbine, a mechanical part of a mechanical turbine, artificial heart or a wind engine. 39. The machine according to item 21, wherein the blade part has an aerodynamic curvature, which allows for the implementation of the transportation of various substances in the machine in the direction from its periphery to its center, from its center to its periphery, from one side to the other. 40. The machine according to item 21, wherein the valves and spark plugs are installed on the rotary part or on the blade part. 41. The machine according to item 21, wherein the location of the valves, spark plugs and other auxiliary devices of this machine are located in the function of material figures and the sequence of implementation of the compression phases.

Images