RU2581509C2 - Rotary mechanism and generator device interacting with same - Google Patents

Abstract

FIELD: mechanisms.

SUBSTANCE: decorative or entertaining product - rotating mechanism - includes a plurality of concentric rotary units having different sizes and able to rotate around a common center of rotation, several liaisons with equal weight to bring them in motion, and at least one connecting link to swivel rotatable connection units with connecting links. Rotatable links can symmetrically push / tow each other. Connecting links and the connecting link are respectively mounted in the sections cooperate with at least some rotating units for energy absorption. Energy is transmitted through the connecting links sections of the interaction on the rotating units for the accumulation and transmission of energy. In terms of small energy losses of the rotating mechanism forms a rock and a rotating device, which can be seen for a long time.

EFFECT: invention aims at achieving new entertaining visual effects.

55 cl, 8 dwg

Description

1. The technical field of the invention

The present invention generally relates to a rotating mechanism and a generator device interacting with it. The rotating mechanism has a precisely calculated weight distribution pattern. After applying an initial force to the rotating mechanism to bring it into rotation, the rotating mechanism can function for a long time, while the generator device is capable of absorbing and storing energy.

2. Description of the Related Art

A traditional decorative or entertaining rotating product, such as a bamboo dragonfly, is manually rotated in order to achieve a visual effect, as well as for entertainment, educational purposes and other functions. However, the rotating product is in contact with the ground or air and, due to friction, gradually changes from a state of rapid rotation to a stationary state. The rotation time of the product varies depending on the product’s own configuration and weight distribution scheme.

The so-called "Newton's pendulum" is another frequently encountered decorative item that obeys the law of conservation of energy. Newton's pendulum includes many metal balls suspended on strings. Initially, metal balls are stationary and are located next to each other. When the first metal ball is raised and then released and allowed to fall to collide with the second metal ball, kinetic energy is sequentially transmitted from the second metal ball to the last metal ball. At this moment, the last metal ball flies up, converting kinetic energy into potential energy. The conversion of kinetic energy into potential energy and vice versa is repeated, so that Newton's pendulum can function for a long time.

The above-described rotating mechanism or decorative product is driven by external force or work, obeying the law of conservation of energy. These decorative products can be modified to increase operating time and expand the range of applications. For example, under conditions of minimal energy loss or energy absorption during operation, a rotating product can function for a longer time according to various schemes to achieve new entertaining visual effects. In addition, a generator device for supplying electrical energy can interact with the rotating mechanism.

SUMMARY OF THE INVENTION

The main objective of the present invention, therefore, is to create a rotating mechanism and a generator device that interacts with it. The rotating mechanism has a complex structure and is able to rotate continuously.

To solve this problem and other tasks, the rotating mechanism includes many concentric rotatable links having different sizes and able to rotate around a single center of rotation, several connecting links having equal weight to bring them into motion, as well as at least one connecting link for the articulation of rotatable links with connecting links. Swivel links can push / tow each other symmetrically. The connecting links and the connecting link are respectively installed in the interaction sections of at least some rotatable links to transform the mutual influence. The energy of the connecting links is transmitted through the interaction sections to the rotatable links and the connecting link to form an energy conversion cycle, as well as energy absorption during this cycle. Under conditions of small energy losses, the rotating mechanism forms a continuously swinging and rotating device, which can be observed for a long time.

In a rotating mechanism, the moment applied to the rotating links changes with the distance between the rotating links and the axis of rotation. In a preferred embodiment, the rotating mechanism includes four metal rings having different sizes. Four metal rings are concentric. When the weight of the link is applied to the rotatable links, a larger moment is applied to the rotatable link having a larger size and spaced a greater distance from the axis of rotation. In this case, the rotating mechanism rotates in the direction of action of the moment applied to the larger rotating link. Accordingly, at least one node of the symmetrical connecting link and the connecting link is located around the concentric rotatable links to create an auxiliary pushing / towing effect and solving problems of ensuring low power loss and continuous rotation.

A generating device interacting with a rotating mechanism is capable of storing energy in the form of electrical energy to extend the operating time of the rotating mechanism.

The present invention will become clearer thanks to the following description and the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

In FIG. 1 is an exploded perspective view of the present invention;

in FIG. 2 is an exploded perspective view of the present invention;

in FIG. 3 is an assembled front view of the present invention;

in FIG. 4 is a front view in accordance with FIG. 3, which presents the principle of operation of the present invention;

in FIG. 5 is a perspective view of the present invention, where two rotating mechanisms are assembled with a single center of rotation or axis of rotation and having a mismatch in angle;

in FIG. 6 is a perspective view where a generating device is connected to an axis of rotation of the present invention;

in FIG. 7 shows a top view in accordance with FIG. 6; and

in FIG. 8 is a perspective view in accordance with FIG. 6, where the energy storage device is further connected to a generator.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Turning to FIG. 1-3. The rotary mechanism 1 of the present invention includes a first rotatable ring 10, a second rotatable ring 11, a third rotatable ring 12, as well as a rotatable disk 13, which can rotate around a single center of rotation or axis of rotation 20. The rotating mechanism 1 of the present invention further includes at least two connecting links 30, 31, 32, 33 connected to the first, second and third rotatable rings 10, 11, 12, as well as to the rotatable disk 13. Rotatable disk 13 has the smallest diameter. The third rotatable ring 12 is located around the rotatable disk 13. The second rotatable ring 11 is located around the third rotatable ring 12, while the first rotatable ring 10 is located around the second rotatable ring 11. The connecting links are symmetrically, at least with an interval of 180 degrees and connected between the above rotatable rings.

The rotary disk 13 is made with a Central hole 130, in which there is a center of rotation or in which the axis of rotation 20 is mounted with the possibility of transmitting drive force. The rotatable disk 13 is additionally made with the first turning points 131, 132 located symmetrically and opposite to each other. The rotary disk 13 is additionally made with symmetrical rotary matching sections 133, 134. The rotary disk 13 is further equipped with first guide plates 135, 136 symmetrically extending outwardly. The outer circumference of the rotary disk 13 is made with the first engagement sections 137, 138. The third rotatable ring 12 is equipped with second outwardly symmetrically extending second guide plates 121, 122 corresponding to the first guide plates 135, 136. The third rotatable ring 12 is further provided with second engagement sections 123, 124 corresponding to the first engagement sections 137, 138. The third rotatable ring 12 is further equipped with outwardly extending connecting plates 125, 126 spaced apart from the second guide plates 121, 122 by a certain angle. The outer circumference of the third rotatable ring 12 is made with the third engagement sections 127, 128. On the front face of the third rotatable ring 12, there are several pushing / towing sections 129. The second guide plates 121, 122 are provided with lead-in slots 1210, 1220 into which the first guide plates 135, 136 are inserted and placed therein.

The inner circumference of the second rotatable ring 11 is made with the fourth engagement sections 110, 111 corresponding to the third engagement sections 127, 128. On the two face surfaces of the second rotatable ring 11, a plurality of first interaction sections 112 are arranged to create a supporting force in the first direction of rotation. In this embodiment, the first interaction sections 112 are L-shaped plates bent in one single direction.

On the two face surfaces of the first rotatable ring 10, a plurality of second interaction sections 101 are arranged corresponding to the first interaction sections 112 to create a supporting force in a second direction of rotation opposite to the first direction of rotation. The number of second interaction sections 101 is equal to the number of first interaction sections 112. The second interaction sections 101 may have the same shape as the first interaction sections 112.

In accordance with the above scheme, the first guide plates 135, 136 of the rotatable disk 13 are inserted into the insertion grooves 1210, 1220 of the second guide plates 121, 122. The free ends of the first guide plates 135, 136 are pivotally connected to the second rotational ring 11. The free ends of the second guide plates 121 122 of the third rotatable ring 12 are pivotally connected on the first rotational ring 10. The free ends of the connecting plates 125, 126 are also pivotally connected on the first rotational ring 10. The engagement sections 110, 111, 127, 128, 123, 124, 137, 138 are meshing with each other by means of links 14 gearing.

Each of the connecting links 30, 31, 32, 33 contains a connecting rod 302, 312, 322, 332, as well as a weighting body 301, 311, 321, 331 connected to the outer end of the connecting rod. Weighting materials may be placed in weighting bodies 301, 311, 321, 331 to control their weight with microscopic precision. The weighting bodies 301, 311, 321, 331 are assembled with rotatable links and are essentially located around the first rotatable ring 10. Coupling rods 302, 312, 322, 332 are made with through holes 303, 313, 323, 333 near the inner ends of the binders rods 302, 312, 322, 332 corresponding to the center of rotation or axis of rotation 20 for articulating the connecting rods 302, 312, 322, 332 with the center of rotation or axis of rotation 20. In addition, the connecting rods 302, 312, 322, 332 are respectively made with stabilizing points 304, 314, 324, 334 for articulating with the first pivot points 131, 132 of the rotation of the rotatable disk 13. The inner ends of some symmetrical connecting rods 302, 322 additionally have continuing in the outer direction of the sections 3021, 3221 for articulating with the second rotatable ring 11. In addition, the various sections of the tie rods 302, 312, 322, 332 are respectively locked in the first and second interaction sections 112, 101. Numerous rod-shaped restrictive links 34 are freely seated through the second interaction sections 101 and are attached to the tie rods 302, 312, 322, 332. The rod-shaped restrictive links 34 are further fixedly mounted through the first interaction sections 112.

In a preferred embodiment, to maintain the relative position of the respective components of the rotary mechanism 1 in a sufficiently stable state during operation between the rotary matching sections 133, 134 of the rotatable disk 13 and the push / pull sections 129 of the third rotatable ring 12, as well as between the limiting links 34 and the center of rotation or a rotational axis 20 provides multiple elastic links 40, 41. The elastic links 40, 41 serve to provide an elastic push effect to prevent donkey The combination of the respective components and the gaps between them so as to stabilize the operation of the rotating mechanism 1. In addition, the elastic link 40 between the rotary matching sections 133, 134 of the rotatable disk 13 and the push / pull sections 129 of the third rotatable ring 12 serves to store energy in the form of energy elasticity in the rotation process to facilitate the rotation of the third rotatable ring 12. In addition, the elastic link 41 between the restrictive links 34 and the center of rotation or axis of rotation 20 serves to storing energy in the form of elastic energy during rotation for facilitating rotation of the first rotatable ring 10 so as to increase its ability to continuously rotate.

Turning to FIG. 5. In a preferred embodiment of the present invention, two rotating mechanisms are assembled having a single center of rotation or axis of rotation 20 and an angle mismatch. In this case, the inertia of rotation can be gradually increased.

Turning now to FIG. 6-8. An operating device or generator device 5 is additionally connected to the center of rotation or axis of rotation 20 for converting stored energy into electrical energy and making full use of natural forces as a source of useful energy. The generator device 5 includes a coupling wheel (or gear) 50 mounted in the center of rotation or on the axis of rotation 20. The coupling wheel 50 is connected to an actuator 51 (such as an engine) and a connecting part of the generator 52. The generator 52 is further connected to an electric control device 53, which is electrically connected to an electric converter 54 (such as a rectifier or transformer), as well as an energy storage device 55 (such as a battery). The energy storage device 55 may further supply electrical energy to external devices or an actuator 51 via an electrical converter 54. In the center of rotation or on the axis of rotation 20, as well as on the central axis of rotation 522 of the generator 52, sensors 56 are arranged for measuring rotation speed for repeated turning on the actuator 51 at the required time and maintaining the optimal rotation speed for generating energy. The energy storage device 55 may provide the necessary power to the actuator 51.

The above embodiments are used only to illustrate the present invention and do not limit its scope. Various changes to the above embodiments may be proposed without departing from the spirit of the present invention.

Claims (55)

1. A rotating mechanism comprising at least two concentric rotatable links having different sizes and capable of rotating around a single center of rotation or axis of rotation, as well as at least one pair of connecting links connected between said concentric rotatable links, at least on a large rotatable link and a small rotatable link there are interaction sections in different directions of rotation, while the connecting links are blocked in the interaction sections, and projections of interaction large size of the rotating unit are designed to provide support for the efforts of the connecting links, rotate and descend, while the interaction of small-sized section of the rotating unit are designed to provide support for the efforts of the connecting links, rotate and rise. 2. The mechanism of claim 1, wherein the rotatable links include a first rotatable ring, a second rotatable ring, a third rotatable ring, and a rotatable disk, which are concentric and decreasing in size, each of the connecting links consists of a connecting rod and the weighting body connected to the connecting rod, wherein the interaction sections located on the first rotatable ring are the second interaction sections, the interaction sections located on the second rotatable ring are the first interaction sections, the weighting bodies are arranged around the first rotatable ring, the connecting rods are made with through holes near the inner ends of the connecting rods for articulating the connecting rods with a rotation center or axis of rotation, and the connecting rods are additionally made with stabilizing points for articulating with the first turning points rotatable disk, while the connecting rods are locked in various sections of the interaction of the rotatable links. 3. The mechanism of claim 2, wherein the inner ends of the tie rods further have outwardly extending sections for articulating with the second rotatable ring. 4. The mechanism according to claim 2, wherein the rotatable disk is made with a central hole in which the center of rotation or the axis of rotation are mounted with the possibility of transmitting drive force, while the rotatable disk, the third rotatable ring and the second rotatable ring are engaged with each other. 5. The mechanism of claim 4, wherein the rotatable links are engaged with meshing sections engaged with each other by means of meshing links. 6. The mechanism according to paragraphs. 2, 3, 4 or 5, in which the rotatable disk has at least two first guide plates symmetrically extending outwardly, the free ends of the first guide plates being pivotally connected to the second rotatable ring. 7. The mechanism of claim 6, wherein the third rotatable ring has second guide plates symmetrically extending opposite in the outward direction corresponding to the first guide plates, wherein the second guide plates are provided with lead-in grooves into which the first guide plates are inserted, with free ends the second guide plates are pivotally connected on the first rotatable ring. 8. The mechanism according to paragraphs. 2, 3, 4 or 5, in which the third rotatable ring has a second guide plate symmetrically extending opposite in the outward direction, the free ends of the second guide plate being pivotally connected to the first rotatable ring. 9. The mechanism according to paragraphs. 2, 3, 4 or 5, in which the third rotatable ring further has connecting plates symmetrically opposed in the opposite direction, the free ends of the connecting plates being pivotally connected to the first rotatable ring. 10. The mechanism according to claim 6, in which the third rotatable ring further has a connecting plate symmetrically opposed in the opposite direction, the free ends of the connecting plate pivotally connected to the first rotatable ring. 11. The mechanism of claim 7, wherein the third rotatable ring additionally has connecting plates symmetrically opposed in the opposite direction, the free ends of the connecting plates being pivotally connected to the first rotatable ring. 12. The mechanism according to claim 8, in which the third rotatable ring further has a connecting plate symmetrically opposed in the opposite direction, the free ends of the connecting plate pivotally connected to the first rotatable ring. 13. The mechanism according to paragraphs. 2, 3, 4 or 5, in which the pushing / towing sections are located on the third rotatable ring, and the rotary matching sections are located on the rotatable disk, while when the third rotatable ring is assembled with the rotatable disk, between the rotary matching sections and the pushing / towing sections mounted elastic links. 14. The mechanism according to claim 6, in which the pushing / towing sections are located on the third rotatable ring, and the rotary matching sections are located on the rotatable disk, while when the third rotatable ring is assembled with the rotatable disk, between the rotary matching sections and the pushing / towing sections mounted elastic links. 15. The mechanism according to claim 7, in which the pushing / towing sections are located on the third rotatable ring, and the rotary matching sections are located on the rotatable disk, while when the third rotatable ring is assembled with the rotatable disk, between the rotary matching sections and the pushing / towing sections mounted elastic links. 16. The mechanism according to claim 8, in which the pushing / towing sections are located on the third rotatable ring, and the rotary matching sections are located on the rotatable disk, while when the third rotatable ring is assembled with the rotatable disk, between the rotary matching sections and the pushing / towing sections mounted elastic links. 17. The mechanism according to claim 9, in which the pushing / towing sections are located on the third rotatable ring, and the rotary matching sections are located on the rotatable disk, while when the third rotatable ring is assembled with the rotatable disk, between the rotary matching sections and the pushing / towing sections mounted elastic links. 18. The mechanism of paragraphs. 2, 3, 4 or 5, in which the various sections of the connecting rods are respectively locked in the first and second interaction sections, the restrictive links freely seated through the second interaction sections and attached to the connecting rods, while the elastic links are pivotally mounted between the restrictive links and the center of rotation or an axis of rotation, the first ends and second ends of the elastic links respectively acting on the limiting links and the center of rotation or the axis of rotation. 19. The mechanism according to p. 18, in which the restrictive links are stationary through the first interaction sections, each elastic link has a center of rotation, and the centers of rotation of the elastic links are mounted on the restrictive links. 20. The mechanism according to claim 6, in which the various sections of the connecting rods are respectively locked in the first and second interaction sections, and the restrictive links are freely seated through the second interaction sections and are attached to the connecting rods, while the elastic links are pivotally mounted between the restrictive links and the center of rotation or an axis of rotation, the first ends and second ends of the elastic links respectively acting on the limiting links and the center of rotation or the axis of rotation. 21. The mechanism according to claim 7, in which the various sections of the connecting rods are respectively locked in the first and second interaction sections, and the restrictive links are freely seated through the second interaction sections and are attached to the connecting rods, while the elastic links are pivotally mounted between the restrictive links and the center of rotation or an axis of rotation, the first ends and second ends of the elastic links respectively acting on the limiting links and the center of rotation or the axis of rotation. 22. The mechanism according to claim 8, in which the various sections of the connecting rods are respectively locked in the first and second interaction sections, and the restrictive links are freely seated through the second interaction sections and are attached to the connecting rods, while the elastic links are pivotally mounted between the restrictive links and the center of rotation or an axis of rotation, the first ends and second ends of the elastic links respectively acting on the limiting links and the center of rotation or the axis of rotation. 23. The mechanism according to claim 9, in which the various sections of the connecting rods are respectively locked in the first and second interaction sections, the restrictive links freely seated through the second interaction sections and attached to the connecting rods, while the elastic links are pivotally mounted between the restrictive links and the center of rotation or an axis of rotation, the first ends and second ends of the elastic links respectively acting on the limiting links and the center of rotation or the axis of rotation. 24. The mechanism according to p. 13, in which the various sections of the connecting rods are respectively locked in the first and second sections of the interaction, and the restrictive links are freely seated through the second interaction sections and are attached to the connecting rods, while the elastic links are pivotally mounted between the restrictive links and the center of rotation or an axis of rotation, the first ends and second ends of the elastic links respectively acting on the limiting links and the center of rotation or the axis of rotation. 25. The mechanism according to paragraphs. 2, 3, 4 or 5, in which the elastic link is pivotally mounted between the rotatable disk and the third rotatable ring, wherein the first end and the second end of the elastic link respectively exert a pushing force on the third rotatable ring and on the rotatable disk. 26. The mechanism according to paragraphs. 1, 2, 3, 4 or 5, in which multiple rotating mechanisms, each of which consists of rotating links and connecting links, are installed in the center of rotation or on the axis of rotation. 27. The mechanism according to claim 6, in which multiple rotating mechanisms, each of which consists of rotatable links and connecting links, are installed in the center of rotation or on the axis of rotation. 28. The mechanism according to claim 7, in which multiple rotating mechanisms, each of which consists of rotatable links and connecting links, are installed in the center of rotation or on the axis of rotation. 29. The mechanism according to p. 8, in which multiple rotating mechanisms, each of which consists of rotatable links and connecting links, are installed in the center of rotation or on the axis of rotation. 30. The mechanism according to p. 9, in which multiple rotating mechanisms, each of which consists of rotatable links and connecting links, are installed in the center of rotation or on the axis of rotation. 31. The mechanism according to p. 13, in which multiple rotating mechanisms, each of which consists of rotatable links and connecting links, are installed in the center of rotation or on the axis of rotation. 32. The mechanism according to p. 18, in which multiple rotating mechanisms, each of which consists of rotatable links and connecting links, are installed in the center of rotation or on the axis of rotation. 33. The mechanism according to p. 25, in which multiple rotating mechanisms, each of which consists of rotatable links and connecting links, are installed in the center of rotation or on the axis of rotation. 34. A generator device that interacts with a rotating mechanism, the rotating mechanism includes at least two concentric rotatable links having different sizes and able to rotate around a single center of rotation or axis of rotation, as well as at least one pair of connecting links connected between the said concentric rotatable links, while at least on the large rotatable link and the small rotatable link there are interaction sections in different directions growth, while the connecting links are blocked in the interaction sections, moreover, the interaction sections of the large-sized rotational link serve to provide a supporting force for the connecting links that rotate and lower, while the interaction sections of the small-sized rotational link serve to provide a supporting force for the connecting links making rotation and rise. 35. The generator device according to p. 34, in which the rotatable parts include a first rotatable ring, a second rotatable ring, a third rotatable ring, and a rotatable disk, which are concentric and decreasing in size, each of the connecting links consists of a connecting rod and a weighting body connected to the connecting rod, wherein the interaction sections located on the first rotatable ring are the second interaction sections, the interaction sections located on the second rotatable ring, etc. constitute the first interaction sections, weighting bodies are located around the first rotational ring, the connecting rods are made with through holes near the inner ends of the connecting rods for articulating the connecting rods with a rotation center or axis of rotation, and the connecting rods are additionally made with stabilizing points for articulating with the first turning points of the rotational disk, while the connecting rods are locked in various sections of the interaction of the rotatable links. 36. The generator device according to p. 35, in which the inner ends of the connecting rods additionally have continuing in the outer direction of the section for articulation with a second rotatable ring. 37. The generator device according to p. 35, in which the rotary disk is made with a Central hole in which the center of rotation or the axis of rotation are mounted with the possibility of transmitting drive forces, while the rotatable disk, the third rotatable ring and the second rotatable ring are engaged with each other . 38. The generator device according to paragraphs. 35, 36 or 37, in which the rotatable disk has at least two first guide plates symmetrically extending outwardly, the free ends of the first guide plates being pivotally connected to the second rotatable ring. 39. The generator device according to paragraphs. 35, 36 or 37, in which the third rotatable ring has a second guide plate symmetrically extending opposite in the outward direction, the free ends of the second guide plate being pivotally connected to the first rotatable ring. 40. The generator device according to paragraphs. 35, 36 or 37, in which the third rotatable ring further has connecting plates symmetrically opposed opposite in the outward direction, the free ends of the connecting plates being pivotally connected to the first rotatable ring. 41. Generator device according to claims 35, 36 or 37, in which the pushing / towing sections are located on the third rotatable ring and the rotary matching sections are located on the rotatable disk, wherein when the third rotatable ring is assembled with the rotatable disk, between the rotary matching sections and the pushing / towing sections elastic links installed. 42. The generator device according to paragraphs. 35, 36 or 37, in which the various sections of the connecting rods are respectively locked in the first and second interaction sections, the restrictive links freely seated through the second interaction sections and attached to the connecting rods, while the elastic links are pivotally mounted between the restrictive links and the center of rotation or axis rotation, and the first ends and second ends of the elastic links, respectively, act on the limiting links and the center of rotation or the axis of rotation. 43. The generator device according to paragraphs. 35, 36 or 37, in which the elastic link is pivotally mounted between the rotatable disk and the third rotatable ring, while the first end and the second end of the elastic link respectively exert a pushing force on the third rotatable ring and on the rotatable disk. 44. The generator device according to paragraphs. 35, 36 or 37, in which multiple rotating mechanisms, each of which consists of rotating links and connecting links, are installed in the center of rotation or on the axis of rotation. 45. The generator device according to paragraphs. 35, 36 or 37, in which the generating device comprises a coupling wheel mounted in the center of rotation or on the axis of rotation, the coupling wheel being connected to the actuator and the generator. 46. The generator device according to paragraphs. 35, 36 or 37, wherein the generator is further connected to an electrical control device, wherein the electrical control device is electrically connected to an energy storage device. 47. The generator device according to claim 45, wherein the generator is further connected to an electric control device, wherein the electric control device is electrically connected to an energy storage device. 48. The generator device according to claim 46, in which the electrical control device is additionally electrically connected to the electrical conversion device. 49. The generator device according to claim 47, in which the electrical control device is additionally electrically connected to the electrical conversion device. 50. The generator device according to claim 46, in which the electrical control device is additionally electrically connected to the actuator. 51. The generator device according to claim 47, in which the electrical control device is additionally electrically connected to the actuator. 52. The generator device according to claim 48, in which the electrical control device is additionally electrically connected to the actuator. 53. The generator device according to p. 50, in which the electrical control device is electrically connected to the actuator through an electrical conversion device. 54. The generator device according to claim 51, in which the electrical control device is electrically connected to the actuator through an electrical conversion device. 55. The generator device according to claim 52, wherein the electrical control device is electrically connected to the actuator via an electrical converter device.

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