ES1148558U - Self-sufficient rocker mechanism (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Self-sufficient mechanism of rocker, for exploitation of the force of acceleration in free precipitation producing movement of diverse uses or energy in any plane of the universe, characterized for being energetically autonomous, perpetuable, scalable -in whole or in parts- and multiplicable - in series, in battery or/and in layers- and for understanding: a support (1); a lath system (2) and a rope system (3) complementary calibrated, in such a way that they maintain an acceleration margin in free precipitation, translated into a force differential; a contact surface (4), which, with the same purpose, allows the rope (3.1) to be de-stressed even with gases or magnetization; at least one use point (5) that can be located in any element, so that its calibration contributes to the perpetuation of the movement and production of the excess, and applied to another external element, optionally a rotor (6); and, optionally also, sensors (7) to assist the self-regulation of the elements and other complements, according to the different uses, such as p. E., tires (8), blades (9) or teeth (10) externally incorporated to the rotor (6) for displacement, norias or self-sufficient fans or insertion in complex mechanisms. (Machine-translation by Google Translate, not legally binding)

Description

FIG. 2: Thumbnail view in an 8 phase cycle

phase: The body (3.2) has already impacted the contact surface (4); the end (2.1), delayed

by its transmission of movement to the wheel (6.2), it is about to touch the stop (1.2), leaving a

stretch of rope (3.1) without tension; and the body (3.3), following its impulse, is about to reach maximum displacement.

3

phase: The body (3.2) is immersed in its base (4.2); the end (2.1) has already reached the top

(1.2); and the body (3.3) its maximum displacement.

3

phase: The body (3.3) begins to precipitate freely accelerating towards the surface of

contact (4) and thus increasing its strength with respect to the body (3.2); while the end (2.1) is

still immersed in its top (1.2). 4 3 phase: The lath system (2) begins its rapid expiration; and immediately the body (3.3) it impacts the contact surface (4) and defeats the body (3.2), which begins its displacement.

S 3 phase: Same as the 13 phase, but on the opposite side.

6 3 phase: Idem 23 phase.

7 3 phase: Idem 33 phase.

phase: Idem 43 phase.

DETAILED EXHIBITION OF REALIZATION MODES

The key to the realization of each Self-sufficient Rocker Mechanism is based on its dimensioning and calibration according to specific location and use; and the development of a project like p. and. a Central also contemplates its multiplicable character - in series, in battery or / and in layers - or Attending to the precision of said task, it is possible to opt for: a computer model in

whose equations include all parameters; a calibrated model for each use; a versatile joint with replaceable, adjustable, and even self-regulating parts with the assistance of sensors (7).

The support (1), which can take the form of "W" with variable heights, consists of: a central bearing (1.1), whose size of radius and whose length of fixation to the lath system (2) - through one or several points of union-condition its stability or delay, its subsequent speed and the curve of deviation of the extremes (2.1) and (2.2) with respect to the center; and two stops (1.2) and (1.3), which,

p. e., with an adjustable "Y" shape or magnetization, they can be calibrated as lath system retarders (2) and with two springs as impellers. The slat system (2) is fixed in greater or lesser length to said central bearing

(1.1) and its ends (2.1) and (2.2) are also calibrated by weight -or attraction to magnetization-, lengths and aerodynamics, in relation to the desired energy surplus and coordination with the rope system (3) in each phase of a cycle.

The rope system (3) consists of the rope (3.1) - rope, rope, chain - and two bodies (3.2) and

(3.3) calibrated according to the same criteria of the previous paragraph, so that the free precipitation, with an end immediately before that of the ribbon (2), has sufficient acceleration length so that, in their respective moment, each body (3.2) and (3.3) add the necessary differential force. Preferably it is also provided with: a pair - or a series - of holes (3.4) and (3.5), calculated at a convenient distance from the ends (2.1) Y (2.2); on them two guide bearings (3.6) and (3.7), which if necessary can also restrain the rope (3.1); and, optionally, to facilitate the calibration - and even with braking action - a third body (3.8) fixed on the rope (3.1) and rolled on the lath system (2). The contact surface (4), in order to loosen the rope (3.1) even with gases - above - or magnetization, is optionally constituted by: a platform (4.1), which can be magnetizing insulator to avoid direct contact or even contain water, depending on the case; base paths

(4.2) and (4.3), which can be two water containers, noise dampers, roll over or motion retarders, as needed; two floats (4.4) and (4.5) for the bodies

(3.2) and (3.3), which can be resized by inflation. In the magnetization option: pairs of magnets (4.6) and (4.7) located under the platform (4.1) and containment sheets (4.8) perpendicular to that The point of use (5) is at least one that can be located in any element, calibrated according to designated energy surplus and use, as p. e .: the central bearing (1.1), for a pendular movement; the stops (1.2) and (1.3) and the bases (4.2) and (4.3), for compression; one of the ends (2.1) Y (2.2) or both, for the activation of another coupled element, such as the rotor (6). Said optional rotor (6) consists of: an axis (6.1) -to obtain magnetized electricity-; a wheel

(6.2) or several -separated or as a cylindrical bovine-, in sync to complete the 360 ° rotation, with at least each lever (6.2.1); and the necessary fasteners / bearings (6.3). The optional sensors (7), also located in any element to assist in its self-regulation, can detect movement, force or pressure, such as the illustrated example of the stops (1.2) and (1.3), which according to presence times would assist in pinching, magnetization or springs. As peculiarities, especially to optimize the weight, both the bodies (3.2) and (3.3) or / and the ends (2.1) Y (2.2) and the surrounding atmosphere can be encapsulated containing different gases, and use an inverted model, with the support (1) in the form of "M". Also, for non-vertical planes and in the absence of gravity, where the force is recreated by the pairs of magnets (4.6) and (4.7), the lath system (2) can be fixed to the central bearing (1.1) by " below ", closer to the contact surface (4). The possibility of sandwiching or burying it is another important aspect to keep in mind.

Claims (1)