DE8912129U1 - Device working with centrifugal force - Google Patents

Description

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Hit centrifugal force working device

The invention relates to a device for changing the absolute value of the centrifugal force in at least one * rotating body with a drive direction having an axis of rotation and driving the body rotating about the axis of rotation.

A point at rest in the rotating reference system (s = o) moves in the inertial system with the speed ω χ s, ie on a circle. In this case, the point is also subjected to a centrifugal force which points radially outwards and has a magnitude of m χ χ ² χ a (m = mass, ω = angular velocity and a = distance from the axis of rotation).

Based on the above prior art, the invention is based on the object of creating a device in which the centrifugal force acting on a rotating body can be influenced in a targeted manner.

The object is achieved according to the invention in that the center of gravity of the body performs a reciprocating movement with respect to the axis of rotation during one of its revolutions about the axis of rotation.

It can be seen that the invention is at least realized when, with constant mass and angular velocity, the distance of the center of gravity from the axis of rotation can be changed

The centrifugal force is a linear function of the distance of the center of gravity from the axis of rotation and can take values between 0 and a maximum that corresponds to the maximum distance of the center of gravity from the axis of rotation.

Further expedient and advantageous embodiments of the invention emerge from the subclaims.

If it is a device with a drive shaft having the axis of rotation ) that runs coaxially to a circular and radially directed running surface, then it is expedient if the drive shaft can be connected in a rotationally fixed manner to at least one connecting rod that projects approximately radially from it, if the connecting rod carries the body that rotates about its axis and rolls on the running surface, if the outer diameter of the body, which is circular in cross-section in the area of its running path, corresponds to the diameter of the circle defined by the running surface and if the center of gravity of the body lies outside its axis of rotation. In this case, the center of gravity of the body moves on a circular involute so that it performs back and forth movements with respect to the axis of rotation, in such a way that the body is at the maximum distance from the axis of rotation in one of its positions, while in another position it is at the minimum distance from the axis of rotation. These two end positions and the axis of rotation lie in a common plane, with the axis of rotation being arranged between the two extreme positions of the center of gravity.

If it is a device in which the running surfaces and tracks form the casing of wheels, then it is practical if the running surface running coaxially with the drive shaft

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Wheel is arranged in a stationary manner if at least two bodies designed as wheels are provided, which are arranged diagonally to one another with respect to the axis of rotation of the drive shaft, and if the maximum and minimum distances of the centers of gravity from the axis of rotation lie in a common plane. In this embodiment of the invention, the bodies consist of cylinders or wheels or are designed in such a way that they have a circular cross-section in the area of the running surfaces and tracks. The radius of the fixed wheel corresponds to the radii of the wheels rotating around this wheel, so that the bodies assume their original position after one revolution around the fixed wheel.

Rotating bodies are those bodies in which the center of gravity is located outside their own axis of rotation. From a physical point of view, rotating bodies are therefore eccentrics that rotate both around their own axis and around the axis of rotation. Since the centrifugal force depends on the distance of the center of gravity from the axis of rotation, its maximum value changes continuously. Assuming that the mass and angular velocity of the body are constant, the body takes on values between a maximum and a minimum during its one rotation around the axis of rotation. If the device has several rotating bodies, e.g. two or four, then each rotating body is subject to its own centrifugal force. If the centers of gravity of the rotating bodies have the same geometry and are evenly distributed around the axis of rotation, then the resultant of the centrifugal forces acts in a certain direction.

Two embodiments of the invention are shown schematically in the drawing and are explained in more detail below. They show

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Fig. 1 a device for generating centrifugal force via a gear,

Fig. 2 is a section along the line II-II of Fig.

Fig. 3 to 6 the individual positions of the center of gravity with reference to the axis of rotation during its rotation around the axis of rotation and the body's own axis,

Fig. 7 shows part of another device for generating centrifugal force, wherein the body slides along a sliding curve,

Fig. 8 is a view of the device according to Fig. 7 in the direction of arrow VIII.

In Figs. 1 and 2, part of a device for changing the absolute value of the centrifugal force in at least one rotating body 4 is shown with a drive device 10 having an axis of rotation 12 and driving the body rotating about the axis of rotation 12. The center of gravity S of the body 4 performs a reciprocating movement with respect to the axis of rotation 12 during one of its revolutions about the axis of rotation 12. The device consists of a bearing block 1 which carries the drive device 10. The drive device 10 is connected to a connecting rod 2 in a rotationally fixed manner via a shaft 5 with a bearing 8. The connecting rod 2 is connected to the body 4 via a bolt 9, whereby the body 4 can be connected to the bolt 9 via a bearing 7. The fixed gear 3 and the body 4, which is also designed as a gear, have the same outer diameter, so that the body 4 can rotate after a

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Rotation around the axis 12 takes the position of origin as shown in Fig. 1 and 2. The distance between the axes 12 and 15 from each other therefore corresponds to the diameter of the gears 3 and 4. The gear 3 is fixed so that the track 13 of the gear 4 rolls on the running surface 17 of the gear 3. The axis of rotation 15 of the gear 4 moves on a circle 14, the radius of which corresponds to the distance between the axes 12 and 15. The gear 4 also rotates around its own axis 15 so that the center of gravity S performs a double circular movement (circular involute).

In Fig. 3 the initial position of the center of gravity is shown with reference

on the rotation axis 12, with the center of gravity being at the maximum distance from the rotation axis 12. If the center of gravity is now

S on circles 13 and 14 and moved in the direction of the arrows,

then he takes positions as shown in Fig. 4,5 and

j 6 are shown. After its further rotation, j the center of gravity S takes the initial position shown in Fig. 3

\ . The position of the center of gravity } S shown in Fig. 5 corresponds to the minimum distance of the center of gravity S from

the rotation axis 12.

In Figs. 7 and 8, a body 20 with weights 21 is shown. The weights 21 have sliding surfaces 34 and are connected to one another via a rod 19. The rod passes through a shaft 5 in which a circular hole is formed for the rod 19. The rod 19 can therefore be easily adjusted in the direction of the double arrow 30. The body 20 is axially symmetrical. If the center of gravity S is in the area of the axis of rotation 12, then no centrifugal force acts on it. The body 20 takes up a fixed position with respect to the axis of rotation 12. If the

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If the center of gravity S is slightly offset with respect to the axis of rotation 12 and the shaft 5 is rotated, a centrifugal force acts on the center of gravity S, causing the distance between the center of gravity S and the axis of rotation 12 to increase until it reaches a maximum value (Fig. 7). In this position, the upper weight 21 works together with a constant curve 32, which converges downwards with respect to the axis of rotation 12. As the rotation continues, the center of gravity S is moved in the direction of the axis of rotation 12 until it is located between the axis of rotation 12 and the lower weight 21. From this point on, a greater centrifugal force acts on the lower weight 21 than on the upper weight 21, so that the rod 19 is moved in the opposite direction. The sliding curve 32 forms the inside of an arm, which has start and run-out surfaces at the end. The bearing block 4, in which the shaft 23 is mounted via bearings 25, is designed to be stationary.

Claims (1)

Georg Vögel Patent Engineer · 7141 Schwieberdingen, Germany Telephone (07150)33271 · Fax (07150)32191 A 7829 - j/w 03 October 1989 Rolf Leidig
Burgstrasse 41 Felbach Expectations Device for changing the absolute value of the centrifugal force in at least one rotating body with a drive device having an axis of rotation and driving the body rotating about the axis of rotation,
characterized, that the centre of gravity (S) of the body (4) performs a reciprocating movement with respect to the axis of rotation (12) during one of its revolutions about the axis of rotation (12). Device according to claim 1 with a rotation axis drive shaft which runs coaxially to a circular and radially directed running surface, characterized, that the drive shaft can be connected in a rotationally fixed manner to at least one connecting rod projecting approximately radially from it, a 7829 ': ^A :2 ·■* : : ·..·: : that the connecting rod (2) carries the body (4) which rotates about its axis (15) and rolls on the running surface (17),
that the outer diameter of the body (4) which is circular in cross-section in the region of its raceway (13) corresponds to the diameter of the circle defined by the running surface (17) and that the centre of gravity (S) of the body (4) lies outside its axis of rotation (15). 3. Device according to claim 1 or 2, in which the running surfaces and tracks are formed by wheels,
characterized, that the wheel (3) running coaxially with the drive shaft (5) is arranged in a fixed position, that at least two bodies designed as wheels are provided, which are arranged diagonally to each other with respect to the axis of rotation of the drive shaft, and
that the maximum and minimum distances of the centers of gravity (S) of the bodies from the axis of rotation (12) lie in a common plane. 4. Device according to one of claims 1 to 3,
characterized, that the axis of rotation (12) lies between the maximum and the minimum distances of the centers of gravity.