DE102017003819A1 - DagKard pendulum - Google Patents

Abstract

Dagkard pendulum describes a construction, which compensates for the occurring energy loss during a pendulum movement by the extension of the pendulum distance with the help of the tightening force of permanent magnets. The adhesion of the magnets is terminated by means of buoyancy force mechanically or by reversing a magnetic side to repel the Megnete. This process is repeated until the fatigue of the magnets or due to material wear.

Description

The invention relates to a construction for maintaining a pendulum motion by the interaction of momentum, acceleration, attractive and repulsive forces of permanent magnets and buoyancy force.

State of the art

To maintain the pendulum movements z. B. in grandfather clocks is obtained by spring force or the drop of weights. After completion of the process, the movement is made possible by manually establishing the initial state again. A permanent pendulum-like movement with a circular flow can be brought about by gravitational forces.

The claim of the invention set forth is based on the problem of maintaining a pendulum motion until the inserted permanent magnets are fatigued.

The construction according to the invention will be explained in more detail with reference to an embodiment and associated schematic drawings.

1 shows the construction of a pendulum with attracting permanent magnets in pendulum deflection end area and a buoyancy unit located near the pendulum bearing as power source for releasing the permanent magnets. The pendulum movement is triggered once manually, so that the pendulum on one side with the pendulum magnet ( 5 ) of the corresponding magnetic stop ( 10 ) is attracted and held. The residual momentum in the end area of the deflection plus the attraction of the differently poled permanent magnets ( 5 ) and ( 10 ) cause the attachment situation to reach outside the end point to be reached only by the pendulum swing. The in the liquid container ( 2 ) rotatably mounted buoyancy bodies ( 3 ) is due to the displacement of the liquid ( 11 ) of inertia, with the result that the buoyancy body ( 3 ) only after the magnets have adhered ( 5 ) and ( 10 ) and its buoyancy force via the traction cable ( 9 ) to the shears ( 7 ). The induced extension of the scissor arms ( 7 ) releases the pendulum magnet ( 5 ) from the magnetic stop ( 10 ) and accelerates it to such an extent that the pendulum absorbs momentum and in turn into the attraction region of the opposing magnet stop ( 10 ) vibrates. The residual power still present in the end area and the increasing magnetic force during the approach are sufficient to compensate for the normal loss of travel of the pendulum and in turn cause the pendulum to stop ( 10 ) to keep. After docking moves - the buoyancy body ( 3 ) around its pivot point and after crossing its vertical upward and in turn triggers the pendulum magnet ( 5 ) from the magnetic stop ( 10 ). Continuous pendulum motion is made possible by compensating for the lost distance of each pendulum motion by means of the permanent magnets' attraction force and releasing them from their fixed position by buoyancy force. Neglecting the wear of the material and the loss of fluid, the pendulum movement takes place until the fatigue of the permanent magnets.

LIST OF REFERENCE NUMBERS

1

axis of rotation

2

liquid container

3

buoyancy

4

pendulum

5

Pendulum magnet (positive)

6

bob

7

scissors kick

8th

idler pulley

9

Pulling rope for shearing shears

10

Magnetic stop (negative)

11

liquid

Claims (3)

Dagkard pendulum, characterized in that a pendulum motion is increased by the attraction of permanent magnets and the reduction of the pendulum swings is thereby more than compensated. Dagkard pendulum after Claim 1 , characterized in that the adhering permanent magnets are released by the action of buoyancy force. Dagkard pendulum after Claim 1 and 2 , characterized in that the pendulum motion is extended by attracting permanent magnets and with the help of buoyancy force one side of the differently polarized magnets is exchanged for Gleichgepolte magnets and consequently the pendulum motion is accelerated.

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