The present invention relates generally to field sensors and more particularly to electromagnetic field sensors.
None at this time
The present invention uses high inertia mass(es) to create the possibility of a large (high) inertial reaction force. Firstly the device creates a high-inertia rotational mass as its core operation. Second, the device provides a means or mechanism for creating motion in space of the inertial mass core when it is at high speed (rotational, translational, etc.) Third, the device provides an electromagnetically sensitive detection area comprised of e-m sensitive materials, e-m sensors, rechargeable batteries, e-m or e-s sensitive inert gases, coils, capacitors, or other chemical substances whereby the reaction force can be observed visibly or via other sensor readings (distributed volt-meters, sensors, etc.) when the disruption to the motion of the high inertia mass is precipitated, or in the case of large celestial alignments of nearby matter (sun, Moon, Virgo supercluster, etc.) with the earth and device, these regular small observations can be made with the device whether high inertia mass is disturbed or not (i.e., can be observed from inertia run up and run down alone).
The current embodiment of the device employs 10 small DC voltmeters and these devices read the voltages across the six (6) 1.2V AA rechargeable nickel cadmium battery series strings on each arm—labeled A through H) while remotely transmitting voltage change in the batteries to nearby collection unit. In total 48 AA batteries are used as sensors in this current detector and 4 AA batteries are used to drive the DC pancake motors that are able to create the rotational disturbance to the inertia of the central core of the device.
The batteries serving as the electromagnetically active detection area which fulfill the dual purpose of powering the central DC motors that keep the internal inertial mass rotating in excess of 6,000 rpm or desired rpm, while also responsive to the Machian-like reaction force when a disturbance in the local, high inertia mass is attempted. In previous experiments and smaller embodiments of the device the inventor was able to create instantaneous battery polarity reversal when the Machian field was interacted with in the proximity of the battery/sensor detectors. In order for the effect to manifest the other requirement is that the high inertia device is disturbed in its gyroscopic-like behavior. This can be achieved by hanging the device and altering its position in space via impact, rotation, or movement either internally or externally. Initial devices were rotated externally by the use of rubberized cords. The current device uses DC pancake motor drives connected to the top and bottom of the central inertial core.
For a more complete understanding of the invention, reference is made to the following detailed description in conjunction with the accompanying drawings, in which:
The device acts as a battery system sensor network that monitors and interacts with a Machian inertial reaction field/force while simultaneously creating a discernible transient mass fluctuation and large battery voltage disruption believed to be electromagnetic in nature. The device design is on a spherical shape to interact more effectively with the Machian inertial reaction field/force. The batteries on the 8 arms function both as power supply and sensors by having the batteries in optimum juxtaposition/proximity to the Machian interaction field induced by the challenges to the inertia of the wheel located at the center of the device.
The device Elevation view (
The device's simple electrical connections are shown in these views (
Referring to
The central wheel assembly 28 consists of a central inertia wheel 30 six inches in diameter comprised of three laminated quarter inch aluminum discs with the central disc of a full six inches with the other two discs placed on opposite sides of the full six inches, with hollowed out coverings one inch of the outer wheel, all three discs are secured by fasteners. The axle 32 that attaches to the central disc 30 is supported by bearings (not shown) and driven by the DC motor 34. The central wheel assembly 28 is connected to the pancake motors 24, 26 on the top and bottom of the sphere 10, it is connected using bearings 36, 38 to allow torque spin to be applied to the central inertia wheel assembly 28. Attached to the pancake motors 24, 26 are the eight armatures 12a-h supporting the three (3) battery packs (see battery packs 14c, 16c, 18c, 14g, 16g, 18g) connected in series on each arm, wiring and voltage sensors. All eight arms 12a-h are connected electrically to support balanced operation of the DC motor 34. Turning now to
The external battery ring (i.e., battery rings 14, 16, 18, 20, 22) of the detector has two roles in the operation of the device. First as a power supply to keep the wheel 30 at high inertia when external grid power has been disconnected, the second is as a sensor array by means of the voltage sensors, and the experimental procedure to denote any unexpected or outside normal range of power draw (or voltage fluctuations) in the system. It is important to keep in mind that due to Kirchoff's Laws the absolute voltage measurements are imprecise due to unequal voltages connected to the same bus point of connection, and since batteries will charge and discharge differently the experiment requires detailed pre- and post-voltage measurements for each battery for each experiment.