PATENT CLAIM ANALYSIS

Application Number: 15932502
Application Type: Utility
Filing Date: 2018-03
Publication Date: 2019-02
Patent Classification: ["137", "247490"]

Abstract:
A forever technologies ultimate energy device affecting energy dynamics planet genesis, gravity fields do: embodies sui generis boundaries perfections in ultimately compact structures, discerns, distinguishes forms of cycling energy genres, effectuates an energy form respective directionality and embraces energy cycling maximum conductance, or maximum ultimate Heat Rate efficiency or maximally, ultimately short paths-of-passage lengths' sums comprising a least sum (PPLSLS).

Claim (Index 8):
A three phase, four pole induction motor of ultimately compact device utilizes a stator, a yoke, a plurality of stator teeth, a plurality of stator slots, a maximum ultimate copper fill by a hexagonal barely rectangular cross-sectional area of wound coil rows, wound coil columns wound precisely concentric wire coils, the coils, comprising:\n a maximum ultimate number of wound wire coils of a magnet wire, the magnet wire, in each of the slots; a least length of the wire length in the maximum ultimate number of the wound precisely concentric wire coils in a magnetic pole, a magnetic pole pair and pairs of magnetic poles; a column of pre-insulated coils, wherein the wound coil columns in position press and wedge in grooves and ridges of concentric wire coils in place and/or into insulation in base of the slot; a row of pre-insulated coils, wherein the wound coil columns of the wound coil rows wedge the row each outermost coil into grooves and ridges in insulation of respective walls of each slot; a volume of an electrical insulation in the coils of stator slots, wherein the maximum ultimate copper fill compresses the volume of the electrical insulation in a plurality of the stator slots; a layer bundle, wherein perimeter coils of the layer bundle are pressing on and wedging into groves and ridges in the electrical insulation of the slot; a coil, a coil pair and coil pairs, wherein the maximum ultimate number of the wound precisely concentric wire coils maximize the maximal ultimate number of the wound wire coils and, also, maximize the maximum ultimate copper fill in the slot; a winding coils group of the wound precisely concentric wire coils of a dual layer bundle and a perimeter two surfaces of compress volume of an insulation lining the slot and surface perimeter of the slot affects an absolute maximum surface area of respective interacting perimeter surfaces; a thermal energy most direct outflow path flows from maximum perimeter surfaces of each of the coils and from surfaces of slot perimeters within a stator yoke; a rectangular hexagon cross-sectional area of the coils and the slots absolutely maximized respective perimeters surface areas maximized heat energy outflow conductance; a structure configuration of the slot maximized respective electrical, thermal, electromagnetic energy cycling comprising the slot sui generis surfaces boundaries of the structure configuration; a compacted configuration slot compacting the slot cross-sectional area, in turn, the steel laminations required a stator diameter size and, in turn, diameter size of the yoke, the motor; a compacted slot cross-sectional area, in turn, minimized weight of the induction device; wherein, the motor, the induction device, the induction motor, the ultimate induction device is one and the same device; wherein, the layer bundle of the wound precisely concentric wire coils, the compacted columns of the wound wire coils of the layer bundle compacts the wound coil rows of the layer bundle; wherein, the wound precisely concentric wire coils compress a thickness of an electrical insulation of the slot, compress a flexible coat portion of a pre-insulation insulation of the wound coil rows to a least needed insulation thickness in the layer bundle and an insulation lining the slot to maximize outflowing heat energy conductance of the coils and of the stator slots; wherein, the hexagonal barely rectangular cross-sectional area of the wound coil rows, wound coil columns wound precisely concentric wire coils comprising said wires coils, a wire coil an absolute maximum surface area that conducts/transfers heat energy in a radial direction; wherein, a biaxial compression of a compressed volume of an electrical insulation in the slot affects an ultimately compact volume, the ultimately compact structure of the slot; wherein, a cross-sectional area of a hexagonal barely rectangular cross-sectional area a conforming to the equal entirely round cross-sectional area affecting a significant increase in the conductance of a heat energy dissipation increased conductance of cycling electrical energy and decreased a rising temperature increase by the heat energy dissipation of cycling heat energy; wherein, the cross-sectional area of the hexagonal barely rectangular cross-section conforming to the equal entirely round cross-sectional area affecting the significant increase in the conductance of the heat energy dissipation, the increased conductance of the cycling electrical energy, a decreased rising temperature increases increase cycling electromagnetic flux density; wherein, the cross-sectional area of the hexagonal barely rectangular cross-section conforming to the equal entirely round cross-sectional area an increase in electrical energy cycling transfer to electromagnetic flux density cycling increases Heat Rate efficiency of cycling energies transfer; wherein, the cross-sectional area of the hexagonal barely rectangular cross-sectional area of the wound coil rows in each of the stator slots winds concentric without a torsional twisting; wherein, the cross-sectional area of the hexagonal barely rectangular cross-sectional area of the wound coil rows in each of the stator slots winding concentric without the torsional twisting in the stator slots minimizes the torsional twisting on outside of the stator slots and minimizes the torsional twisting of the wire coil and the winding layer; wherein, the cross-sectional area of the hexagonal barely rectangular cross-section no torsional twisting in the slots and torsional minimized twisting outside of the slots engenders compressed insulation volume maximized thermal energy conductance maximized electrical energy conductance; wherein, the maximum ultimate copper fill, a maximum coil number, a compressed volume of insulation thicknesses, a maximum conductance of electrical energy, a maximum conductance of thermal energy respective cycling yield an electromagnetic maximum torque and a mechanical maximum torque at relatively low a slot temperature; wherein, the structure configuration of the slot maximized respective electrical, thermal, electromagnetic energy cycling comprising the slot sui generis surfaces boundaries of the structure configuration comprising energy specific directionalities preferred directions; wherein, electrical insolation in the slot, in the coil, in the coil pair, in the coil pairs comprises the compressed insulation volume least needed thicknesses of electrical insulation least needed volume in insulation coat of the wire windings of the coils and the insulation lining of the stator teeth; and, wherein, 60 slot arrangement associated with the yoke illustrates the stator of the present invention; and, the three phase, four pole induction motor of ultimately compact device further comprises a rotor yoke thickness of a rotor yoke comprising:\n a plurality of rotor teeth which extend radially and outwardly away from a rotor center axis; \n a common tooth length of the plurality of the rotor teeth: \n wherein each tooth of the plurality of the rotor teeth has two sides; \n wherein each pair of the rotor teeth has the side surfaces parallel; \n wherein the plurality of the rotor teeth comprises the side surfaces in parallel; \n wherein each pair of the rotor teeth embodies a rotor tooth slot; \n wherein a rotor bridge seals the rotor tooth slot, therein, affecting a surface of the air gap; and, \n wherein, the illustrated example shows 72 rotor teeth.

Metadata:
- Claim Count in Document: 53.0
- Percentile: 90.0
- Lexical Diversity: 1.24561
- Patent Class: 137.0
- Transitional Phrase Type: open
- Component Type: 1
- Foreign Priority: True
- Related Applications: ['13074841', '12370082', '13670429', '11836876', '11295888']

Analysis Scores:
- 35 USC 101 Eligibility (BERT): 0.7848550763538672
- 35 USC 102 Novelty (BERT): 0.4507428896589796
- Combined Prediction Score: 0.7514438576843784
- Mean Citation Score: 127.630604
- Max Citation Score: 131.79463
- Similarity Product: 100.4017135662824

Labels:
- Claim Label 101: 1
- Claim Label 102: 1
- Claim Label 103: 1
- Claim Label 112: 0
- Combined Label: 1
- Label 101 Adjusted: 1

Dataset: test