TITLE OF THE INVENTION: A POWER ENHANCER 
FILED OF THE INVENTION
The present disclosure generally relates to power enhancers. Specifically, it relates to power enhancers that do not depend on natural resources such as wind energy or solar energy.
BACKGROUND OF THE INVENTION
Power enhancers that depend on natural resources are useful in areas that have abundance of natural resources. For instance, power enhancers that utilize wind energy or solar energy facilitate generation of power in places that are blessed with high availability of wind and sun, respectively. 
However, such power enhancers have several drawbacks. First, they are of little use in places that have limited natural resources. Second, the initial cost to install such power enhancers is extremely high. Likewise, their maintenance costs are also quite high. Third, they cannot be relied upon to generate consistent power. Fourth, the conversion efficiency of such enhancers is comparatively low.
Due to the aforementioned drawbacks, power generation using such power enhancers is costly.
There is, therefore, a need in the art for a power enhancer that does not depend on natural resources.

There is, therefore, a need in the art for a power enhancer that has low installation and maintenance costs.

There is, therefore, a need in the art for a power enhancer that generates consistent power and can be relied upon at all times.

SUMMARY OF THE INVENTION
A power enhancer is disclosed. The power enhancer comprises a motor that comprises a first shaft; a first power cable that transmits power from a socket to the motor; a first gear; a second gear that is coupled with a first end of a second shaft; a third gear that is coupled with a second end of the second shaft; a plurality of gears that is in contact with the third gear to achieve a greater speed than torque, wherein each gear in the plurality of gears is associated with a corresponding permanent magnet generator; an output cable that is associated with each permanent magnet generator; a multi-connector that receives power from each permanent magnet generator through the output cable; a rectifier that converts DC from the multi-connector to AC; a cable that transmits AC from the rectifier to a UPS; a second power cable and a third power cable that transmit power from the UPS for storing in a battery; and a fourth power cable that transmits power from the UPS to the socket via a plug for immediate utilization. 
The first gear, the second gear, the third gear, and the plurality of gears are configured in appropriate ratios for enhancing the output power.
The disclosed power enhancer does not depend on natural resources, has low installation and maintenance costs, and generates consistent power.
BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 illustrates an embodiment of a power enhancer, in accordance with the present disclosure
Figure 2 illustrates a rear view of an embodiment of a power enhancer, in accordance with the present disclosure
DETAILED DESCRIPTION OF THE INVENTION
Throughout this specification, the use of the word "comprise" and variations such as "comprises" and "comprising" may imply the inclusion of an element or elements not specifically recited.
A power enhancer is disclosed. As illustrated in Figures 1 and 2, the power enhancer comprises a motor (1) comprising a first shaft (2); a first power cable (3) that transmits power from a socket (29) to the motor (1); a first gear (4) that is coupled to the first shaft (2), said first gear (4) receiving power from the motor (1) through the first shaft (2); a second gear (8) that is meshed with the first gear (4), said second gear (8) being coupled with a first end of a second shaft (11); a third gear (13) that is coupled with a second end of the second shaft (11); a plurality of gears (14), said plurality of gears (14) being in contact with the third gear (13) to achieve a greater speed than torque, wherein each gear in the plurality of gears (14) is associated with a corresponding permanent magnet generator (16); an output cable (17) that is associated with each permanent magnet generator (16), said output cable (17) transmitting power from each permanent magnet generator (16) to a multi-connector (20) for cumulative power generation; a rectifier (21) that converts Direct Current (DC) from the multi-connector (20) to Alternate Current (AC); a cable (22) that transmits Alternate Current (AC) from the rectifier (21) to a Uninterruptible Power Supply (UPS) (23); a second power cable (25) and a third power cable (26) that transmit power from the UPS (23) for storing in a battery (24); and a fourth power cable (27) that transmits power from the UPS (23) to the socket (29) via a plug (28) for immediate utilization.
The first shaft (2) is supported on a first stand (5) through a first bearing (6) that facilitates the frictionless rotation of the first shaft (2).
The motor (1) is stabilized on a second stand (7).
The first end of the second shaft (11) is supported on a third stand (9) through a second bearing (19) and the second end of the second shaft (11) is supported on a fourth stand (12) through a third bearing (10). The second bearing (19) and the third bearing (10) facilitate the frictionless rotation of the second shaft (11).
Each gear in the plurality of gears (14) is coupled with a fifth stand (18) through a corresponding nut (15).
Depending on the power requirement, the first gear (4), the second gear (8), the third gear (13), and the plurality of gears (14) are configured in appropriate ratios for stepping up or enhancing the output power.
In an embodiment of the present disclosure, each permanent magnet generator (16) has a rating of 12 Volts.
In yet another embodiment of the present disclosure, each permanent magnet generator (16) has a rating of 24 Volts.
In yet another embodiment of the present disclosure, the motor (1) is a 1HP motor.
The motor (1) drives the first gear (4), which drives the second gear (8), which is smaller in diameter than the first gear (4). The second gear (8) drives the third gear (13), which is bigger in diameter than the first gear (4) and the second gear (8), through the second shaft (11). The third gear (13) drives each of the plurality of gears (14) which is smaller in diameter than the third gear (13), said each gear being associated with the permanent magnet generator (16). The power generated from each permanent magnet generator (16) is partly stored in the battery (24) for future use, with the remaining power being transmitted to the socket (29) for immediate use through the UPS (23). A part of the power so stored in the battery (24) is used to drive the motor (1).
To protect the power enhancer from overloading, an overload relay (not shown) is provided in the power enhancer, which cuts-off as and when there is overload.
In yet another embodiment of the present disclosure, the diameter of the first gear (4) is 21 units.
In yet another embodiment of the present disclosure, the diameter of the second gear (8) is 7 units.
In yet another embodiment of the present disclosure, the diameter of the third gear (13) is 35 units.
In yet another embodiment of the present disclosure, the diameter of each gear in the plurality of gears (14) is 11 units.
In yet another embodiment of the present disclosure, the ratio of the diameter of the second gear (8) to the diameter of each gear in the plurality of gears (14) is 1:1.5.
It will be apparent to a person skilled in the art that the above description is for illustrative purposes only and should not be considered as limiting. Various modifications, additions, alterations and improvements without deviating from the spirit and the scope of the disclosure may be made by a person skilled in the art. Such modifications, additions, alterations and improvements should be construed as being within the scope of this disclosure.

LIST OF REFERENCE NUMERALS
1 – Motor
2 – First Shaft
3 – First Power Cable
4 – First Gear
5 – First Stand
6 – First Bearing
7 – Second Stand
8 – Second Gear
9 – Third Stand
10 – Third Bearing
11 – Second Shaft
12 – Fourth Stand
13 – Third Gear
14 – Plurality of Gears
15 – Nut
16 – Permanent Magnet Generator
17 – Output Cable
18 – Fifth Stand
19 – Second Bearing
20 – Multi-connector
21 – Rectifier
22 – Cable
23 – UPS
24 – Battery
25 – Second Power Cable
26 – Third Power Cable
27 – Fourth Power Cable
28 – Plug
29 - Socket




CLAIMS
I claim:
1. A power enhancer, said power enhancer comprising a motor (1) that comprises a first shaft (2); a first power cable (3) that transmits power from a socket (29) to the motor (1); a first gear (4) that is coupled to the first shaft (2), said first gear (4) receiving power from the motor (1) through the first shaft (2); a second gear (8) that is meshed with the first gear (4), said second gear (8) being coupled with a first end of a second shaft (11); a third gear (13) that is coupled with a second end of the second shaft (11); a plurality of gears (14), said plurality of gears (14) being in contact with the third gear (13) to achieve a greater speed than torque, wherein each gear in the plurality of gears (14) is associated with a corresponding permanent magnet generator (16); an output cable (17) that is associated with each permanent magnet generator (16), said output cable (17) transmitting power from each permanent magnet generator (16) to a multi-connector (20) for cumulative power generation; a rectifier (21) that converts Direct Current (DC) from the multi-connector (20) to Alternate Current (AC); a cable (22) that transmits Alternate Current (AC) from the rectifier (21) to a Uninterruptible Power Supply (UPS) (23); a second power cable (25) and a third power cable (26) that transmit power from the UPS (23) for storing in a battery (24); a fourth power cable (27) that transmits power from the UPS (23) to the socket (29) via a plug (28) for immediate utilization; a first stand (5) that supports the first shaft through a first bearing (6); a second stand (7) that stabilizes the motor (1); a third stand (9) that supports the first end of the second shaft (11) through a second bearing (19); and a fourth stand (12) that supports the second end of the second shaft (11) through a third bearing (10), wherein the first gear (4), the second gear (8), the third gear (13), and the plurality of gears (14) are configured in appropriate ratios for enhancing the output power.
2. A power enhancer as claimed in claim 1, wherein each permanent magnet generator (16) has a rating of 12 Volts.
3. A power enhancer as claimed in claim 1, wherein each permanent magnet generator (16) has a rating of 24 Volts.
4. A power enhancer as claimed in claim 1, wherein the motor (1) is a 1HP motor.
5. A power enhancer as claimed in claim 1, wherein the diameter of the first gear (4) is 21 units.
6. A power enhancer as claimed in claim 1, wherein the ratio of the diameter of the second gear (8) to the diameter of each gear in the plurality of gears (14) is 1:1.5.
7. A power enhancer as claimed in claim 6, wherein the diameter of the second gear (8) is 7 units.
8. A power enhancer as claimed in claim 1, wherein the diameter of the third gear (13) is 35 units.
9. A power enhancer as claimed in claim 6, wherein the diameter of each gear in the plurality of gears (14) is 11 units.


Dated this the ------- day of February 2018


ABSTRACT
A POWER ENHANCER
A power enhancer comprises a motor (1) that comprises a first shaft (2); a first power cable (3) that transmits power from a socket (29) to the motor (1); a first gear (4); a second gear (8) that is coupled with a first end of a second shaft (11); a third gear (13) that is coupled with a second end of the second shaft (11); a plurality of gears (14) that is in contact with the third gear (13) to achieve a greater speed than torque, wherein each gear in the plurality of gears (14) is associated with a corresponding permanent magnet generator (16); an output cable (17) that is associated with each permanent magnet generator (16); a multi-connector (20); a rectifier (21); a cable (22); a UPS (23); a battery (24); a second power cable (25); a third power cable (26); and a fourth power cable (27). The first gear (4), the second gear (8), the third gear (13), and the plurality of gears (14) are configured in appropriate ratios for enhancing the output power.
Figure To Be Included in Abstract: Figure 1