SYSTEM AND METHOD OF GENERATING SHOCK
PROOF ELECTRICITY
TECHNICAL FIELD
The present disclosure relates generally to conversion of electricity and more
particularly, to generating shock proof electricity.
BACKGROUND
It may be considered that the discovery of electricity is one of the greatest of its kind.
Electricity has immerged as one of the basic needs of our day to day life. Many of
the appliances that we use are powered by electricity. However, if a user comes in
contact of electricity, the user might experience electric shock.
Electric shock is the physiological reaction or injury caused by electric current
passing through the (human) body. An electric shock can occur upon contact of a
human or animal body with any source of voltage high enough to cause sufficient
current flow through the muscles or nerves. The minimum detectable current in
humans is thought to be about 1 mA. The current may cause tissue damage or heart
fibrillation if it is sufficiently high. An electric shock is usually painful and can be
lethal The level of voltage is not a direct guide to the level of injury or danger of
death, despite the common misconception that it is. A small shock from static
electricity may contain thousands of volts but has very little current behind it due to
high internal resistance. Physiological effects and damage are generally determined
by current and duration. Even a low voltage causing a current of extended duration
can be fatal.
Electrical receptacle outlets in walls and floors present serious hazards to the public.
A survey of accidents relating to electricity in India revels that about 2, 020 farmers
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died due to electricity shocks between 2005'and 2012 in 11 districts. A survey of
U.S. estimates that 3,900 injuries are associated with electrical receptacle outlets are
treated in hospital emergency rooms each year. Approximately a third of these
injuries occur when young children insert metal objects, such as hair pins and keys,
into the outlet, resulting in electric shock or burn injuries to the hands or fingers, and,
in many instances, death. It is also estimates that electric receptacles are involved in
5,300 fires annually, which claim, on average, 40 lives and injure 110 consumers.
In some existing technology or prior art documents it has been found to transmit
electricity through a shielded medium, so that a user of electric current may not be
harmed or come in contact of electricity. But often these methods or techniques seem
to have failed to server their purposes. However, if a means could be devised to
remove the property by virtue of which a user might obtain an electric shock, when in
contact of electricity the various issues and problems would be solved.
Therefore, there exists a need to develop a method or a system for generating shockfree
electricity.
SUMMARY
The present disclosure seeks to provide a system and a method for generating shock
proof electricity. The present disclosure also seeks to provide a system and a method
to transform norma! electric current into shock free electric current.
According to one aspect of the present disclosure aims to at least partially overcome
the problems encountered in the prior art, especially relating to the safety of a user of
electric current and the electronic appliances.
In one aspect, an embodiment of the present disclosure provides a system for
generating shock proof electricity; the system comprises generating a shock proof
electricity from an unstable electric current input, the system further comprising:
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a voltage stabilizing unit for providing a stabilized output current from the input of
the unstable electric current;
a capacitor bank, including a plurality of capacitors to normalize the stabilized
output current; and
a shock free current generator unit, including automatic line changing means.
In another aspect, an embodiment of the present disclosure provides a method of
generating shock proof electricity; the method comprises generating shock proof
electricity from an unstable input electric current, the method further comprising:
a means of stabilizing voltage for providing a stabilized output electric current
from the unstable input electric current;
a means for normalizing the stabilized output electric current; and
a means for automatically altering lines of the stabilized output electric current.
Additionally, in one objective of the present disclosure the voltage stabilizing unit
further comprise at least one primary transformer; at least one relay and
at least one electronic circuitry.
Further, in another objective of the present disclosure, the capacitor bank comprises
of plurality of capacitors and may alter inductive current into capacitive current or
resistive current.
Furthermore, in yet another objective of the present disclosure, the shock free current
generator unit comprises a secondary transformer with equal number of coil turns in
either side. .
Embodiments of the present disclosure substantially eliminates or at least address the
aforementioned problems in the prior art, and provides an efficient communication
network for managing a container system.
Additional aspects advantages features and object of the present disclosure would be
made apparent from the drawings and the detailed description of the illustrative
embodiments constructed in conjunction with the appended claims that follow
BRIEF DESCRIPTION OF THE DRAWINGS
The summary above, as well as the following detailed description of illustrative
embodiments, is better understpod when read in conjunction with the appended
drawings. For the purpose of illustrating the present disclosure, exemplary
constructions of the disclosure are shown in the drawings. However, the present
disclosure is not limited to specific methods and instrumentalities disclosed herein.
Moreover, those skilled in the art will understand that the drawings are not to scale.
Wherever possible, like elements have been indicated by identical numbers.
Embodiments of the present disclosure will now be described, by way of example
only, with reference to the following diagrams wherein:
FIG. 1 illustrates a block diagram for generating a system for generating shock proof
electricity, in accordance with an embodiment of the disclosure;
FIG. 2 illustrates a circuit diagram for generating a system for generating shock proof
electricity, in accordance with an embodiment of the disclosure
DETAILED DESCRIPTION OF EMBODIMENTS
The following detailed description illustrates embodiments of the present disclosure
and ways in which they can be implemented. Although some modes of carrying out
the present disclosure have been disclosed, those skilled in the art would-recognize
that other embodiments for carrying out or practicing the present disclosure are also
possible.
In one aspect, an embodiment of the present disclosure provides a system for
generating shock proof electricity; the system comprises generating a shock proof
electricity from an unstable electric current input, the system further comprising:
a voltage stabilizing unit for providing a stabilized output current from the input of
the unstable electric current;
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a capacitor bank, including a plurality of capacitors to normalize the stabilized
output current; and
a shock free current generator unit, including automatic line changing means.
In another aspect, an embodiment of the present disclosure provides a method of
generating shock proof electricity; the method comprises generating shock proof
electricity from an unstable input electric current, the method further comprising:
a means of stabilizing voltage for providing a stabilized output electric current
from the unstable input electric current;
a means for normalizing the stabilized output electric current; and
a means for automatically altering-lines of the stabilized output electric current.
According to an embodiment, in the system for generating shock proof electricity the
system may be connected to the main electric input line of an electrical set up for the
safety of the users of the electrical set up. For example, the system may be connected
to the main line that provides electric current for the household to generate shock free
electricity throughout each and every power outlet in the entire household
environment. Further, the system for generating shock proof electricity may also be
connected to a part or a single electrical connection of a larger electrical set up of an
electrical environment. For example, the system may be connected to a power outlet
for generating shock free electricity for providing power supply to an electrical
appliance.
In one embodiment;, the unstable electric current input is the generally provided
electric power for use in (but not limited to) households or commercial
establishments. The electric current input may have various voltages and may be
provided from various means.
In one embodiment the voltages of the input current fluctuate, thereby being unstable.
The system stabilizes the unstable voltage in the input current. For example the as
the system can take an input current with a fluctuating voltage ranging from 110 to
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and stabilizing the voltage in the output current which may range from 210V to
240V
According to the present disclosure, the voltage stabilizing unit stabilizes output
current from the input of the unstable electric current. The stabilizing unit provides a
means of stabilizing voltage for providing a stabilized output electric current.
Further, the voltage stabilizing unit comprises of at least one primary transformer, at
least one relay and at least one electronic circuitry
In one embodiment, the at least one primary transformer is a voltage transformer. The
primary transformer may include various size, shape, design, core type and windings.
Further the transformer may be a step up or step down. In one embodiment the
primary transformer in accept a current with a voltage ranging from 110 to 440V and
convert it to a current having a voltage ranging from 210V to 240V
Further, the at least one primary transformer is operably connected to the at least one
relay. The relay connected to the transformer makes connection for the transformer.
For example, when an input voltage for the transformer is 110V the relay makes the
connection of the transformer to 110V and when the input voltage for the transformer
is 440V the relay makes the connection in the transformer to 440V Moreover the
primary transformer is connected to at least.two circuitry.
In another embodiment of the present disclosure, the output current always has a
stabilized voltage. Further the range of the voltage may be (but not limited to) 2I0V
to 240V
According to the present disclosure, the system for generating shock proof electricity
comprises of the capacitor bank. The capacitor bank provides a means for
normalizing the stabilized output electric current.
In one embodiment the capacitor bank includes a plurality of capacitors to normalize
the stabilized output current. The capacitors may be of various types, shapes, sizes
and may be made of various materials. Further the capacitors used in the capacitor
bank may be of various capacitances.
In one embodiment the plurality of capacitors may be connected in parallel. The
output current of the voltage stabilizing unit is fed to the capacitor bank, the plurality
of capacitors to normalize the stabilized output current by removing the unwanted
spikes in the current.
In one embodiment of the present disclosure, the capacitor bank may change the
inductive current into capacitive current load or into inductive current into capacitive
current load.
According to the present disclosure, the system for generating shock proof electricity
comprises of the shock free current generator unit. Further, the shock free current
generator unit provides a means for automatically altering lines of the stabilized
output electric current.
In one embodiment of the present disclosure, the shock free current generator unit
comprises a secondary transformer. The secondary transformer may include various
size, shape, design, and core type.
In another embodiment of the present disclosure, the secondary transformer has equal
number of windings on either side. For example, if one side has 800 turns that the
other side also has 800 turns.
In one embodiment of the present disclosure, the secondary transformer having equal
number of bindings on the either side converts the normal current into a shock free
current. For example, the current after passing a power line after it has passed
through the secondary transformer having equal number of bindings on the either side
can be touched by a person and the person would not feel an electric shock.
In another embodiment according to the disclosure, the secondary transformer is
connected to at least two circuitry. One of the circuitry that is providing an electric
power output to be used in a power outlet becomes shock-less. For example, when a
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person is exposed to an unshielded power cable (a copper wire in the power cable)
that is conducting electricity.
In one embodiment of the present disclosure, the system and the method for
generating shock free electricity from an unstable electric current input comprises of
using the normal current supply that is provided for powering the electrical
appliances as an input. The input current is subjected to a voltage stabilizing unit. The
voltage stabilizing comprises of at one primary transformer, at least one relay and at
least one electronic circuitry. The input current in the stabilizing unit is passed
through the primary transformer; the transformer stabilizes the input current along
with the relay and passes onto the electronic circuitry. The electronic circuitry
connects the primary transformer of the stabilizing unit to the capacitor bank, through
which the stabilized output current passes, the capacitor bank normalize the stabilized
output current and alters the inductive current into capacitive current or resistive
current. Thereafter, the normalized stabilized output current is subjected to a shock
free current generator unit. The normalized stabilized output current may than be
passed through a secondary transformer in the shock free current generator unit. The
secondary transformer in the shock free current generator unit which has equal
number of turns in its either sides converts the normalized stabilized output current
into a shock free current.
In one embodiment of the present disclosure, the system with secondary transformer
which has equal number of turns in its either sides is connected to a power line of a
power outlet, it creates its own neutral phase. For example when a person touches the
power line the transformer due to its which has equal number of turns in its either
sides automatically converts the hot line into a neutral line, which thereby prevents
the person from getting an electric shock.
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3.
Referring to the drawings, specifically to FIG.l, illustrates a block diagram for
generating a system for generating shock proof electricity. The system includes a
voltage stabilizing unit, a capacitor bank and a shock free current generator unit.
Further, the stabilizing unit comprises primary transformer, relay and electronic
circuitry.
Referring to the drawings, specifically to FIG. 2, illustrates a circuit diagram for
generating a system for generating shock proof electricity.
Claims
What is claimed is:
1. A system for generating shock proof electricity from an unstable electric
current input, system comprising:
a voltage stabilizing unit for providing a stabilized output current from
the input of the unstable electric current;
a capacitor bank, including a plurality of capacitors to normalize the
stabilized output current; and
a shock free current generator unit, including automatic line changing
means.
2. The system as set forth 1, wherein the voltage stabilizing unit further
comprises:
at least one primary transformer;
at least one relay; and
at least one electronic circuitry.
3. The system as set forth 2, wherein the primary transformer is used to alter
voltage of the unstable electric current input.
4. The system as set forth 1, wherein the plurality of capacitors is connected in
parallel connection.
5. The method as set forth in claim 1, wherein the capacitor bank alters the
inductive current into capacitive current.
6. The method as set forth in claim 1, wherein the capacitor bank alters the
inductive current into resistive current.
7. The system as set forth 1, wherein the shock free current generator unit
comprises a secondary transformer.
8. The system as-set forth 7, wherein the secondary transformer has equal
number of coil turns in either side.
9. The system as set forth 1, wherein the shock free current generator unit is
capable of interchanging the flow of electric current between the phase line
and neutral line of a power outlet.
10. A method of generating shock proof electricity from an unstable input electric
current, method comprising:
a means of stabilizing voltage for providing a stabilized output electric
current from the unstable input electric current;
a means for normalizing the stabilized output electricscurrent; and
a means for automatically altering lines of the stabilized output electric
current.
11. The method as set forth in claim 10,wherein the means of stabilizing voltage
comprises:
at"least one primary transformer;
at least one relay; and
at least one electronic circuitry.
12. The method as set forth in claim 11, wherein the primary transformer is used
to alter voltage of the unstable electric current input.
13. The method as set forth in claim 10, wherein the means for normalizing the
stabilized output electric current is a capacitor bank.
14. The method as set forth in claim 13, wherein the capacitor bank alters the
inductive current into capacitive current.
15. The method as set forth in claim 13, wherein the capacitor bank alters the
inductive current into resistive current.
16. The method as set forth in claim 10, wherein the means for automatically
altering lines comprises a secondary transformer.
17. The system as set forth in claim 10, wherein the secondary transformer has
equal number of coil turns in either side.
18. The system as set forth in claim 10, wherein the shock free current generator
unit is capable of interchanging the flow of electric current between the phase
line and neutral line of a power outlet.