FIELD OF INVENTION

The present invention generally related to data and power transfer system. In particular, the invention relates to transfer of at least one of data and power from at least one battery operated donor electronic device to at least one beneficiary electronic device.

BACKGROUND OF THE INVENTION

Rechargeable lithium battery which was originally designed for use in military applications however is now found as a power source for consumer as well as industrial products. Usually, rechargeable battery is housed inside the product and is recharged by AC-DC charger being connected to an AC main power supply. The user has to rely on AC power to recharge their battery which may not be available in certain situations such as while travelling or residing at a remote location etc. This is highly undesirable as it is inconvenient to the user.

In addition, DC charger such as vehicle charger can be used to recharge the battery. However, it is not a good alternative due to its limited charging capacity. Furthermore, many portable electronic devices such as mobile phone, tablets etc have USB port incorporated and it can be connected to other electronic device such as laptop, computer etc in order to receive power from them. However, the current that can be provided through USB connection is limited. Thus, the time taken to recharge the battery using only USB port is significantly longer than using AC mains charging. Moreover, smaller voltage operated devices cannot transfer their power to bigger voltage operated devices. For example, a mobile device cannot recharge a laptop or a tablet.

USB or micro-USB cables are presently available that facilitate the power sharing between two electronic devices. However, it has its own limitations. The electronic devices need specific software to enable power sharing between each other. This is again a limitation because it is not always possible that the software may be present in every electronic device. In a situation of travelling or at remote location the user will not be able to receive power from other device if it does not have the software and hence making it inconvenient to the user. Moreover, not all electronic devices incorporate USB or micro-USB port and hence user may not be able to connect with other devices and share power between them.

Battery pack is another alternative which is used to power the battery operated electronic devices. However it has many limitations. Battery pack is limited to recharge lower voltage operated devices and hence other devices like tablets, laptops or any other higher voltage operated devices like drill or medical devices cannot be recharged. Furthermore, once discharged the battery pack needs to be charged again for further use. This is again a limitation as recharging facilities may not be present everywhere.

It is a well known technology that ports such as USB, micro-USB, lightening connector, MHL port or an optical port of battery operative electronic device works with dual purpose of sharing data as well as power with other electronic devices. Moreover, it is also a known technology that ports such as audio jack, laptop charging port, USB, micro-USB, lightening connector, MHL port or an optical port discharges small current with time and these currents are harvested from the respective ports to recharge another electronic device. However, presently there is no provision available which accumulates the small current as well as battery current discharged by the respective port of at least one battery operated electronic device and share it with at least one beneficiary electronic device.

Thus, there remains a need to eliminate the above mentioned shortcomings in power sharing technology. Therefore, the present invention facilitates accumulation of at least one of data and power from at least one battery operated donor electronic device and distributes to at least one beneficiary electronic device. Moreover, the present invention does not require any energy storage component as it distributes the accumulated power instantaneously. Hence the user does not need to recharge the electronic device to facilitate the power transfer from a battery operated donor electronic device to beneficiary electronic device.

SUMMARY OF INVENTION

The main objective of the present invention is to transfer at least one of data and power from at least one battery operated donor electronic device to at least one beneficiary electronic device. The present invention harvests at least one of small current discharged by the ports such as audio jack, MHL port, laptop charging port, an optical port, USB port or a micro- USB port and the battery power of the battery operated donor electronic device.

In order to achieve the above mentioned objective, the present invention discloses an electronic device and method to transfer at least one of power and data from at least one battery operated donor electronic device to at least one beneficiary electronic device. The electronic device comprises multiple input ports wherein the first end of at least one input port is connected with a computing unit residing inside the housing of electronic device and second end of at least one input port is made available to connect with at least one battery operated donor electronic device. The electronic device further comprises multiple output ports wherein the first end of at least one output port is connected with the computing unit residing inside the housing of electronic device and second end of at least one output port is made available to connect with at least one beneficiary electronic device.

BRIEF DESCRIPTION OF DRAWINGS

Fig. la and Fig. lb illustrates the top and bottom view of the electronic device respectively.

Fig.2 and Fig. 3 illustrates the isometric view and exploded view of the electronic device 1 respectively.

Fig.4 illustrates the block diagram of computing unit 200 residing inside the housing of electronic device.

Fig.5a-5b illustrates an embodiment where the electronic device 1 is connected with battery operated donor electronic device 6a and beneficiary electronic device 5b.

Fig.6 illustrates another embodiment of the electronic device 1 with multiple input switches llal-llb2 and multiple output switches 12al-12c2 residing on the housing of the electronic device 1.

Fig.7 illustrates another embodiment of the electronic device 1 with one input switch 11a- 11b and one output switch 12a-12c residing on the housing of the electronic device 1.

Fig. 8 illustrates another embodiment of the electronic device 1 where at least one of input port 4a-4b and output port 8a-8c is removable from the electronic device 1.

Fig. 9 illustrates another embodiment of the electronic device 1 with one switch 101 residing on the housing of the electronic device 1.

Fig.10a and Fig. 10b illustrates another embodiment of the electronic device 1 where input port 4c and output port 8c is a female port.

DETAILED DESCRIPTION OF THE INVENTION

Reference will now be made in detail to the exemplary embodiment (s) of the invention, examples of which are illustrated in the accompanying drawings. Whenever possible, the same reference numerals will be used throughout the drawings to refer to the same or like parts.

Fig. la and lb illustrates the top and bottom view of the electronic device 1 respectively. The first end 2a-2b of the input port 4a-4b is connected to the housing of the electronic device 1 and second end 7a-7b of the input port 4a-4b is made available to connect with at least one battery operated electronic device. Moreover, the first end 9a-9c of the output port 8a-8c is connected to the housing of the electronic device 1 and second end lOa-lOc is made available to connect with at least one beneficiary electronic device.

Fig. 2 illustrates the isometric view of the electronic device 1

Fig. 3 illustrates the exploded view of the electronic device 1 wherein the computing unit 200 is shown residing inside the housing of the electronic device 1. The first end 2a-2b of the input port 4a-4b is connected to the computing unit 200 of the electronic device 1 and second end 7a-7b of the input port 4a-4b is made available to connect with at least one battery operated electronic device. Moreover, the first end 9a-9c of the output port 8a-8c is connected to the computing unit 200 of the electronic device 1 and second end lOa-lOc is made available to connect with at least one beneficiary electronic device.

Fig. 4 illustrates the block diagram of the computing unit 200 which resides inside the housing of the electronic device. Amplification module 202 is represented as Amp. module 202 in Fig. 4.

First end 2041 of the accumulation module 204 is connected to at least one input port 4a-4b and the second end 2042 of accumulation module 204 is connected to the first end 2051 of voltage regulation and current stabilization module 205. Third end 2043 of accumulation module 204 is connected to first end 2021 of amplification module 202. First end 2011 of detection module 201 is connected to at least one input port 4a-4b and second end 2012 of detection module 201 is connected to at least one output port 8a-8c. Further, the third end 2013 of the detection module 201 is connected to the third end 2023 of amplification module 202 and the fourth end 2014 of detection module 201 is connected to the fifth end 2035 of DC-AC module 203. The second end 2052 and third end 2053 of the voltage regulation and current stabilization module 205 is connected to the second end 2022 of amplification module 202 and second end 2032 of DC-AC module 203 respectively. Fifth end 2025 of the amplification module 202 is connected to the first end 2031 of DC-AC module 203 and fourth end 2024 of the amplification module 202 is connected to the third end 2063 of the distribution module 206. Fourth end 2034 of DC-AC module 203 is connected to the second end 2062 of distribution module 206 and fourth end 2064 of distribution module 206 is connected to at least one output port 8a-8c. Fourth end 2054 of voltage regulation and current stabilization module 205 is connected to the first end of distribution module 2061. First end 2071 of isolation module 207 is connected to fourth end 2044 of accumulation module 204 and second end 2072 of isolation module 207 is connected to fifth end of distribution module 2065. Isolation module 207 is provided to prevent current cross-talking between input ports 4a-4b and output ports 8a-8c.

Voltage regulation and current stabilization module 205 is provided to stabilize the voltage and current of at least one of data and power received from at least one input port 4a-4b. Amp. module 202 is provided to amplify at least one of data and power received from at least one input port 4a-4b. DC-AC module 203 is provided to convert DC input power received from at least one input port 4a-4b to AC output power.

Fig. 5a and Fig. 5b illustrates one embodiment of the electronic device 1 wherein the battery operated donor electronic device 6a is connected to the input port 4a of electronic device 1. Furthermore, the beneficiary electronic device 5b is connected with output port 8b of electronic device 1.

Fig. 6 illustrates another embodiment of electronic device 1. Two input switches llal-llb2, residing on the surface of the electronic device 1, are associated with at least one input port 4a-4b and provides an option to donor user to send at least one of power and data to the beneficiary electronic device. Moreover, two output switches 12al-12c2, residing on the surface of the electronic device 1, are associated with at one output port 8a-8c and provides an option to beneficiary user to receive at least one of power and data from at least one battery operated electronic device.

Fig. 7 illustrates another embodiment of electronic device 1. One input switch lla-llb, residing on the surface of the electronic device 1, is associated with at least one input port 4a- 4b and provides an option to donor user to send at least one of power and data to the beneficiary electronic device. Moreover, one output switch 12a-12c, residing on the surface of the electronic device 1, is associated with at one output port 8a-8c and provides an option to beneficiary user to receive at least one of power and data from at least one battery operated electronic device.

Fig.8 illustrates another embodiment of the electronic device 1 where at least one of input port 4a-4b and output port 8a-8c is removable from the housing of the electronic device 1.

Fig. 9 illustrates an isometric view of another embodiment of electronic device 1. Switch 101 resides on the surface of the electronic device 1 and provides an option to donor user to send at least one of power and data to the beneficiary device.

Fig. 10a illustrates another embodiment of the electronic device 1. Female input port 4c is provided to allow donor user to connect at least one battery operated donor electronic device with it.

Fig. 10b illustrates another embodiment of the electronic device 1. Female output port 8c is provided to allow beneficiary user to connect at least one beneficiary electronic device.

In first preferred embodiment, the donor user 13 wants to transfer at least one of data and power from at least one battery operated donor electronic device 6a-6b to at least one beneficiary electronic device 5a-5c associated with the beneficiary user 14. The donor user 13 connects at least one battery operated donor electronic device 6a-6b with at least one input port 4a-4b of the electronic device 1. A detection module 201 of the computing unit 200 detects and activates the input port 4a-4b connected with respective battery operated donor electronic device 6a-6b. Further, in order to receive data and power from at least one battery operated donor electronic device 6a-6b, the beneficiary user 14 connects at least one beneficiary electronic device 5a-5c with at least one output port 8a-8c of the electronic device 1 and triggers at least one output switch 12a-12c associated with the data and power. The detection module 201 of computing unit detects and activates output port 8a-8c connected with respective beneficiary electronic device 5a-5c. Moreover, the detection module 201 detects the voltage rating of at least one battery operated donor electronic device 6a-6b connected with the respective input port 4a-4b and at least one beneficiary electronic device 5a-5c connected with the respective output port 8a-8c. The detection module 201 activates its amplification module 202 if the voltage rating of at least one beneficiary electronic device 5a-5c is detected higher than the voltage rating of at least one battery operated donor electronic device 6a-6b. The detection module 201 further activates its DC- AC module 203 if at least one beneficiary electronic device is detected as AC powered device.

The donor user 13 transfers the data from at least one battery operated donor electronic device 6a-6b to the computing unit and moreover, the computing unit withdraws the power from at least one battery operated donor electronic device 6a-6b connected with respective input port 4a-4b. The withdrawn power includes at least one of small current discharged by the respective battery operated donor electronic device 6a-6b port as well as the battery charge of the respective battery operated donor electronic device 6a-6b. An accumulation module 204 of the computing unit 200 receives and accumulates the data and power from at least one input port 4a-4b connected with respective battery operated donor electronic device 6a-6b.

Since, the data and power received from at least one battery operated donor electronic device 6a-6b may comprise unregulated data and power hence the accumulation module 204 transfers the accumulated data and power to a voltage regulation and current stabilization module, voltage regulation and current stabilization module 205 of the computing unit 2 to regulate at least one of accumulated data and power. If the amplification module 202 and DC-AC module 203 is deactivated by the detection module 201 then the voltage regulation and current stabilization module 205 transfers at least one of regulated data and power to a distribution module 206 of the computing unit 2 wherein the distribution module 206 distributes at least one of regulated data and power to at least one output port 8a-8c connected with at least one beneficiary electronic device 5a-5c.

In an alternative embodiment of the first embodiment where the amplification module 202 is activated and DC-AC module 203 is deactivated by the detection module 201, the voltage regulation and current stabilization module 205 transfers the regulated data and power to the amplification module 202 to achieve the required amplification of at least one of data and power. The amplification module 202 transfers at least one of amplified data and power to the distribution module 206 of the computing unit 200 wherein the distribution module 206 distributes the regulated data and power to at least one output port connected with at least one beneficiary electronic device 5a-5c.

In another alternative embodiment of the first embodiment where the amplification module 202 and DC-AC module 203 are activated by the detection module 201, the voltage regulation and current stabilization module 205 transfers at least one of regulated data and power to DC-AC module 203 to achieve the converted output. Furthermore, at least one of converted data and power is transferred from DC-AC module 203 to amplification module 202 to achieve the required amplification of at least one of data and power. Thereafter, the amplification module 202 transfers at least one of amplified data and power to the distribution module 206 of the computing unit 200 wherein the distribution module 206 distributes the required data and power to at least one output port 8a-8c connected with at least one beneficiary electronic device 5a-5c.

In a yet another embodiment of the first embodiment where the amplification module 202 is deactivated and DC-AC module 203 is activated by the detection module, the voltage regulation and current stabilization module 205 transfers at least one of regulated data and power to DC-AC module 203 to achieve the converted output. Furthermore, at least one of converted data and power is transferred from DC-AC module 203 to the distribution module 206 of the computing unit 200 wherein the distribution module 206 and distributes the regulated data and power accordingly to at least one output port 8a-8c connected with at least one beneficiary electronic device 5a-5c.

In second embodiment, the donor user 13 wants to share both data and power of at least one battery operated donor electronic device 6a-6b with at least one beneficiary electronic device 5a-5c associated with the beneficiary user 14. The donor user 13 connects at least one battery operated donor electronic device 6a-6b with at least one input port 4a-4b of the electronic device 1 and triggers at least one input switch lla-llb associated with the data and power. A detection module 201 of the computing unit 200 detects and activates the input port 4a-4b connected with the respective battery operated donor electronic device 6a-6b. Further, in order to receive data and power from at least one battery operated donor electronic device 6a- 6b, the beneficiary user 14 connects at least one beneficiary electronic device 5a-5c with at least one output port 8a-8c of the electronic device 1 and triggers at least one output switch 12a-12c associated with the data and power. The detection module 201 of computing unit 200 detects and activates output port 8a-8b connected with respective beneficiary electronic device 5a-5c. Moreover, the detection module 201 detects the voltage rating of at least one battery operated donor electronic device 6a-6b connected with the respective input port 4a- 4b and at least one beneficiary electronic device 5a-5c connected with the respective output port 8a-8c. The detection module 201 activates its amplification module 202 if the voltage rating of at least one beneficiary electronic device 5a-5c is detected higher than the voltage rating of at least one battery operated donor electronic device 6a-6b. The detection module 201 further activates its DC-AC module 203 if at least one beneficiary electronic device 5a- 5c is detected as AC powered device.

The donor user 13 transfers the data from at least one battery operated donor electronic device 6a-6b to the computing unit 200 and moreover, the computing unit 200 withdraws the power from at least one battery operated donor electronic device 6a-6b connected with respective input port 4a-4b. The withdrawn power includes both small current discharged by the respective battery operated donor electronic device port 6a-6b as well as the battery charge of the respective battery operated donor electronic device 6a-6b. An accumulation module 204 of the computing unit 200 receives and accumulates the data and power from at least one input port 4a-4b connected with respective battery operated donor electronic device 6a-6b.

Since, the data and power received from at least one battery operated donor electronic device 6a-6b may comprise unregulated data and power hence the accumulation module 204 transfers the accumulated data and power to a voltage regulation and current stabilization module 205 of the computing unit 200 to regulate at least one of accumulated data and power. If the amplification module 202 and DC-AC module 203 is deactivated by the detection module 201 then the voltage regulation and current stabilization module 205 transfers at least one of regulated data and power to a distribution module 206 of the computing unit wherein the distribution module 206 detects the trigger state of at least one output switch 12a-12c associated with the output port 8a-8c and distributes at least one of regulated data and power accordingly to at least one output port 8a-8c connected with at least one beneficiary electronic device 5a-5c.

In an alternative embodiment of the second embodiment where the amplification module 202 is activated and DC-AC module 203 is deactivated by the detection module 201, the voltage regulation and current stabilization module 205 transfers the regulated data and power to the amplification module 202 to achieve the required amplification of at least one of data and power. The amplification module 202 transfers at least one of amplified data and power to the distribution module 201 of the computing unit 200 wherein the distribution module 206 detects the trigger state of at least one output switch 12a-12c and distributes the regulated data and power accordingly to at least one output port 8a-8c connected with at least one beneficiary electronic device 5a-5c.

In another alternative embodiment of the second embodiment where the amplification module 202 and DC-AC module 203 are activated by the detection module 201, the voltage regulation and current stabilization module 205 transfers at least one of regulated data and power to DC-AC module 203 to achieve the converted output. Furthermore, at least one of converted data and power is transferred from DC-AC module 203 to amplification module

202 to achieve the required amplification of at least one of data and power. Thereafter, the amplification module 202 transfers at least one of amplified data and power to the distribution module 206 of the computing unit 200 wherein the distribution module 206 detects the trigger state of at least one output switch 12a-12c and distributes the required data and power accordingly to at least one output port 8a-8c connected with at least one beneficiary electronic device 5a-5c.

In a yet another embodiment of the second embodiment where the amplification module 202 is deactivated and DC-AC module 203 is activated by the detection module 201, the voltage regulation and current stabilization module 205 transfers at least one of regulated data and power to DC-AC module 203 to achieve the converted output. Furthermore, at least one of converted data and power is transferred from DC-AC module 203 to the distribution module 206 of the computing unit 200 wherein the distribution module 206 detects the trigger state of at least one output switch 12a-12c and distributes the regulated data and power accordingly to at least one output port 8a-8c connected with at least one beneficiary electronic device 5a- 5c.

In third embodiment, the donor user 13 does not wants to share the data but wants to share the power of at least one battery operated donor electronic device 6a-6b with at least one beneficiary electronic device 5a-5c associated with the beneficiary user 14. The donor user 13 connects at least one battery operated donor electronic device 6a-6b with at least one input port 4a-4b of the electronic device 1 and triggers at least one input switch lla-llb associated with the data and triggers at least one input switch lla-llb associated with the power. The trigger of input switch lla-llb associated with the data ensures the prevention of data transfer from at least one battery operated donor electronic device 6a-6b. A detection module 201 of the computing unit 200 detects and activates the input port 4a-4b connected with respective battery operated donor electronic device 6a-6b. Further, in order to receive power from at least one battery operated donor electronic device 6a-6b, the beneficiary user 14 connects at least one beneficiary electronic device 5a-5c with at least one output port 8a-8c of the electronic device 1 and triggers at least one output switch 12a-12c associated with the power optionally triggers at least one output switch 12a-12c associated with the data. The optional trigger of output switch 12a-12c associated with the data ensures the prevention of receiving any data from at least one battery operated donor electronic device 6a-6b. The detection module 201 of computing unit 200 detects and activates output port 8a-8c connected with respective beneficiary electronic device 5a-5c. Moreover, the detection module 201 detects the voltage rating of at least one battery operated donor electronic device 6a-6b connected with the respective input port 4a-4b and at least one beneficiary electronic device 5a-5c connected with the respective output port 8a-8c. The detection module 201 activates its amplification module 202 if the voltage rating of at least one beneficiary electronic device 5a-5c is detected higher than the voltage rating of at least one battery operated donor electronic device 6a-6b. The detection module 201 further activates its DC- AC module 203 if at least one beneficiary electronic device 5a-5c is detected as AC powered device.

The computing unit 200 withdraws the power from at least one battery operated donor electronic device 6a-6b connected with respective input port 4a-4b. The withdrawn power includes both small current discharged by the respective battery operated donor electronic device 6a-6b port as well as the battery charge of the respective battery operated donor electronic device 6a-6b. An accumulation module 204 of the computing unit 200 receives and accumulates power from all input port 4a-4b connected with respective battery operated donor electronic device 6a-6b.

Since, the power received from at least one battery operated donor electronic device 6a-6b may comprise unregulated power hence the accumulation module 204 transfers the accumulated power to a voltage regulation and current stabilization module 205 of the computing unit 200 to regulate the accumulated power. If the amplification module 202 and DC-AC module 203 is deactivated by the detection module 201 then the voltage regulation and current stabilization module 205 transfers the regulated power to a distribution module 206 of the computing unit 200 wherein the distribution module 206 detects the trigger state of at least one output switch 12a-12c associated with the output port 8a-8c and distributes the regulated power accordingly to at least one output port 8a-8c connected with at least one beneficiary electronic device 5a-5c.

In an alternative embodiment of the third embodiment where the amplification module 202 is activated and DC-AC module 203 is deactivated by the detection module 201, the voltage regulation and current stabilization module 205 transfers the regulated power to the amplification module 202 to achieve the required amplification of power. The amplification module 202 transfers at least one of amplified power to the distribution module 206 of the computing unit 200 wherein the distribution module 206 detects the trigger state of at least one output switch 12a-12c and distributes the regulated power accordingly to at least one output port 8a-8c connected with at least one beneficiary electronic device 5a-5c.

In another alternative embodiment of the third embodiment where the amplification module 202 and DC-AC module 203 are activated by the detection module 201, the voltage regulation and current stabilization module 205 transfers power to DC-AC module 203 to achieve the converted output. Furthermore, converted power is transferred from DC-AC module 203 to amplification module 202 to achieve the required amplification of power. Thereafter, the amplification module 202 transfers the amplified power to the distribution module 206 of the computing unit 200 wherein the distribution module 206 detects the trigger state of at least one output switch 12a-12c and distributes the required power accordingly to at least one output port 8a-8c connected with at least one beneficiary electronic device 5a-5c.

In a yet another embodiment of the third embodiment where the amplification module 202 is deactivated and DC-AC module 203 is activated by the detection module 201, the voltage regulation and current stabilization module 205 transfers power to DC-AC module 203 to achieve the converted output. Furthermore, converted data and power is transferred from DC-AC module 203 to the distribution module 206 of the computing unit 200 wherein the distribution module 206 detects the trigger state of at least one output switch 12a-12c and distributes the regulated power accordingly to at least one output port 8a-8c connected with at least one beneficiary electronic device 5a-5c. In fourth embodiment, the donor user 13 wants to share the data but does not wants to share the power of at least one battery operated donor electronic device 6a-6b with at least one beneficiary electronic device 5a-5c associated with the beneficiary user 14. The donor user 13 connects at least one battery operated donor electronic device 6a-6b with at least one input port 4a-4b of the electronic device 1 and triggers at least one input switch lla-llb associated with the data and triggers at least one input switch lla-llb associated with the power. The trigger of input switch lla-llb associated with the power ensures the prevention of power transfer from at least one battery operated electronic device 6a-6b to at least one beneficiary electronic device 5a-5c. A detection module 201 of the computing unit 200 detects and activates the input port 4a-4b connected with respective battery operated donor electronic device 6a-6b. Further, in order to receive data from at least one battery operated donor electronic device 6a-6b, the beneficiary user 14 connects at least one beneficiary electronic device 5a-5c with at least one output port 8a-8c of the electronic device 1 and triggers at least one output switch 12a-12c associated with the data optionally triggers at least one output switch 12a-12c associated with the power. The optional trigger of output switch 12a-12c associated with the power ensures the prevention of receiving any power from at least one battery operated donor electronic device 6a-6b. The detection module 201 of computing unit 200 detects and activates output port 8a-8c connected with respective beneficiary electronic device 5a-5c. Moreover, the detection module 201 detects the voltage rating of at least one battery operated donor electronic device 6a-6b connected with the respective input port and at least one beneficiary electronic device 5a-5c connected with the respective output port 8a- 8c. The detection module 201 activates its amplification module 202 if the voltage rating of at least one beneficiary electronic device 5a-5c is detected higher than the voltage rating of at least one battery operated donor electronic device 6a-6b. The detection module 201 further activates its DC-AC module 203 if at least one beneficiary electronic device 5a-5c is detected as AC powered device.

The donor user 13 transfers the data from at least one battery operated donor electronic device 6a-6b to the computing unit 200. An accumulation module 204 of the computing unit 200 receives and accumulates data from all input port 4a-4b connected with respective battery operated donor electronic device 6a-6b. The accumulation module 204 transfers the accumulated data to the distribution module 206 of the computing unit 200 wherein the distribution module 206 detects the trigger state of at least one output switch 12a-12c and distributes the accumulated data accordingly to at least one output port 8a-8c connected with at least one beneficiary electronic device 5a-5c.

In at least one of embodiment one, two, three or four; at least one of the input port 4a-4b and output port 8a-8c of the electronic device 1 is USB, micro-usb, a laptop charging port, an AC power plug, an optical port, an audio jack, a MHL port and a lightening connector.

In at least one of embodiment one, two, three or four; the donor user 13 disconnects at least one battery operated donor electronic device 6a-6b after withdrawal of certain level of battery power from it. In at least one of embodiment one, two, three or four; the beneficiary user 14 disconnects at least one beneficiary electronic device 5a-5c after receiving certain level of battery power in it.

In at least one of embodiment one, two, three or four; at least one of the input port 4a-4b and output port 8a-8c is a male headed port.

In at least one of embodiment one, two, three or four; at least one of the input port 4a-4b and output port 8a-8c is a female headed port.

In at least one of embodiment one, two, three or four; at least one of the input port 4a-4b and output port 8a-8c is a removable port.

In at least one of embodiment one, two, three or four; the electronic device 1 is a portable electronic device.

In at least one of embodiment one, two, three or four; the electronic device 1 is a nonportable electronic device.

In at least one of embodiment one, two, three or four; the electronic device 1 does not require energy storage component to facilitate at least one of data and power transfer from at least one battery donor operated donor electronic device 6a-6b to beneficiary electronic device 5a- 5c.

In at least one of embodiment one, two, three or four; the battery operated donor electronic device 6a-6b is at least one of but not limited to smart phones, tablets, medical devices, wrist bands, drill, table fan, hair dryer, shaving razor, Battery charging adaptor, laptops, smart watch, battery operated eye glass, toys, lamps, torch, PDA, GPS unit, navigation unit, music player, DVD player, Radio, camera, coffee maker, Iron, humidifiers, battery pack, military equipment or any consumer and industrial good which is operated by a battery.

In at least one of embodiment one, two, three or four; the beneficiary electronic device 5a-5c is at least one of but not limited to smart phones, tablets, medical devices, wrist bands, drill, table fan, hair dryer, shaving razor, Battery charging adaptor, laptops, smart watch, battery operated eye glass, toys, lamps, torch, PDA, GPS unit, navigation unit, music player, DVD player, Radio, camera, coffee maker, Iron, humidifiers, battery pack, AC powered LCD, AC powered fan, military equipment or any consumer and industrial good which is either AC powered or operated by a battery.