DE102009050766A1 - A charging device for charging an electronic device with a built-in battery and a charging system - Google Patents

Abstract

The invention relates to a charging device (2) for charging an electronic device (12) with an internal battery (16), with an interface (4) for contacting the electronic device (12), supplying an electrical current to the electronic device (12 ) for charging the battery (16) and for absorbing the heat from the electronic device (12), with a heat sink (8) for dissipating the heat and with a charger connection (6) between the interface (4) and the heat sink (8) for transmitting the heat absorbed by the electronic device (12) to the heat sink (8). Moreover, the invention relates to a charging system with the above-described charging device (2) and the electronic device (12) with an internal battery (16).

Description

The invention relates to a charging device for charging an electronic device with built-in battery and a charging system.

As is known, a charging device charges a battery through the supply of electric current. When charging, the battery heats up. The heat is generated in the battery through chemical and electrochemical processes during charging. This increase in temperature leads to expansion of the battery and could result in degassing, cracking or blasting of the battery when the temperature exceeds a certain limit.

A general goal is to charge batteries as fast as possible. This is achieved by increasing the electrical current supplied to the battery. A higher current, however, also causes higher temperatures in the battery. Therefore, the supplied power must be limited, which in turn is reflected in longer charging times.

WO 2008/058266 A2 discloses a docking station for receiving an electronic device with an internal battery for charging. This docking station cools down the device during the charging process. An electric current for charging the battery is supplied from the docking station to the electronic device via an electrical connection to the docking station. The docking station also includes a thermal contact for the heat flow between the electronic device and a heat sink in the docking station for cooling the electronic device.

The invention has for its object to provide a simple method for cooling the battery in an electronic device, the design should be kept compact.

This object is achieved by a charger according to claim 1 and a charging system according to claim 7.

According to one embodiment of the invention, a charging device for charging an electronic device with an internal battery is provided within the device. The charger includes an interface for receiving heat from the electronic device or battery in this device and for providing electrical power to the electronic device for charging the battery. The charger further includes a heat sink for dissipating the heat and a charger connection between the interface and the heat sink for transmitting the heat received by the electrical appliance. The connection to the charger and the interface is used for both the electric power and the heat flux. The interface, which both supplies an electric current and absorbs the heat, is a simple solution that allows a compact design of the charger, as it can be avoided that two separate interfaces - one for the electric current and one for heat transfer - built Need to become. This allows a compact design of the electronic device, since it only needs a battery connection for the electric power and for the heat transfer.

The charger can also charge an existing electronic device. A battery terminal in such devices consists of the electrical conductors, which are usually metal, which have good conductivity for both electricity and heat. Thus, the battery terminal in the existing electronic device receives the electric current and at the same time it can transfer the heat to the interface of the charging device. Thus, the charger provides a simple solution for cooling the battery within the existing electronic device.

In a further embodiment of the invention, a fan is provided which enhances the heat dissipation capacity of the heat sink. The use of a fan creates a convection current around the heat sink that quickly cools the heat sink. It helps to absorb the heat more quickly from the electronic device, so that the battery is cooled faster.

According to another embodiment of the invention, the heat sink is advantageously provided in the form of a lamella. Since the lamella has a larger contact surface with the surrounding air, the heat is dissipated more quickly into the environment.

According to a further embodiment of the invention, an advantageous heat sink is provided in the form of a Peltier element in the charging device in order to dissipate the heat quickly. The Peltier element is easily available and compact.

According to a further embodiment of the invention, the connection of the charging device is made of metal. Metals have excellent both electrical and thermal conductivity, therefore they increase the conductivity bez. Heat and electricity for connection of the charger.

According to a further embodiment of the invention, a charging system is provided, which is a electronic device comprising an internal battery and the charger as described above.

According to a further embodiment of the invention, the charging system is provided with an electronic device which has a battery receiving device in which the battery is inserted, and a battery connection for transmitting the heat from the battery to the interface. The battery connector is used to supply the electrical power from the charger to the battery. Such a battery terminal, which can conduct both the electric power and the heat, does not cause any modifications in the electronic equipment, and the same electronic equipment can be used for both. Such a battery connection makes the electronic device compact and inexpensive.

According to another aspect of the invention, the electronic device is provided with a contact pad adapted to be in contact with a charging pole and able to absorb heat from the battery. This contact field is advantageous to realize a simple solution for efficient heat transfer from the battery to the battery terminal, since the contact pad is a good conductor of heat. The contact pad is adapted to be able to transmit the electrical current to the battery through the charging pole.

According to another aspect of the invention, the contact pad is in contact with a substantial portion of the surface of the charging pole of the battery. Such contact is advantageous for better heat transfer from the battery to the battery terminal since the larger contact area allows for greater heat transfer between the contact pad and the battery.

According to a further embodiment of the invention, the contact field is advantageously extended such that it is in contact with an electrically insulated part of the battery. Such an enlarged contact field further increases the heat transfer from the battery to the contact pad.

According to another embodiment of the invention, the battery connection is advantageously made of metal, since metals are very good conductors, both for heat and for electricity.

According to a further embodiment of the invention, the electronic device is provided with a Peltier elements for cooling the battery. Such a Peltier element cools the battery quickly, since the cooling of the battery within the electronic device takes place in addition to cooling by the heat sink in the charger.

In accordance with another aspect of the invention, the electronic device includes an air delivery port and another air delivery port to allow convection around the battery. This convection cools the battery, in addition to cooling by the heat sink in the charger. It thus represents a simple and inexpensive solution for the rapid cooling of the battery.

According to a further embodiment of the invention, the charging system consists of an electronic device in the form of a hearing device or a hearing device. The use of this invention as an electronic device in the form of a hearing aid is particularly useful because the compact shape of the device is an important feature of the hearing aid.

The above-mentioned and other features of the invention will now be described with reference to the drawings of a preferred embodiment of the charging device and the electronic device as part of the charging system. The embodiments of the charging device and the charging system shown here serve to illustrate the invention, and not to impose any restrictions on it. The drawings include the following figures, wherein like reference numerals refer to like parts throughout, throughout all descriptions and drawings.

1 shows an internal view of the charging system with the charger and the electronic device.

2 shows an internal view of the charger, wherein the charger has an opening in the charger to allow the convection current around the heat sink in the form of a Peltier elements.

3 shows an internal view of the charging device, wherein the charging device comprises a fan for cooling a heat sink in the form of a lamella.

4 shows an internal view of the electronic device that is part of the charging system.

5 shows an internal view of the electronic device, which is part of the charging system, wherein the electronic device comprises a Peltier element and an opening for air introduction and a further opening for the air execution for cooling the battery.

1 shows a charging system consisting of a charger 2 and an electronic device 12 with an internal battery 16 , The charger 2 is used to charge an electronic device 12 with an internal battery 16 inside the device 12 , The charger 2 includes an interface 4 , adapted to the transmission of electricity from the charger 2 to the electronic device 12 , for charging the battery 16 and adapted for heat absorption from the electronic device 12 , The charger 2 further includes a charger connection 6 between the interface 4 and the heat sink 8th to transfer the heat from the electronic device 12 and the heat sink 8th is transferred, and a heat sink 8th for the removal of heat to the surrounding air.

When the charger 2 begins to supply the electrical power to the electronic device 12 for charging the battery 16 to conduct, the battery begins 16 to warm up. The heat generated by this is then removed from the battery 16 to the electronic device 12 and then from there via the interface 4 to the charger 2 transfer. Because the interface 4 Being a good conductor for both electricity and heat can transmit both at the same time.

The charger connection 6 He is also a good leader for both electricity and heat, so he can pass both on efficiently. The charger connection dissipates the heat from the interface 4 to the heat sink 8th and conducts the electrical current to the interface 4 to supply the electronic device 12 , The charger connection 6 may be made of a metal such as aluminum, copper, steel, gold, silver, etc., or any other metals that readily allow the transfer of both heat and electricity. The charger connection 6 This may consist of a combination of these metals, z. In the form of an alloy, in the form of a metal coated with another metal, or in any other structural or functional combination of metals. The charger connection 6 can also consist of such metal oxides, which are good conductors of heat and electricity. In general, any material having sufficient heat conduction property and electric conductivity can be used as a charger terminal 6 be used.

The heat sink 8th works by transferring heat from one surface of the heat sink 8th in contact with the charger connection 6 stands on a surface of the heat sink 8th which is open to the environment. The area in contact with the charger connection has a relatively higher temperature compared to the area that is open to the environment. The heat is further dissipated to the environment around the heat sink 8th through the area that is open to the environment. This further allows the heat transfer from the electronic device 12 to the charger connection 6 , This lowers the temperature of the battery 16 within the electronic device 12 ,

The heat sink 8th has a solid structure; it may also have a hollow structure, or be a structure with some holes on a side surface of the structure, or a porous structure or any other structure covering the contact surface of the heat sink 8th increased to the environment, have. The heat sink 8th may also be a hollow metallic structure, in whose openings a coolant is filled.

The heat sink 8th can be any combination of metals, alloys, metal oxides, Peltier element, metallic structures, or liquid coolant that provides efficient heat dissipation through the heat sink 8th guaranteed in the environment.

The electronic device 12 can to the charger 2 over the interface 4 be connected during charging. When connected, an electric current starts from the charger 2 into the electronic device 12 to flow. Charging starts the battery 16 To generate heat. The heat of the battery 16 gets to the charger 2 over the interface 4 dissipated.

The electronic device 12 consists of a container for batteries 14 and a battery connector 18 , The battery 16 is inside the container for batteries 14 , The electric current flows from the interface 4 to the battery 12 via a battery connection 18 , The same battery connection 18 also transfers the heat from the battery 16 to the interface 4 ,

The battery connection 18 Being a good conductor of electricity and heat, it allows both the transfer of electricity and the transfer of heat. It transfers the heat from the battery 16 off to the interface 4 and passes the electrical current to the battery 16 , According to one embodiment of the invention, the battery connection 18 of metals, for example, aluminum, copper, steel, gold, silver, etc., or any other metals that allow the transfer of both heat and electricity. The battery connection 18 may consist of a combination of metals in the form of an alloy or of a metal with coating of another metal or of any other structural or functional combination of the metals. The battery connection 18 It can also consist of metal oxides, which are good conductors of heat and electricity.

A battery receiving device in the form of a battery compartment 14 takes the battery 16 in the electronic device 12 on. The battery compartment 14 is located in a recess of the device 2 , The battery compartment 14 isolates the battery 16 against an electric current transmission. The battery compartment 16 can also insulate against heat transfer, but it can also be a good conductor of heat to provide better heat transfer by dissipating heat from the electronic device 2 to ensure.

2 shows on a further embodiment, the charger with the heat sink 8th , which includes a Peltier element, and a charger with ventilation slots 26 in a heat exchange relationship with the heat sink 8th stands. Peltier elements are also known as thermoelectric coolers. They are usually compact, and cool efficiently. In addition, they are inexpensive and readily available. The ventilation slots 26 have an inlet for the supply and an outlet for the discharge of air to a convection current around the heat sink 8th to allow around. The ventilation slots 26 thus provide an exchange of warm air around the heat sink with the relatively cooler air outside the charger 2 ,

3 shows on the basis of a further embodiment of the invention, the charging device with the heat sink 8th in the form of a lamella and a fan 10 ,

The slat represents the heat sink 8th a large contact area to the environment available. The larger the contact area with the environment, the better the heat dissipation. The shape of the heat sink 8th is not limited to that of a fin, and may have any shape that increases the area of the heat sink, and thereby the heat dissipation capacity of the heat sink 8th elevated.

The fan 10 keeps the airflow around the heat sink 8th upright, allowing the air around the heat sink 8th always stays at a lower temperature. As the air around the heat sink warms up, the warm air moves around the heat sink to the fan 10 while cold air from the fan 10 upwards into the environment of the heat sink 8th flows. Thus, an air flow around the heat sink 8th built and maintained. The cold air around the heat sink 8th Supports better heat dissipation from the heat sink 8th ,

Instead of the fan 10 It is also possible to use an available lamella or a cooling fan specially designed for use in the supercharger.

4 shows an electronic device 12 as part of a charging system according to 1 , where the electronic device 12 a contact field 22 for contact with a charging pole 20 and with the charger, as previously explained. The contact field 22 favors heat transfer from the battery 16 to the battery connection 18 and the transmission of the electric current from the battery terminal 18 to the battery 16 , The contact field 22 is between the battery 16 and the battery connector 18 positioned.

The contact field 22 covers a significant part of the surface of the Aufpolungspols 20 , The larger the contact area in relation to the environment, the better the heat transfer between the contact field 22 and the battery 16 , The large area coverage through the contact field 22 promotes a better dissipation of heat from the battery 16 ,

The contact field 22 is over the charging pole 20 extends and extends at least partially over an isolated part of the electronic device 12 , Such an extension promotes an increase in the area of the contact field 22 , which gives more heat in the contact field 22 is recorded. In this way it increases the heat transfer from the battery 16 to the contact field 22 ,

The contact field 22 can also from the container for the batteries 14 outside the electronic device 12 protrude. The contact field 22 can also be used as a battery connection 18 act, and heat transfer directly from the battery 16 to the interface 4 as well as the transmission of electrical current from the interface 4 to the battery 16 promote.

5 shows an electronic device 12 out 4 , with a Peltier element 24 and the container for the batteries 14 , with an opening for the air inlet 28 and an outlet for the air outlet 30 , The Peltier element 24 is in a cooling relationship with the battery 16 , The cold surface of the Peltier element 24 is in contact with the battery 16 and takes the heat off the battery 16 due to the conduction and convection of the warm air in the environment of the Peltier element 24 is distributed.

The inlet for the air 28 and the exit port 30 for the outgoing air battery compartment 14 Helps the air convection around the battery 16 around. When the air through the opening 28 flows in, she moves to the battery 16 and the Peltier element 24 where they put warm air around the battery 16 and the Peltier element 24 repressed. The warm air around the battery 16 around and around the Peltier element 24 enters through the corresponding opening 30 out. The Peltier element 24 and the openings 28 . 30 put together a simple solution for cooling the battery 16 within the device. Such a charging system provides rapid battery cooling that in addition to cooling via the heat sink 8th of the charger 2 an additional cooling of the battery 16 guaranteed.

The charger 2 can be designed in the form of a docking station, which is a device for receiving the electrical device 12 having. By mounting in the receptacles similar to the openings 28 . 30 in the electronic device 12 , can create a flow of air around the outside surface of the electronic device 12 be generated, which provides additional cooling of the electrical device 12 and indirectly also the battery 16 provides. This convection flow around the housing of the electrical device 12 can convection within the electrical device 12 amplify, as the air currents outside the electrical device 12 a suction effect on the openings 28 . 30 generated by the electronic device.

The charging system does not need a Peltier element 24 own, but only the openings 28 . 30 an effective and easy solution for cooling the battery 16 offer, in addition to cooling by the heat sink 8th inside the charger 2 , Furthermore, the charging system does not need any openings 28 . 30 instead, it can only be the Peltier element 24 having in a cooling relationship with the battery 16 stands.

The presence of the Peltier element 24 leads to a larger temperature difference that enhances convection. The Peltier element 24 can also be in a cooling relationship with the contact field 22 or the charging pole 20 or with a combination of the charging pole 20 , the battery connection 18 or the contact field 22 stand to the battery 16 cool.

Similar to the battery 16 in the electronic device 12 can also use the electronic device 12 even inside the charger 2 be arranged. In this case would be in 5 the battery 16 through the electronic device 12 and the electronic device 12 through the charger 2 to replace. The electrical device 12 is then cooled with the same means from the outside, as before with respect to the battery 16 described.

In the embodiments described above, the electronic device 12 a hearing aid. The electronic device 12 however, it may also be an mp3 player, a mobile phone, a remote control, an electronic toy, a stationary telephone handset, or other electronic device containing a battery.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• WO 2008/058266 A2 [0004]

Claims (15)

A charger ( 2 ) for charging an electronic device ( 12 ) with an internal battery ( 16 ) comprising: an interface ( 4 ), which is adapted to contact the electronic device ( 12 ), an electrical current to the electronic device ( 12 ) for charging the battery ( 16 ) and the heat from the electronic device ( 12 ); - a heat sink ( 8th ) for the removal of heat; - a charger connection ( 6 ) between the interface ( 4 ) and the heat sink ( 8th ) for transmission from the electronic device ( 12 ) delivered heat to the heat sink ( 8th ). The charger ( 2 ) according to claim 1, further comprising a fan ( 10 ) for cooling the heat sink ( 8th ). The charger ( 2 ) according to one of claims 1 or 2, in which the heat sink ( 8th ) comprises a lamella for dissipating the heat to the environment. The charger ( 2 ) according to one of claims 1 to 3, wherein the heat sink ( 8th ) from a Peltier element ( 32 ) consists. The charger ( 2 ) according to one of claims 1 to 4, wherein the charger connection ( 6 ) is metallic. A charging system comprising: - an electronic device ( 12 ) with an internal battery; - a charger ( 2 ) for charging the electronic device; the charging device ( 2 ) comprises: an interface ( 4 ) for contact with the electronic device ( 12 ), for providing an electrical current to the electronic device ( 12 ) for charging the battery ( 16 ) and to absorb the heat from the electronic device ( 12 ) is adjusted; - a heat sink ( 8th ) for the removal of heat; - a charger connection ( 6 ) between the interface ( 4 ) and the heat sink ( 8th ) for transmission from the electronic device ( 12 ) absorbed heat to the heat sink ( 8th ). The charging system according to claim 6 with a charging device ( 2 ) according to one of claims 1 to 5. The charging system according to one of claims 6 or 7, wherein the electronic device ( 12 ) Comprises: - a battery receiving device ( 14 ) for receiving the battery ( 16 ) in the electronic device ( 12 ); - a battery connection ( 18 ), adapted for transmitting the electrical current from the interface ( 4 ) to the battery ( 16 ) in a battery receiving device ( 14 ), and to transfer the heat from the battery ( 16 ) to the interface ( 4 ). The charging system according to any one of claims 6 to 8, wherein the electronic device ( 12 ) a contact field ( 22 ) adapted for contact with a charging pole ( 20 ) of the battery ( 16 ), for transferring an electric current to the battery ( 16 ) through the charging pole ( 20 ) and to transfer the heat from the battery ( 16 ) to the battery connector ( 18 ). The charging system according to claim 9, wherein the contact field ( 22 ) for contact with a substantial part of the surface of the charging pole ( 20 ) of the battery ( 16 ) is adjusted. The charging system according to one of claims 9 or 10 wherein the contact field ( 22 ) for contact with an electrically isolated surface of the battery ( 16 ) is adjusted. The charging system according to any one of claims 6 to 11, wherein the battery terminal ( 18 ) consists of metal. The charging system according to any one of claims 6 to 12, wherein an electronic device ( 12 ) a Peltier element ( 24 ) for cooling the battery ( 16 ). The charging system according to any one of claims 6 to 13, wherein the battery receiving device ( 14 ) an opening for the incoming air ( 28 ) and an opening for the outgoing air ( 30 ) for generating a convection flow around the battery ( 16 ). The charging system according to any one of claims 6 to 14, wherein the electronic device ( 12 ) is a hearing aid.

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