DE102021100580A1 - Charger for a mobile device - Google Patents

Abstract

A charger for a mobile device comprises a transmission device for electrical energy to the mobile device; and an abutment member having an abutment surface for abutting against the mobile device while electrical power is being transmitted to the mobile device. In this case, the contact element is set up to dissipate thermal energy absorbed on the contact surface from the mobile device.

Description

The present invention relates to a charger for a mobile device. In particular, the invention relates to a charger for use on board a vehicle.

A mobile device includes, for example, a smartphone, a tablet computer or a laptop computer. The mobile device includes electrical energy storage that occasionally needs to be charged to operate the device. Energy storage devices currently in use have large capacities in order to enable long-term operation or the use of a powerful processing device on the mobile device. In order to keep the charging process of the energy store short, a relatively high electrical power must be transmitted from a charging device to the mobile device. The mobile device can heat up in the process, which can be detrimental to the service life of the energy store. Using the heated mobile device can be uncomfortable for a user. If the heating is very strong, for example because the mobile device is exposed to strong sunlight while it is being charged, a safety function that switches off the mobile device or limits an electric charging current can be activated.

An object on which the present invention is based is therefore to specify an improved charging device for charging a mobile device, in particular for use on board a vehicle. The invention solves the problem by means of the subject matter of the independent claims. Subclaims reflect preferred embodiments.

According to a first aspect of the present invention, a charging device for a mobile device comprises a transmission device for electrical energy to the mobile device; and an abutment member having an abutment surface for abutting against the mobile device while electrical power is being transmitted to the mobile device. In this case, the contact element is set up to dissipate thermal energy absorbed on the contact surface from the mobile device.

Conventional mobile devices are often cuboid and relatively thin. It is therefore possible to bring them into contact with the abutment element over a relatively large area. Heat generated in the area of the charging device and/or the mobile device during charging can be dissipated from the mobile device by means of the contact element. This can reduce the heating of the mobile device. As a result, an electrical energy store of the mobile device can be subject to less thermal stress and age less quickly. A user can interrupt the charging process if necessary and use the mobile device immediately without first allowing it to cool down. A power that can be transmitted during charging can be increased. In particular, the charger can be used in an area in which the mobile device is exposed to another heat source, for example direct sunlight. The contact element can be produced inexpensively and can efficiently dissipate the heat in an area between the charging device and the mobile device.

The charging device preferably also includes a heat sink for dissipating thermal energy from the contact element to the surrounding air. For example, the heatsink can be made from a lightweight part so that it has high structural strength while maintaining low thermal resistance. The heat sink can have a structure to increase its surface area, so that heat transfer to the ambient air is improved. A cooling structure can be designed in such a way that a flow of air along the heat sink is promoted. Although it is preferred that the heat sink and the contact element are individual elements, a solution is also conceivable in which the contact element and the heat sink are integrated with one another in one component.

Optionally, the charger can also have a fan for forced ventilation of the heat sink. The fan can in particular have an electric motor with a fan. The electric motor can be controlled by a control device of the charger.

In a further embodiment, a heat pipe is provided for transporting thermal energy from the contact element to the heat sink. The use of a heat pipe can be particularly advantageous when the contact element is not to be arranged directly on the heat sink. A distance of up to approx. 20 cm can be bridged using a heat pipe.

In yet another embodiment, a thermoelectric cooling element is also provided for transporting thermal energy from the contact element to the heat sink. The cooling element can be designed in particular as a Peltier element. An electrical voltage on the cooling element can ensure that a temperature difference between opposite surfaces can be up to approx. 50 to 70 K. A cooler side of the Peltier element can be thermally coupled to the abutment element, while a warmer side can be coupled to the heat sink. By means of a thermoelectric cooling element, a temperature in the area of the system elements can be lowered below a temperature of ambient air.

In a particularly preferred embodiment, the transmission device includes a transmission coil for inductive coupling to a reception coil of the mobile device. The transmission coil can advantageously be integrated with the contact element. The large surface of the contact element to the mobile device can be advantageous in terms of the size of the coils and heat transfer between the mobile device and the charger.

Magnetic centering or mounting of the mobile device relative to the charging device can be provided, particularly in connection with inductive energy transmission. For this purpose, a magnet can be attached on one side and a magnet or magnetic element on the other side, so that the mobile device is moved into a predetermined position relative to the charging device or is held in this position.

It is also preferred that the contact element has a recess for receiving the transmission coil. In this way, a component that can be handled separately can be created, which can be used in an improved manner both to transmit electrical energy to the mobile device and to transmit thermal energy from the mobile device. Thermal energy possibly occurring in the area of the transmission coil can also be dissipated by the contact element.

It is preferred that the contact element can be produced from a thermally conductive elastomer or polymer. In general, the contact element can be made of an electrically non-conductive and preferably magnetically non-susceptible material. An inductive energy transfer cannot be impeded by this, while a thermal energy transfer can be positively influenced.

In a further embodiment, the charging device comprises a control device for controlling a transmitted electrical energy and/or a dissipation of thermal energy from the contact element as a function of a temperature in the area of the charging device. The electrical energy transmitted can be controlled by appropriately controlling the transmission coil. The dissipation of thermal energy can be influenced by controlling the fan or the thermoelectric element accordingly, for example. Improved thermal control of the charger can thus be achieved.

In yet another embodiment, the charger includes communication means for receiving a message indicative of a temperature of the mobile device. Said control can take place depending on the message. In particular, the charger can be controlled in such a way that the mobile device is charged quickly on the one hand and does not overheat on the other.

According to another aspect of the present invention, a vehicle includes a charger as described herein. The vehicle can include an electrical system to which the charger can be electrically connected.

In addition, the vehicle may include a ventilation system with a duct for directing air into an area of the charger. In particular when the charger has a heat sink, the air guided along the heat sink can dissipate heat in an improved manner.

It is particularly preferred that the ventilation system is set up to cool air and direct it into the duct. The ventilation system can be part of an HVAC system (heating, ventilation, air conditioning) of the vehicle. In particular, an air conditioning system in the vehicle can be used to dissipate heat from the charger and ultimately from the mobile device.

• 1 ein Ladegerät mit einem Mobilgerät;
• 2 ein Ladegerät in einer weiteren Ausführungsform

illustriert.The invention will now be described in more detail with reference to the accompanying drawings, in which:

• 1 a charger with a mobile device;
• 2 a charger in another embodiment

illustrated.

1 10 shows a charging device 100 with a mobile device 105. The mobile device 105 can in particular comprise a personal mobile device, for example a smartphone, a tablet computer, a laptop computer or a similar device. The mobile device 105 is usually essentially cuboid. It preferably has two relatively large, flat surfaces that are opposite one another on the mobile device 105 . Mobile device 105 has an electrical energy store and a device for charging it from electrical energy provided.

The charging device 100 is preferably set up to be operated on board a vehicle 110, which in particular can comprise a passenger car or a truck. The charging device 100 is usually connected to an on-board electrical system of the vehicle 110, which usually has a DC voltage in a range of about 12 to about 24 volts. Other voltages are also possible. The charger 100 can be permanently installed on board the vehicle 110 or can be provided as a stand-alone device. For the transmission of electrical energy to the mobile device 105, a transmission device 115 is provided, which can include an electrical plug-in connection, for example.

The charging device 100 preferably includes a contact element 120 with a contact surface 125 for contacting the mobile device 105. In a preferred embodiment, the transmission device 115 includes a transmission coil 130 for inductive coupling to a corresponding receiving coil of the mobile device 105. Although the present invention can in principle also be used with a different, In particular wired connection between the charger 100 and the mobile device 105 is applicable, is assumed in the following from an inductive transmission of electrical energy.

Mobile device 105 can be moved to or held in a predetermined position relative to charger 110 using magnetic force. For this purpose, a magnet can be attached to the charging device 110 and another magnet or a magnetic element can be attached to the mobile device 105 . In particular, on board a vehicle, the mobile device 105 can be held on the charging device 110 in an improved manner against the effect of vibrations or shocks. A surface on which the mobile device 105 lies while being charged on the charging device 110 can be designed in an improved manner, for example curved or edged, so that the mobile device 105 can be seen or gripped in an improved manner.

The charger 110 can be concealed under a cover so that it fits better into an interior. In one embodiment, the charger 110 may be concealed under the cover in an unseen manner. The cover lies between the charging device 110 and the mobile device 105 and can, for example, comprise leather or imitation leather, plastic or wood. The cover can be attached, for example, in a vehicle in the area of a shelf, a center console, a dashboard or an armrest. The cover preferably has good thermal conductivity in order to dissipate heat that may arise when the mobile device 105 is being charged.

A control device 135 can be provided for controlling the charging device 100 . Communication by means of the transmission device 115 can be possible between the control device 135 and the mobile device 105 . A communication signal may be modulated onto transmitted electrical power or a dedicated communication line may be provided. Communication can be unidirectional or bidirectional. In addition, the charging device 100 preferably includes a heat sink 140 which is set up to emit thermal energy from the contact element 120 to an ambient air 145 .

The heat sink 140 preferably rests on the contact element 120 over as large an area as possible. In the preferred embodiment shown, the contact element 120 is sandwiched between the mobile device 105 and the heat sink 140. The contact element 120 can be produced from a plastic, for example, which is preferably electrically insulating and more preferably not magnetizable.

A transfer of thermal energy between the contact element 120 and the heat sink 140 can be improved in different ways. In one embodiment, for example, a thermally conductive element can be used in order to bring about the lowest possible thermal resistance between the contact element 120 and the heat sink 140 . The thermally conductive element can be liquid, pasty or solid. In a further embodiment, one or more thermoelectric cooling elements 150 are provided between the contact element 120 and the heat sink 140 . The cooling element 150 can be designed in particular as a Peltier element. When a predetermined voltage is applied to the cooling member 150, a temperature difference between opposing surfaces can be increased. A cool surface of the cooling element 150 preferably faces the contact element 120 or the mobile device 105 . A warmer surface preferably faces or is in contact with heat sink 140 . An electric current flowing through the cooling element 150 can be controlled depending on a cooling need in the area of the abutment element 120 .

Furthermore, a symbolically drawn heat pipe 155 can be provided in order to transport thermal energy from the contact element 120 to the heat sink 140 . The heat pipe 155 comprises a tube filled with a fluid and having a warmer end and a colder end. The fluid can vaporize at the warmer end, absorbing heat of vaporization. The gaseous fluid can be transported to the cooler end and condense there, releasing condensation energy. The fluid can then circulate back to the warm end. In order to promote the circulation, a material can be provided in the tube which causes the transport on the basis of the capillary effect. Depending on prevailing conditions and requirements, the heat pipe 155 can be sized and the fluid can be chosen to match a temperature in the system elements 120 not to rise above a predetermined threshold.

The ambient air 145 can flow freely around the heat sink 140 or a fan 160 can be provided which generates a flow of ambient air 145 and preferably guides it along the heat sink 140 in a predetermined manner. The ambient air 145 can also be guided into an area between the charging device 110 and the mobile device 105 . An intermediate cover may be solid, perforated, or porous to improve ambient air 145 distribution. The fan 160 for conveying ambient air 145 can be included in the charger 100 or in the vehicle 110 . In one embodiment, the vehicle 110 includes a duct 165 through which ambient air 145 can flow. The ambient air 145 can preferably be cooled, in particular by means of an air conditioning system of the vehicle 110. The air conditioning system can include an air conditioning compressor, a heat pump or an evaporation system. Optionally, instead of a gaseous cooling fluid, a liquid cooling fluid of the air conditioning system can also be routed into the area of the channel 165 to absorb heat. In one specific embodiment, control device 135 is set up to determine a request for a volume flow and/or a temperature of flowing ambient air 145 and to transmit it to vehicle 110 . The vehicle 110 may be configured to provide an appropriate flow of ambient air 145 to the charger 100 .

2 shows a charger 100 in a further embodiment. The charger 100 shown is shown in longitudinal section and constructed essentially like the charger 100 of FIG 1 . The mobile device 105 can be placed on the charging device 100 so that it has the largest possible contact with the contact element 120 . In the present embodiment, the transmission coil 130 is arranged between the contact element 120 and the heat sink 140 . The contact element 120 and/or the heat sink 140 can have a recess in which the transmission coil 130 can be accommodated. In a further embodiment, the transmission coil 130 can be completely integrated into the contact element 120, for example by the transmission coil 130 being cast or overmoulded.

Two thermoelectric cooling elements 150 are also provided, for example, between the contact element 120 and the heat sink 140 . Purely by way of example, the cooling elements 150 are arranged in opposite positions with respect to the transmission coil 130 . In another embodiment, for example, a cooling element 150 can also be attached inside the transmission coil 130 . For this purpose, the cooling element 150 should be neither electrically conductive nor magnetizable, if possible.

In the present embodiment, the heat sink 140 has significantly smaller cooling fins than in FIG 1 illustrated embodiment. The heat sink 140 can be forced ventilated, for example, by means of a fan 160, which can be provided below the heat sink 140, ie on a side facing away from the contact element 120. By way of example, an axial fan is provided, which can be located in particular in the area of the transmission coil 130 .

Reference List

100

charger

105

mobile device

110

vehicle

115

transmission facility

120

investment element

125

contact surface

130

transmitter coil

135

control device

140

heatsink

145

ambient air

150

thermoelectric cooling element (Peltier element)

155

heat pipe

160

Fan

165

channel

Claims (13)

Charger (100) for a mobile device (105), the charger (100) comprising: - a transmission device (115) for electrical energy to the mobile device (105); - A contact element (120) with a contact surface (125) for contact with the mobile device (105), while electrical energy is transmitted to the mobile device (105); - Wherein the contact element (120) is set up to derive thermal energy absorbed on the contact surface (125) from the mobile device (105). Charger (100) after claim 1 , Further comprising a heat sink (140) for dissipating thermal energy from the contact element (120) to an ambient air (145). Charger (100) after claim 2 , Further comprising a fan (160) for forced ventilation of the heat sink (140). Charger (100) after claim 2 or 3 , Further comprising a heat pipe (155) for transporting thermal energy from the contact element (120) to the heat sink (140). Charger (100) after one of claims 2 until 4 , Further comprising a thermoelectric cooling element (150) for transporting thermal energy from the contact element (120) to the heat sink (140). Charger (100) according to any one of the preceding claims, wherein the transmission device (115) has a transmitting coil (130) for inductive coupling to a receiving coil of the mobile device (105). Charger (100) after claim 6 , wherein the contact element (120) has a recess for receiving the transmission coil (130). Charger (100) according to any one of the preceding claims, wherein the abutment element (120) can be produced from a thermally conductive elastomer or polymer. Charger (100) according to one of the preceding claims, further comprising a control device (135) for controlling a transmitted electrical energy and / or a dissipation of thermal energy from the contact element (120) depending on a temperature in the area of the charger (100). Charger (100) according to any one of the preceding claims, further comprising communication means (130) for receiving a message indicative of a temperature of the mobile device (105). Vehicle (110) comprising a charger (100) according to any one of the preceding claims. vehicle (110) to claim 11 , further comprising a ventilation system (160) with a duct (165) for guiding air (145) into an area of the charger (100). vehicle (110) to claim 12 , The ventilation system (160) being set up to cool air (145) and to guide it into the duct (165).

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