BE1020190A3 - A CHARGING DEVICE FOR WIRELESS CHARGING AN EXTERNAL BATTERY. - Google Patents

Abstract

A charging device (1) for wirelessly charging an external battery, which comprises a primary circuit (10) capable of generating a variable electromagnetic field, the external battery being electrically connected to a secondary circuit capable of converting a variable electromagnetic field into a variable electric current, wherein the charging device (1) comprises connecting means (7) for connecting the charging device (1) to a power source and wherein the primary circuit (10) is electrically connected to the connecting means (7), the charging device (1) also is a lighting device in that it is provided with a light source (4) to illuminate at least a part of a space in which the light source (4) is electrically connected to the connecting means (7).

Description

A charging device for wirelessly charging an external battery.

The present invention relates to a charging device for wirelessly charging an external, i.e. non-charging, battery.

More specifically, the invention relates to a charging device comprising a primary circuit, for example a coil, capable of generating a variable electromagnetic field, the external battery being provided with or electrically connected to a secondary circuit, for example also a coil connected externally to the charging device and which can convert a variable electromagnetic field into an electric current.

Here, the secondary circuit may, for example, be integrated into the battery or be externally attached to the battery or may form part of a device in which the battery is inserted and make electrical contact, for example a mobile telephone, or be provided in a casing arranged around a battery and in electrical contact therewith.

The battery can now be charged through inductive coupling between the two circuits.

Such charging devices are known, but are not widely used for many devices because they are much more expensive than traditional charging devices in which a battery is coupled directly to a charging device.

A disadvantage of almost all charging devices, wireless or not, for batteries is related to the fact that a typical user nowadays has a large number of devices that are provided with a rechargeable battery. These devices with their batteries can have a wide variety of charging devices, which differ in the size of their connections, the voltage supplied and the current supplied.

As a result, the user must have many different charging devices, which essentially have the same function.

This is of course disadvantageous from a cost point of view. Also the use of scarce raw materials for the large amount of charging devices, and the environmental problems associated with the end-of-life processing of these charging devices are the greater the more charging devices are required.

Standardization of charging devices and batteries for devices can overcome some of these disadvantages.

This also applies to the use of 'universal' chargers whose charging voltage can be adjusted and which have connections with many different formats. However, these are complex, consist of various interchangeable parts that can easily be lost and have the risk that an incorrect charging voltage is set.

A further disadvantage is that a user of devices with a battery, when moving, must have a charging device available at any location.

As a result, a large number of charging devices must be provided, or a charging device for each device must be taken along with each movement, which is certainly a significant disadvantage when using a large number of devices. In addition, when used in countries other than the user's home country, adapters are often required to connect the charging devices to the electricity grid.

These charging devices also occupy a socket when used, while often the number of free sockets in a room, especially in a hotel room, is limited. This has disadvantages with regard to the shared use of several devices in a room, and with regard to the costs, safety risks and the sloppy appearance of known solutions such as branch boxes.

The present invention has for its object to provide a solution to at least one of the aforementioned and other disadvantages in that it provides a charging device for wirelessly charging an external battery by means of inductive coupling, which comprises a primary circuit comprising a variable electromagnetic field can generate, wherein the external battery is provided with or is electrically connected to a secondary circuit external to the charging device and which can convert a variable electromagnetic field into an electric current, the charging device comprising connecting means to the charging device with an external electrical current source and wherein the primary circuit is electrically connected to the connecting means, wherein the charging device is also a lighting device in that it is provided with a light source to illuminate at least a part of a space in which the light source or a holder therefor is electrically connected to the connecting means.

A lighting device is hereby considered as a device intended to provide sufficient light to at least partially illuminate a room and thereby make the room usable for persons to carry out the desired activities, even when no or insufficient daylight enters. for example, a standing lamp or a desk lamp.

Since luminaires are widely present, and are generally connected to the electricity grid, both in homes, hotels, offices, and many other locations, this has the advantage that there is no need for an additional free socket to have a wireless charging device, and it is no longer necessary for a user of devices with rechargeable battery to take the charging device with them when traveling to another location.

Also, in this way, various components of a traditional lighting device and a traditional charging device, such as the connection means to the electricity grid, such as a plug, the cords, fuses, housings, switches, can be shared, whereby a cost saving is achieved during production, less scarce resources used and less future waste is generated.

Packaging and distribution can also be shared, resulting in cost savings and environmental benefits.

In a preferred embodiment, the light source is of the solid-state lighting type.

This is a type of light source that includes LED, OLED (organic LED) and PLED (polymer LED), where light is generated by electroluminiscence from an electronic component.

This type of light source has a much higher light output, and a much longer lifespan than traditional incandescent bulbs.

In practice, a solid state lighting type of light source requires a transformer or other type of voltage transformer to get from the mains to the required voltage.

In a further preferred embodiment, the charging device therefore comprises voltage converting means for converting the voltage from the external electric current source to a lower direct voltage and, both the primary circuit, and the light source or the holder therefor, are electrically connected to the connecting means via the voltage converting means .

A specific advantage of this preferred embodiment is therefore that an even higher cost saving is possible, because the required voltage transforming means for the light source and for the charging device can largely be shared, whereby a large saving is achieved, both financially and environmentally, because fewer raw materials used and less waste is produced.

This also has the advantage that it makes it possible to switch off the entire combination of charging device and lighting device in an easy manner, thus including the voltage converting means that also consume energy when no power is required by the light source or the primary circuit, manually or automatically or put to sleep, saving energy.

With the insight to better demonstrate the features of the invention, a few preferred embodiments of a charging device according to the invention are described below as an example without any limiting character, with reference to the accompanying drawings, in which:

Figure 1 schematically and in perspective shows a partially cut-away charging device according to the invention; Figure 2 is a block diagram showing the main components of the charging device of Figure 1; Figure 3 shows a block diagram showing the most important components of an alternative charging device according to the invention;

The wireless charging device 1 shown in figures 1 and 2 essentially comprises a base 2 with which the charging device 1 can support on a surface, for example a floor or table, and a lighting part 3 provided with a number, in this case, but not necessarily , five, LEDs 4 which serve as a light source, and which can provide sufficient light to illuminate a space or a part thereof. The lighting part 3 is connected to the base 2 by means of a rod 5 through which a wire runs.

The base 2 is connected by means of a cord 6 to connecting means, in this case in the form of a plug 7, to connect the charging device 1 to an electricity network.

The base 1 mainly consists of a housing 8 on which a charging area 9 is indicated. This charging area 9 can be indicated in different ways, for example by a different color or because it is formed as a slight depression in the housing 8. The charging area 8 should preferably be a flat or slightly cup-shaped part of the charging device 1.

Below this charging area 9, inside the housing 8, there are six primary circuits 10 in the form of coils, which are electrically connected to and controlled by a control unit 12 provided with control lights 11, which are also inside the housing 8.

This control unit 12 is adapted to communicate with a secondary circuit provided by a battery (not shown) that can convert a variable electromagnetic field into a current, and is adapted to control the primary circuits 10 on the basis of that communication.

Further inside the housing 8 are voltage converting means 13, for example in the form of a transformer with rectifier, an on-off switch 14, in this example provided with means for putting the charging device into sleep mode automatically or manually, and a dimmer 15 , which includes a switch to completely reduce the transmitted current to zero.

The voltage transforming means 13 serve to convert the voltage received by the charging device 1 into a lower direct voltage which is usable both for the control unit 12 and for the LEDs 4, possibly after further conversion into further voltage converters (not shown).

The dimmer 15 and the switch 14 have operating buttons.

The cord 6 is electrically connected to the switch 14. The switch 14 is electrically connected to the voltage converting means 13, the voltage converting means 13 are electrically connected in parallel to both the dimmer 15 and the control unit 12 and the dimmer 15 is electrically connected to the lighting part 3, more precisely with the LEDs 4. This last connection can be directly with these LEDs 4, or with holders for replaceable LEDs 4, with which LEDs 4 can in turn be electrically connected.

There is thus an electrical connection between the connecting means 7 and the primary circuits 10 and between the connecting means 7 and the LEDs 4 or the holders therefor, wherein both connections run via the voltage converting means 13.

The charging device 1 can alternatively be seen as a charging device whose components, such as the voltage transforming means 13, the primary circuits 10, and the control unit 12 form a lighting device.

The operation of the charging device 1 is very simple and as follows.

The charging device 1 is connected to an electricity grid by plugging in the plug 7 into a socket and is switched on by operating the on-off switch 14.

A low voltage DC is now generated by means of the voltage converting means 13, which is supplied via the dimmer 15 to the LEDs 4 in the lighting part 3. As a result, the LEDs 4 give light and the amount of light can be adjusted, so that the charging device 1 acts as a lighting device for the illumination of at least a part of a room.

The low voltage generated by the voltage converting means 13 is also supplied to the control unit 12.

As soon as a battery, or a device provided with a battery, is placed on the charging area 9, the control unit 12 determines by means of generating a variable current which is converted by the primary circuits 10 into a variable electromagnetic field, and the determining the effect thereof on the battery, whether the battery is suitable for being charged with the charging device 1.

This will generally be the case if the battery is provided with or is electrically connected to a secondary circuit, for example a coil, which can convert a variable electromagnetic field into an electrical current and if the combination of battery and secondary circuit meets a standard according to which the charging device 1 is adapted to work.

If the battery proves to be suitable, a charging process will start, in which the control unit 12 applies a variable current to the primary circuits 10, whereby a variable electromagnetic field is generated, from which the secondary circuit can again generate a current for charging the battery.

During the charging process, communication takes place between the charging device 1 and the battery, in order to be able to adapt the charging conditions to the battery and its charging status.

The selective use of only one or a few of the primary circuits 10 present, for example as a function of the location of the battery to be charged, can be set by the control unit.

Charging can be monitored by the control lights 11 and malfunctions can be detected.

If there is no need for lighting or charging, the charging device 1 can put itself into sleep mode to save energy.

Figure 3 shows a variant of a charging device 1 according to the invention, which differs from the charging device 1 described above in that combined connection and voltage converting means 16 are used, more specifically a transformer with an integrated plug, the combined connection and voltage converting means 16 being used as are entirely suitable and intended to be plugged into an outlet and are located at a distance from the base 2.

The variant of Figure 3 is not provided with a general on-off switch 14, and therefore cannot switch itself off, but can only be switched off by pulling the combined connection and voltage converting means 16 from the socket.

An on-off switch can still be integrated in the dimmer 15 for the operation of the LEDs 4 only.

The operation of this variant is as described above, with the difference that the functionalities that are linked to parts that are not present are of course not available.

Optionally, additional connectors, for example USB connectors, can be provided on a charging device 1 according to the invention, which are electrically connected to the voltage converting means 13 and used to charge further batteries connected to the charging device 1 via a cable.

The charging device 1 can also optionally be provided with a battery which can for instance be charged at a cheap nightly rate, and then allow the charging device to work partly or completely temporarily without taking energy from the electricity grid at that moment, or which can serve as an emergency provision for the increase operational reliability.

This battery can then also be used for the energy supply of a module to remove the charging device from a sleep mode, or from a clock or alarm.

For this reason, the charging device can also be provided with a solar cell, which could also be used to determine a lighting requirement as a function of the amount of ambient light.

The present invention is by no means limited to the exemplary embodiment (s) described and shown in the figures, but a charging device according to the invention can be realized in all shapes and dimensions without departing from the scope of the invention.

Claims (11)

A charging device (1) for wirelessly charging an external battery by means of inductive coupling, which comprises a primary circuit (10) capable of generating a variable electromagnetic field, the external battery being provided with or electrically connected to a secondary circuit external to the charging device (1) and capable of converting a variable electromagnetic field into an electric current, the charging device (1) comprising connecting means (7) for connecting the charging device (1) to an external electrical current source and wherein the primary circuit (10) is electrically connected to the connecting means (7), characterized in that the charging device (1) is also a lighting device in that it is provided with a light source (4) to illuminate at least a part of a space in which the light source (4) whether a holder therefor is electrically connected to the connecting means (7). A charging device (1) according to claim 1, characterized in that the primary circuit (10) comprises a coil. A charging device (1) according to claim 1 or 2, characterized in that the secondary circuit comprises a coil. A charging device (1) according to any one of the preceding claims, characterized in that the external electric power source is an electricity network. A charging device (1) according to one of the preceding claims, characterized in that the light source (4) is of the solid-state lighting type. A charging device (1) according to any one of the preceding claims, characterized in that the primary circuit (10) is electrically connected to the connecting means (7) via a control unit (12), the control unit (12) means to communicate with an external battery to be charged so that charging conditions can be adjusted. A charging device (1) according to any one of the preceding claims, characterized in that it comprises a base (2) with which it rests on a surface or with which it can be attached to a structure and comprises a lighting part (3) in which the primary circuit ( 10) is in the base (2). A charging device (1) according to any one of the preceding claims, characterized in that it comprises voltage converting means (13) for converting the voltage from the external electric current source to a lower direct voltage and that both the primary circuit (10) and the light source (4) or the holder therefor are electrically connected via the voltage converting means (13) to the connecting means (7). A charging device (1) according to claim 8, characterized in that the voltage transforming means (13) are located in the base (2). A charging device (1) according to claim 8 or 9, characterized in that it is provided with means for putting the charging device (1) into sleep mode if no battery is being charged and the light source is switched off. A charging device (1) according to one of the preceding claims, characterized in that a flat or cup-shaped part (9) is arranged in the vicinity of the primary circuit (10) which is suitable for inserting or inserting at least one external battery. which is provided with or is electrically connected to a secondary circuit which is external to the charging device (1) and which can convert a variable electromagnetic field into an electric current.