DE202017007203U1 - System for monitoring and remotely controlling a state of charge of at least one battery pack - Google Patents

Abstract

System (1) for monitoring and remotely controlling a state of charge of at least one battery pack (2, 3), comprising the at least one battery pack (2, 3) for an electrical device (7), which has a communication device (4, 5) designed for this is to transmit state of charge data of the battery pack (2, 3) to a server device (8) of the system (1), which is designed to transmit the state of charge data to at least one user interface (9) of the system (1), which is designed to to visualize the charge status data of the battery pack (2, 3), the user interface (9) also being designed to transmit control data for controlling a charger (6) to the server device (8), which is designed to do so, depending on a user input , to transmit the control data to the communication device (4, 5) integrated in the battery pack (2, 3), which is designed to transmit the control data for a charging process of the battery pack (2, 3) to be transferred to the charger (6).

Description

The present invention relates to a system for monitoring and remotely controlling a state of charge of at least one battery pack.

Despite all the advantages, battery-operated electrical devices have a very decisive disadvantage compared to wired electrical devices in the form of the limited battery life or battery capacity in combination with the usually relatively long charging times. A crucial aspect for users of such battery-operated electrical devices is in particular the availability of the electrical devices. If the tank of a gasoline-powered device can be filled within a very short time, a 5.2 amp hour battery, for example, first has to be placed in a charging cradle for around two hours before it is fully charged.

One can assume that batteries are rarely stored completely discharged. But even with a residual charge of 50 percent, for example, you can usually assume that, for example, a battery-operated lawn mower with such a battery can no longer be used to completely mow a conventionally large lawn area. If the battery in question is then fully charged or at least sufficiently charged, the sun may have already set. Any increase in battery capacity or the associated battery life is simply subject to certain technical, physical and cost-related limits.

It is the object of the present invention to provide a solution by means of which the availability of battery-operated electrical devices can be increased.

This object is achieved by a system for monitoring and remotely controlling a state of charge of at least one battery pack with the features of the independent claims. Advantageous refinements with expedient and non-trivial developments of the invention are specified in the dependent claims.

The system according to the invention for monitoring and remotely controlling a state of charge of at least one battery pack comprises the at least one battery pack for an electrical device. The battery pack has a communication device which is designed to transmit state of charge data of the battery pack to a server device of the system, which is designed to transmit the state of charge data to at least one user interface of the system. The user interface is designed to visualize the charge status data of the battery pack. In addition, the user interface is designed to transmit control data for controlling a charger to the server device as a function of a user input made at the user interface. This is in turn designed to transmit the control data to the communication device integrated in the battery pack. The communication device integrated in the battery pack is in turn designed to transmit the control data for a charging process of the battery pack to the charger.

Alternatively, it can also be provided according to the invention that a system for monitoring and remotely controlling a state of charge of at least one battery pack has the at least one battery pack for an electrical device which has a communication device which is designed to transmit state of charge data of the battery pack to a server device of the system . The other features mentioned above can also be purely optional in this case. In the simplest case, it is sufficient if the state of charge data reaches the server and the system is at least designed for this.

The battery pack itself preferably comprises an interconnected package of a plurality of battery cells which are constructed, for example, on a lithium-ion basis. Other types of batteries are also possible. The battery cells of the battery pack are preferably connected to the communication device of the battery pack for energy supply. If the battery cells are not emptied, this can ensure at any time that the communication device of the battery pack can be supplied with energy, so that permanent data transmission between the server device and the communication device can be ensured.

The system according to the invention is based on the finding that the runtime of a battery-operated electrical device is often not really the decisive factor even for users. A much more crucial aspect for many users is simply the availability of a battery-operated electrical device at a certain point in time. The system according to the invention contributes to preventing users from even getting into a situation in which they are faced with discharged batteries.

This is achieved on the one hand by the fact that the communication device integrated in the battery pack can preferably continuously transfer state of charge data of the battery pack to the server device of the system, the server device in turn being able to transmit this state of charge data to the at least one user interface of the system. A user can use the User interface, which is designed to visualize the state of charge data, at any location and thus at any distance from the battery pack concerned to recognize how fully the battery pack is currently charged. In addition, the system according to the invention offers the possibility of remote control of said charger.

If the user recognizes from the user interface that the battery pack that he wants to use, for example, in an electric lawnmower in a few hours does not have the required charge status, for example to completely mow his lawn, he can make a corresponding entry via the user interface, as a result the user interface can generate said control data for controlling the charger and can transmit it to the server device. From the server device, these control data for driving the charger in turn reach the communication device of the battery pack, which is designed to transmit the control data to the charger during the charging process.

On the one hand, by means of the system according to the invention, it is therefore possible for a user in a simple way to plan his work, in which the battery pack is required, and the charging processes necessary for this in advance. On the other hand, the remote control of the charger means that the battery pack can also be charged remotely in good time without having to be on site. The battery pack must be plugged into the charger or, in the case of an inductive charger, must be located in the vicinity of the charger, but the start and end of the charging process can be easily controlled remotely via the user interface. It is not necessary for the user to be near the charger in order to remove the battery pack from the charger when it is fully charged in order to protect it from being overcharged. Because just as well as the user can activate the charger via the user interface, he can also deactivate the charger remotely if he recognizes via the user interface that the battery pack in question has been fully charged or at least as far as the user wishes.

The linchpin of these monitoring and remote control functions is the communication device integrated in the battery pack. Via this communication device, it is possible on the one hand that data relating to the battery pack, in particular the charge status data of the battery pack, can reach the user interface via the server device, on the other hand the battery pack also serves as a type of access point via which the charger can be remotely controlled. The communication device of the battery pack is designed and set up accordingly to establish a data connection to the charger. In the simplest case, this data connection can be wired, with a wireless connection also being possible as an alternative or in addition, of course.

The communication device of the battery pack is preferably set up to maintain a permanent data connection between the charger and the server device, preferably via an Internet connection. The system according to the invention therefore has the advantage that, on the one hand, a user can be informed at any time about the state of charge of the battery pack, on the other hand the user can also initiate remote control of a charging process of the battery pack. This optimally supports the user in ensuring the availability of the battery pack for a wide variety of work and areas of application.

The system according to the invention can also be designed such that it has one or more plugins for a wide variety of apps. For example, the user interface can be integrated into an app in the form of such a plug-in. For example, the WeChat app is currently very widespread, especially among Chinese-speaking people. For example, the system according to the invention could offer a plug-in for such an app. Services and functions made possible by the system according to the invention could then be integrated into such an app via the plug-in. Of course, it is also possible that an independent app is offered for the system in addition or as an alternative.

• - LoRaWAN;
• - Symphony Link;
• - LTE-M;
• - NarrowBand-loT;
• - Weightless-N;
• - Weightless-P;
• - Weightless-W;
• - Wi-Fi HaLow;
• - WavIoT NarrowBand Fidelity;
• - SigFox;
• - Random Phase Multiple Access.

An advantageous embodiment provides that the communication device of the battery pack is designed to send the data to and receive data from the server device via a low power wide area network. The communication device is preferably set up to use at least one of the following standards or technologies for transmitting and receiving the data via the low power wide area network:

• - LoRaWAN;
• - Symphony Link;
• - LTE-M;
• - NarrowBand-loT;
• - Weightless-N;
• - Weightless-P;
• - Weightless-W;
• - Wi-Fi HaLow;
• - WavIoT NarrowBand Fidelity;
• - SigFox;
• - Random phase multiple access.

For this purpose, the communication device comprises, for example, a radio module which is designed to send and receive the said data via a low power wide area network. With regard to the reception and transmission of data, the communication device is therefore virtually independent of the range. In principle, the physical connection between various end devices, such as the battery pack and other end devices, can take place via license-free frequencies of the radio spectrum or mobile radio frequencies, the connection between gateways and network servers being able to take place, for example, via IP connections.

A further advantageous embodiment of the invention provides that the communication device is also designed to send and / or receive the above-mentioned data and / or other data via a wireless local area network and / or via a Bluetooth connection. The communication device preferably comprises radio modules designed accordingly, for example a WLAN radio module and / or a Bluetooth radio module.

If the battery pack is used, for example, in the area of a home network, the communication device of the battery pack can dial into the home network. Using such a wireless local area network, large amounts of data can be received and sent quickly and easily. In a home network, for example, WIRELESS INTERNET ACCESS a software update for the battery pack or the relevant electrical device can be easily downloaded and installed using the battery pack. In this case, the battery pack serves as an access point for a cloud-based update. The battery pack is preferably set up to carry out a viral update of a respective firmware of the battery pack or of the electrical device in which the battery pack is inserted. For this purpose, the battery pack, preferably the communication device of the battery pack, is set up to check whether the firmware installed on it and the firmware installed on the electrical device are at the same version, for example as soon as the battery pack has been inserted into the electrical device. The communication between the battery pack and the electrical device preferably takes place via a bus system of the electrical device and / or the battery pack. The battery pack is set up to automatically download new firmware for the battery pack from a cloud if the firmware of the battery pack is of an older version than that of the electrical device. In addition, the battery pack is set up to automatically download new firmware for the electrical device from a cloud if the firmware of the electrical device is of an older version than that of the battery pack. The battery pack and the electrical device are therefore almost automatically infected when used together with regard to the latest firmware. The electrical device can also be understood to mean, for example, the charger. This ensures that the battery pack and the electrical device are operated on the same software version. As a result, the latest functions can always be used with both the battery pack and the electrical device, and the correct communication between the battery pack and the electrical device can be ensured.

In a further advantageous embodiment of the invention, it is provided that the communication device of the battery pack is designed to transmit status data relating to a temperature of the battery pack, fault memory entries of the battery pack and / or a state of health of the battery pack to the server device, which is designed to transmit the status data to the user interface, which is designed to visualize the data. A user of the battery pack can thus constantly view all relevant data and parameters relating to the status of the battery pack from a distance. If necessary or at least requested by him, he can also control the charging process from a distance, for example if he should recognize that the temperature of the battery pack should be too high, certain errors occur on the battery pack and the like. If necessary, the user can simply end a charging process, for example. In addition, he can also remotely monitor at any time how the battery pack is doing, whether the state of health of the battery pack is critical or whether other errors have occurred. This also helps to increase the availability of the battery pack.

In a further advantageous embodiment of the invention, it is provided that the server device is designed to transmit a request for charging the battery pack to a user interface as a function of weather data, appointment entries in an electronic calendar of a person, the charge status data of the battery pack and / or the status data , which is designed to visualize this request. The system is therefore preferably designed to assist a user in planning and carrying out charging processes in good time. Is, for example, stored in the server device in a person-related manner that a certain person Battery pack or other battery packs used for certain types of garden equipment, such as a lawnmower, among other things, so weather data can be included to automatically determine when the best time to mow would be. Alternatively or additionally, for example, the person's appointment entries can be checked in their electronic calendar in order to compare them with the weather forecast, so that a possible appointment can be suggested automatically, for which the person would still have time to mow the lawn in optimal weather conditions. In particular in combination with the charge status data of the battery pack and possibly also in combination with the status data of the battery pack, the server device can thus provide optimal support for notifying the person concerned via the user interface, for example via a push notification, when a charging process is taking place of the relevant battery pack or several battery packs should be started. This also helps to significantly increase the availability of the battery pack. In addition, it is also possible to recognize from calendar entries that the person in question, for example, will not be at home for the next four. In such a case, for example, a charging lever of the battery pack, that is to say the SOC, can be reduced to 40%, for example. This can reduce the aging of the battery pack.

A further advantageous embodiment of the invention provides that the user interface is in the form of an app for a mobile terminal, in particular for a smartphone and / or for a tablet computer. So users can easily use their smartphone, which they usually carry with them, for example to monitor the charge status of battery packs and to control charging processes remotely. Likewise, it is very convenient, for example, to use the said user interface via a tablet computer. The user interface or also a further user interface can also be designed in the form of a graphical user interface for a web browser. This has the advantage that the user interface can be used independently of devices. For example, a person can dial in on any computer via the respective web browser and use the user interface to monitor and remotely control the charge status of the battery pack. This can be done, for example, in a manner known per se by logging in and entering a corresponding password on an operator side of a company which provides the system as such.

According to a further advantageous embodiment of the invention, it is provided that the communication device is designed to transmit data relating to a remaining charging time of the battery pack to the server device, which is designed to transmit the data to the user interface, which is designed to be based on of the data to visualize the remaining charging time. The user interface can therefore be used to easily see how much time will pass before the battery pack is fully charged. For technically interested users, information about a charging current or other charging parameters can also be transmitted and displayed, for example. In particular, knowing the remaining charging time of the battery pack, a person concerned can schedule any further appointments in such a way that they arrive at the charger just in time when the battery pack is fully charged. If, for example, several battery packs belong to the system, the person can thus easily use one or more battery packs in certain electrical devices, for example in a battery-operated lawn mower, a battery-operated hedge trimmer or the like. At the same time, he can see via the user interface, for example via an app on his smartphone, when another battery pack that is currently in the charger will be fully charged. For example, in gardening or other activities, it is conveniently possible to plan work perfectly so that work can be carried out as uninterrupted as possible, since the user always knows when certain battery packs will be fully charged.

In a further advantageous embodiment of the invention, it is provided that the communication device is designed to transmit occupancy data relating to occupancy of the charger to the server device, which is designed to visualize on the basis of the occupancy data how many battery packs are arranged in the charger. If the charger has a large number of slots for a large number of battery packs, it can be advantageous if a user can see at any time how many of his battery packs are currently arranged in his charger. This simplifies the search for battery packs and also helps to increase the availability of the respective battery packs.

In a further advantageous embodiment of the invention, it is provided that the communication device is designed to transmit data regarding a remaining runtime of the battery pack to the server device, which is designed to transmit the data to the user interface, which is designed to use the Data to visualize the remaining runtime. A user can also easily see from a distance how the remaining battery life is. To determine the remaining runtime can be taken into account, for example, in which electrical devices the battery pack may be used. In this context, it is preferably also possible for various remaining runtimes of the battery pack to be displayed, depending on what type of electrical device the battery pack is used in. For example, for those electrical devices that the user has, it can be displayed how the remaining battery runtimes are. For example, a user can recognize that a certain runtime would still be possible for mowing the lawn using the battery pack, it also being possible to indicate that if the battery pack was used to operate a battery-powered drill, for example, a completely different runtime would be available and the like. Depending on what the user wants to use his battery pack for later, he can decide based on the remaining runtime whether he should charge the battery pack or not. This also helps to increase the availability of the battery pack.

A further advantageous embodiment of the invention provides that the server device is designed to transmit control data for discharging and charging the battery pack to the communication device integrated in the battery pack, which is designed to transmit the control data for a discharging and charging process, in accordance with a predefinable schedule transfer the battery pack to the charger. This has the advantage that the charger can also be used, for example, as a permanent storage option for one or more battery packs. The service life and the performance of the battery packs can be increased by the automatic, cyclical discharge and charging of the battery packs concerned. If, for example, the battery packs are mainly used in electrical garden tools, the battery packs could simply remain in the charger over the winter even if they are not used for a long time. In this case, the server device would ensure that automated remote control for discharging and charging the battery packs takes place, so that the service life of the battery packs can be extended as a result. If the battery packs are used again in the spring, it can be ensured that they are in the best possible condition, especially with regard to their state of health. This also increases the availability of one or more battery packs in the system. In particular, a charge level of one or more battery packs can also be reduced to a low level, e.g. to 40% SOC using the charger to reduce calendar aging while the battery packs are not used for a long time anyway. The server device is accordingly designed to generate suitable control data and to transmit it to the charger via the communication device integrated in the battery pack. The at least one battery pack can also be designed to receive information from the charger and transmit it to the server device.

According to a further advantageous embodiment of the invention, it is provided that the server device is designed to transmit the state of charge data to a communication device of a further battery pack, which is designed to visualize the state of charge data, in particular to indicate whether the other battery pack is fully charged. As an alternative or in addition, the additional battery pack can also be designed to emit sounds and / or to output haptic feedback depending on the charge status data. If the additional battery pack is used, for example, in a garden tool, the user can see while working with this garden tool whether the other battery pack inserted in the charger is already fully charged or what the state of charge is. For example, in gardening, it is not necessary for a user to have a look at the user interface, e.g. on his smartphone or the like. Instead, while working with an electrical device in which he has inserted the additional battery pack, he can easily read from it when the other battery pack that is being charged is fully charged.

The charger according to the invention is designed to interact with the system according to the invention or an advantageous embodiment of the system according to the invention, the charger having a controller which is designed to receive the control data from the communication device of the battery pack and to charge the device as a function of the control data Taxes. In addition, the control of the charger is also designed to receive all the other data mentioned above and to process them accordingly.

The monitoring and remote control of a state of charge of at least one battery pack takes place by means of the system according to the invention or by means of an advantageous embodiment of the system according to the invention, the communication device transmitting state of charge data of the battery pack to the server device, which transmits the state of charge data to the user interface, which visualizes the state of charge data of the battery pack.

Furthermore, depending on a user input, the user interface transmits control data for controlling the charger to the server device, which transfers the control data to the communication device integrated in the battery pack, which transfers the control data for a charging process of the battery pack to the charger.

Further advantages, features and details of the invention result from the following description of preferred exemplary embodiments and from the drawing. The features and combinations of features mentioned above in the description and the features and combinations of features shown below in the description of the figures and / or in the figure alone can be used not only in the respectively specified combination but also in other combinations or alone, without the scope of the invention to leave.

The drawing shows in the single figure a highly schematic representation of a system for monitoring and remotely controlling the charge status of several battery packs.

A system 1 for monitoring and remote control of the respective charge status of several battery packs 2 . 3 is shown highly schematized in the single figure. The two battery packs shown here 2 . 3 have respective communication facilities 4 . 5 on, the functionality of which will be discussed in more detail later. The one battery pack 2 is currently in a charger 6 inserted, the other battery pack 3 into an electrical device 7 is plugged in. With the electrical device 7 can be any electrical device.

For example, the electrical device 7 are a hand tool in the form of a cordless screwdriver, a cordless drill, a cordless circular saw or the like. It can also be the electrical device 7 also act on any battery-operated garden tools, such as, for example, battery-operated leaf blowers, battery-operated grass shears, battery-operated scarifiers, battery-operated lawn mowers or the like. It can be just as good with the electrical device 7 also act as a battery-operated household appliance of any kind. Basically, it can be the electrical device 7 are dealing with any kind of electrical equipment in which the battery packs 2 . 3 can be used.

To the system 1 also includes a server facility 8th and at least one user interface 9 , The user interface 9 can be formed, for example, by a smartphone app that can be operated on any smartphone. Contrary to the present representation, the system 1 any other such user interfaces 9 have, which can also be, for example, an app for a tablet computer, a browser-based graphical user interface and the like.

• - LoRaWAN.
• - Symphony Link;
• - LTE-M;
• - NarrowBand-IoT;
• - Weightless-N;
• - Weightless-P;
• - Weightless-W;
• - Wi-Fi HaLow;
• - WavIoT NarrowBand Fidelity;
• - SigFox;
• - Random Phase Multiple Access.

Both communication facilities 4 . 5 the battery packs 2 . 3 are designed to send a wide variety of data to the server device via a low power wide area network 8th to send and receive from this. The communication facilities 4 . 5 can use a wide variety of standards or technologies for sending and receiving data over the Low Power Wide Area Network, for example the following:

• - LoRaWAN.
• - Symphony Link;
• - LTE-M;
• - NarrowBand-IoT;
• - Weightless-N;
• - Weightless-P;
• - Weightless-W;
• - Wi-Fi HaLow;
• - WavIoT NarrowBand Fidelity;
• - SigFox;
• - Random phase multiple access.

The communication facilities 4 . 5 the battery packs 2 . 3 are preferably also also designed to transmit the data to the server device directly or indirectly - in this case with the interposition of other devices - via a wireless local area network and / or via a Bluetooth connection 8th transferred to.

The whole system 1 is used to determine the respective charge status of the battery pack 2 . 3 to monitor and control remotely. Both communication facilities 4 . 5 the battery packs 2 . 3 are designed for the respective charge status data of the battery packs 2 . 3 to the server facility 8th transferred to. The server setup 8th is designed to send this state of charge data to the user interface 9 of the system 1 transferred to. For example, a user can recognize on his smartphone at any time from an app that serves as the user interface, as is the state of charge of the two battery packs 2 . 3 is ordered.

The user interface also offers 9 the possibility that a user uses the charger 6 can control remotely. This is the user interface 9 designed to have one or more to record related user input and, depending on this, control data for controlling the charger 6 to the server facility 8th transferred to. The server setup 8th is in turn designed to transfer this control data - in the case shown here - to the battery pack 2 integrated communication device 4 transferred to. This is designed to send the control data to a control system for charging the battery pack 10 of the charger 6 transferred to.

A user can thus easily recognize from a distance, for example, what the charge levels of the respective battery packs are 2 . 3 is ordered per se. It can also remotely use the user interface 9 quite simply the charger 6 activate the battery pack 2 charge.

Is it, for example, the electrical device 7 a lawnmower in which the battery packs 2 . 3 can be used, for example, the user can still be seated at work while browser-based or also via his smartphone using the user interface 9 check how the charge levels of each battery pack 2 . 3 is ordered. In addition, it can also be provided that the server device 8th is designed to depend on weather data, event entries in an electronic calendar of the person concerned and the charge status data of the battery packs 2 . 3 a prompt to charge the battery pack 2 . 3 to the user interface 9 to transmit, which is designed to visualize this request. So the user can be optimally supported, the appropriate availability of the battery packs 2 . 3 ensure for the time when he is actually using the electrical device 7 want to mow his lawn.

In addition, the communication facilities 4 . 5 also be designed to provide status data regarding a temperature of the battery packs 2 . 3 Error memory entries of the battery packs 2 . 3 and / or a respective state of health of the battery packs 2 . 3 to the server facility 8th which is designed to transmit the status data to the user interface 9 to transmit, which then visualizes this data accordingly.

In addition, in the case shown here, for example, the communication device 4 of the battery pack 2 also a remaining charging time of the battery pack 2 capture and appropriate data to the server facility 8th which in turn transmit this data to the user interface 9 transmits. The user can therefore see from a distance, for example on his smartphone or at another suitable location, how long it will take for the battery pack 2 is fully charged. The system 1 So offers a very convenient and reliable way to remotely different data regarding the battery packs 2 . 3 , in particular with regard to their respective charge status and to initiate remote-controlled charging processes. This can result in a particularly high availability of the battery packs 2 . 3 be ensured.

It is also possible that the respective communication facilities 4 . 5 the battery packs 2 . 3 are designed to provide occupancy data relating to occupancy of the charger 6 to the server facility 8th to transmit which this data in turn to the user interface 9 transmits. For example, it is possible that the respective battery packs 2 . 3 independently recognize whether they are currently in the charger 6 are plugged in and this information to the server device 8th and ultimately also to the user interface 9 transfer. Alternatively or in addition, it is also possible for the charger 6 itself has a corresponding communication device, not shown here, which is designed to determine its occupancy status with regard to the currently inserted battery packs 2 . 3 to the server facility 8th and thus also to the user interface 9 transferred to. Either way, a user can remotely see at any time how many of their battery packs 2 . 3 just in his charger 6 are plugged in. So he can easily see how many of his battery packs 2 . 3 he could even charge from a distance.

Furthermore, the respective communication devices 4 . 5 the battery packs 2 . 3 also be designed to provide data regarding a remaining runtime of the respective battery pack 2 . 3 to the server facility 8th and also to the user interface 9 transferred to. Via the user interface 9 a user can then see how long he has the battery packs 2 . 3 can still use at all without charging them beforehand. Ideally, for example, is on the server device 8th stores what types of electrical devices the user is actually using. In that case, it would also be possible to have different run times for the respective electrical device types for the different battery packs 2 . 3 using the user interface 9 going out. Depending on the types of electrical equipment the user wants to use, he can then use this information to decide whether to use his battery packs 2 . 3 better recharge from a distance.

In addition, it is also possible that the server device 8th according to the example shown here, is able to display the state of charge data relating to the battery pack 2 to the communication device 5 the other battery pack 3 to transmit, which is designed to visualize the state of charge data, in particular to indicate whether the battery pack 2 is fully charged. The battery pack can do that 3 (just like the other battery pack 2 ) have a display. Alternatively, it would also be possible, for example, for the battery packs 2 . 3 simply have a correspondingly suitable status light, which lights up either red, yellow or green, depending on how fully charged the other battery pack is 2 respectively 3 is straight. Furthermore, it would also be possible for the electrical device 7 has a corresponding display, which can show what the charging status of the charger is 6 inserted battery packs 2 is ordered.

In addition, it is also possible for the server device 8th is designed to control data for discharging and charging to the battery packs according to a predefinable schedule 2 . 3 , more precisely to their communication facilities 4 . 5 , transferred to. Once the battery packs 2 . 3 with the charger 6 are connected, the communication devices transmit 4 . 5 the battery packs 2 . 3 this control data in turn to the control 10 of the charger 6 which is then used for cyclical discharging and charging of the battery packs 2 . 3 used. This makes it possible, even if the battery packs are not used for a long time 2 . 3 this in the charger 6 to be plugged in, with the cyclical and automatic discharging and charging of the battery packs 2 . 3 their lifespan and their performance can be increased. Will the battery packs 2 . 3 For example, mainly used for garden tools, it could happen that the battery packs 2 . 3 not used at all in the winter months. The battery packs 2 . 3 could then be in the charger all the time during the winter months 6 remain plugged in, the server device 8th ensures that the battery packs 2 . 3 from time to time something can be discharged and charged in such a way that the state of health of the battery packs 2 . 3 remains at the highest possible level.

The system 1 and the corresponding method for monitoring and remotely controlling the charge status of the battery packs 2 . 3 using the system 1 thus contribute to the availability of battery packs in a particularly simple manner 2 . 3 can also be ensured remotely by a user by providing appropriate information regarding the battery packs 2 . 3 using the user interface 9 provided and also via the user interface 9 also charging processes for the battery packs 2 . 3 be made possible by remote control.

Reference list

1

system

2

Battery pack

3

Communication device of the battery pack

4

additional battery pack

5

Communication device of the additional battery pack

6

charger

7

Electrical appliance

8th

Server setup

9

User interface

10

control

Claims (14)

System (1) for monitoring and remotely controlling a state of charge of at least one battery pack (2, 3), comprising the at least one battery pack (2, 3) for an electrical device (7), which has a communication device (4, 5) designed for this is to transmit state of charge data of the battery pack (2, 3) to a server device (8) of the system (1), which is designed to transmit the state of charge data to at least one user interface (9) of the system (1), which is designed to to visualize the charge status data of the battery pack (2, 3), the user interface (9) also being designed to transmit control data for controlling a charger (6) to the server device (8), which is designed to do so, depending on a user input , to transmit the control data to the communication device (4, 5) integrated in the battery pack (2, 3), which is designed to transmit the control data for a charging process of the battery pack (2, 3) to be transferred to the charger (6). System (1) according to Claim 1 , characterized in that the communication device (4, 5) of the battery pack (2, 3) is designed to send and receive the data via a low power wide area network to the server device (8). System (1) according to Claim 2 , characterized in that the communication device (4, 5) is set up to use at least one of the following standards or technologies for sending and receiving the data via the low power wide area network: - LoRaWAN. - Symphony Link; - LTE-M; - NarrowBand-IoT; - Weightless-N; - Weightless-P; - Weightless-W; - Wi-Fi HaLow; - WavIoT NarrowBand Fidelity; - SigFox; - Random phase multiple access. System (1) according to one of the preceding claims, characterized in that the communication device (4, 5) of the battery pack (2, 3) is also designed to transmit the data and / or other data via a wireless local area network and / or send and / or receive a Bluetooth connection. System (1) according to one of the preceding claims, characterized in that the communication device (4, 5) of the battery pack (2, 3) is designed to store status data relating to a temperature of the battery pack (2, 3), fault memory entries of the battery pack (2, 3) and / or a state of health of the battery pack (2, 3) to the server device (9), which is designed to transmit the status data to the user interface (9), which is designed to visualize the data . System (1) according to one of the preceding claims, characterized in that the server device (8) is designed, depending on weather data, date entries in an electronic calendar of a person, the charge status data of the battery pack (2, 3) and / or the status data to transmit a request for charging the battery pack (2, 3) to the user interface (9), which is designed to visualize this request. System (1) according to one of the preceding claims, characterized in that the user interface (9) is designed in the form of an app for a mobile terminal, in particular for a smartphone and / or for a tablet computer. System (1) according to one of the preceding claims, characterized in that the user interface (9) or a further user interface is designed in the form of a graphical user interface for a web browser. System (1) according to one of the preceding claims, characterized in that the communication device (4, 5) is designed to transmit data relating to a remaining charging time of the battery pack (2, 3) to the server device (8), which is designed to do so to transmit the data to the user interface (9), which is designed to visualize the remaining charging time on the basis of the data. System (1) according to one of the preceding claims, characterized in that the communication device (4, 5) is designed to transmit occupancy data relating to occupancy of the charger (6) to the server device (8), which is designed to transmit the occupancy data to the user interface (9), which is designed to visualize on the basis of the occupancy data how many battery packs (2, 3) are arranged in the charger (6). System (1) according to one of the preceding claims, characterized in that the communication device (4, 5) is designed to transmit data relating to a remaining runtime of the battery pack (2, 3) to the server device (8), which is designed to do so to transmit the data to the user interface (9), which is designed to visualize the remaining runtime on the basis of the data. System (1) according to one of the preceding claims, characterized in that the server device (8) is designed to control data for discharging and charging the battery pack (2, 3) integrated in the battery pack (2, 3) according to a predefinable schedule Transfer communication device (4, 5), which is designed to transmit this control data for a discharging and charging process of the battery pack (2, 3) to the charger (6). System (1) according to one of the preceding claims, characterized in that the server device (8) is designed to transmit the state of charge data to a communication device (5) of a further battery pack (3) which is designed to visualize the state of charge data, in particular to indicate whether the other battery pack (2) is fully charged. Charger (6) which is designed to interact with a system (1) according to one of the preceding claims, wherein the charger (6) has a controller (10) which is designed to transmit the control data from the communication device (4, 5 ) of the battery pack (2, 3) and to control a charging process depending on the control data.

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