DE102020102010A1 - Method and system for wireless charging of smart home devices - Google Patents

Abstract

Providing an energy transmission unit at a first spatial position, wherein the energy transmission unit is connected to a power source and wherein the energy transmission unit at least comprises
a processor for processing algorithms and executing control commands,
an interface to a power supply,
an antenna arrangement for transmitting and receiving electromagnetic waves;
Providing a smart home device at a second spatial position, the smart home device at least comprising
another processor for processing algorithms and executing control commands,
another antenna arrangement for transmitting and receiving electromagnetic waves;
an energy storage unit;
Bringing the energy transmission unit and the smart home device into a common smart home network,
wherein the energy transmission unit, as a central control unit, coordinates intelligent energy charging management for the smart home device in the smart home network.

Description

The invention relates to a method and a system for charging smart home devices in a smart home network, the smart home devices being operated in particular with a rechargeable battery and / or batteries, whereby the smart home devices are flexibly connected can be used anywhere in the household. Such smart home devices generally do not have an interface to a power grid, which has the consequence that the rechargeable batteries and / or batteries have depleted all of their energy after some time and therefore the smart home devices must continue to be replaced can work.

This problem is known, for example, in radio radiator thermostats, which are usually supplied with energy by means of batteries or accumulators. This energy is used, on the one hand, for communication within the smart home network (if the radio radiator thermostat is informed of the switch-on and switch-off times of the radiator) and, on the other hand, to operate an electric servomotor for the heating, whereby usually the greater proportion of energy is used for the operation of the electric servomotor. Such products are offered by Telekom with DECT radio, eQ-3, or other manufacturers, for example. Due to the high energy consumption, it is necessary that the battery must be changed at certain intervals, usually within 1-2 years. However, this disadvantageously causes very high maintenance costs. At the same time, a freely accessible battery compartment offers the risk of manipulation and removal of the batteries, e.g. because the batteries are currently being used in another device. This creates enormous costs, especially in the hotel industry. The disadvantage of residential real estate is frequent service calls to the landlord or the caretaker, which is why housing companies do not invest in such smart home technologies, although they can be useful for the ancillary rental costs, the environment and the general comfort of the resident.

In practice, some methods for charging or operating the smart home devices are proposed. One possibility is to generate energy from the environment, for example from a temperature difference between the hot water of the heating system and the ambient temperature. The disadvantage here is on the one hand dependent on environmental parameters that cannot be influenced and on the other hand there are a number of smart home devices that are not connected to a hot water source.

Another possibility is that solar cells are built into the smart home device. However, these solar cells are usually too inefficient and it is usually not possible to ensure that smart home devices have enough sunlight available for the solar cells, even inside rooms. In many cases, such solar cells can be integrated in or on the household appliance to be controlled in such a way that the solar cells are shielded from sunlight.

In addition, methods are known in which the electromagnetic radiation from a WLAN router is used during data transmission to charge a smart home device. To ensure that the smart home device is continuously charged, the WLAN router continuously emits electromagnetic waves. If there is no data transmission, the WLAN router sends a noise signal.

The object of the invention is to specify a method and a system that enable a smart home device to be charged efficiently, as a result of which the impairment of residents is minimized.

This method is achieved with the features of the independent claims.

• • Bereitstellen einer Energie-Sende-Einheit an einer ersten räumlichen Position, wobei die Energie-Sende-Einheit mit einer Stromquelle verbunden wird und wobei die Energie-Sende-Einheit zumindest umfasst einen Prozessor zur Verarbeitung von Algorithmen und zum Ausführen von Steuerungsbefehlen, eine Schnittstelle zu einer Stromversorgung, eine Antennenanordnung zum Senden und Empfangen von elektromagnetischen Wellen;
• • Bereitstellen eines Smart-Home-Geräts an einer zweiten räumlichen Position, wobei das Smart-Home-Gerät zumindest umfasst einen weiteren Prozessor zur Verarbeitung von Algorithmen und zum Ausführen von Steuerungsbefehlen, eine weitere Antennenanordnung zum Senden und Empfangen von elektromagnetischen Wellen; eine Energiespeichereinheit;
• • Einbringen der Energie-Sende-Einheit und des Smart-Home-Geräts in ein gemeinsames Smart-Home-Netzwerk.

According to the invention, a method for charging smart home devices is specified, which comprises the following steps:

• • Providing an energy transmission unit at a first spatial position, wherein the energy transmission unit is connected to a power source and wherein the energy transmission unit comprises at least one processor for processing algorithms and for executing control commands, an interface to a power supply, an antenna arrangement for transmitting and receiving electromagnetic waves;
• • Providing a smart home device at a second spatial position, the smart home device comprising at least one further processor for processing algorithms and for executing control commands, a further antenna arrangement for transmitting and receiving electromagnetic waves; an energy storage unit;
• • Bringing the energy transmission unit and the smart home device into a common smart home network.

Because the energy transmission unit is connected to the power supply, in particular a 230 volt power supply, it is independent of external environmental conditions and can be continuously supplied with power and this power also by means of the antenna arrangement in the form of electromagnetic waves or electromagnetic radiation send. The antenna arrangement can be implemented in such a way that it is formed by a single antenna or by a plurality of antennas. The processor controls the emission of the electromagnetic radiation. It is here advantageously possible to vary the wavelength of the electromagnetic radiation. The smart home device, which is provided in the second position, in particular in a household, receives the electromagnetic radiation of the energy transmission unit by means of its further antenna arrangement and can convert this into energy but also process data by means of the further processor, which are sent by the energy transmission unit with the electromagnetic radiation. The converted energy is stored in an energy storage unit of the smart home device. The energy storage unit is preferably a rechargeable battery. In the context of the invention, the term smart home network for two devices, in the present case the energy transmission unit and the energy transmission unit, means that the two devices are set up so that they can communicate with one another - preferably via electromagnetic radiation.

The essence of the invention is that the energy transmission unit, as a central control unit, coordinates intelligent energy charging management for the smart home device in the smart home network. The other processor of the smart home device can determine the charge status of the energy storage unit. As a result, an algorithm implemented on the further processor of the smart home device causes the further antenna arrangement of the smart home device to send a charge request to the energy transmission unit via the shared smart home network. In the case of only one smart home device and only one energy sending unit, the charge request is transmitted directly to the energy sending unit. The energy transmission unit receives the charging request via its antenna arrangement, which is processed by the algorithm and a control command is subsequently executed which causes the antenna arrangement of the energy transmission unit to send electromagnetic radiation to the further antenna arrangement of the smart device as required. Home device that converts the electromagnetic radiation into energy and charges the energy storage unit. The charging request can also contain further information such as a preferred charging frequency or a required amount of energy so that the charging process can be managed intelligently. This enables the smart home device to be charged in a targeted, effective and resource-saving manner. The charging process is no longer dependent on environmental parameters and also no longer runs in an ineffective continuous operation.

The electromagnetic waves or the electromagnetic radiation are preferably sent in the microwave range. This has the advantage, on the one hand, that microwave transmitters are now quite inexpensive and available in compact designs, while on the other hand it is known how microwave radiation can be transmitted in a directed manner. Another advantage of microwave radiation is that it is able to spread relatively effectively into a shadow area behind an object by means of diffraction. If the antenna arrangement is located some distance in front of a plate and the further antenna arrangement is some distance behind this plate, the microwave radiation is more or less able to get from the antenna arrangement around the plate to the further antenna arrangement.

A WLAN router, a smart home adapter plug and / or a smart home lamp is advantageously used as the energy transmission unit. The WLAN router has the advantage that it is normally available in a household anyway and is used to set up or set up the smart home network. In terms of hardware, conventional WLAN routers are usually designed in such a way that they can take over the functions of the central control unit or the energy transmission unit if a corresponding algorithm is implemented on the processor. In most cases, these WLAN routers also have an antenna arrangement with several antennas, so that the electromagnetic radiation can be emitted in a directional manner. However, it is known that the radiation energy decreases inversely with the square of the distance. As a result, a single wireless router is very ineffective for charging a large number of smart home devices that are spread across an entire house. For this purpose, smart home adapter plugs and / or smart home lamps can be used, which are also integrated into the smart home network and placed in close proximity to the smart home devices. As a central control unit, the WLAN router can determine which smart home adapter plug or which smart home lamp is used is near the smart home device that sent a charge request. The central control unit then specifically determines the smart home adapter plug or the smart home lamp that is located near the smart home device for emitting the electromagnetic radiation that charges the smart home device.

The intelligent energy charging management preferably determines the efficiency with which a smart home device is charged. For this purpose, measured values can be stored in a memory of the smart home device or the central control unit, for example, which indicate the amount of energy that is transmitted to the smart home device from the electrical radiation of the energy transmission unit over a defined period of time. These values can be exchanged between the smart home device and the central control unit via the smart home network and compared with one another by the central control unit. If such a comparison reveals that the smart home device is being charged particularly ineffectively at a certain point in time, for example because an object has blocked the radiation, the intelligent energy charging management can interrupt the charging process for a certain period of time and then restart. The charging process can be canceled and restarted as often as required until the smart home device is charged with a previously defined efficiency.

This advantageously prevents energy from being consumed unnecessarily and inefficiently, while at the same time reducing the radiation exposure.

The first spatial position of the energy transmission unit and / or the second spatial position of the smart home device can preferably be determined by a radiation characteristic of the energy transmission unit or the smart home device and / or the first spatial and / or the second spatial position can be entered by a user via a web portal. For this purpose, the processors have an algorithm which is configured in such a way that the antenna arrangements can execute a position determination program which enables the central control unit to collect sufficient information in order to determine the respective spatial position. Alternatively, for example, a floor plan of the user's apartment can be uploaded via the web portal, whereby the user can mark the individual positions of the devices in the floor plan and designate the devices. This offers the advantage that it can be made known in a simple manner at which spatial positions the respective energy transmission units and / or smart home devices are located. The intelligent energy charging management can now control the charging process of a smart home device in a targeted manner. It is particularly advantageous here if the closest energy transmission unit charges the smart home device.

In a preferred embodiment, a plurality of energy transmission units and / or a plurality of smart home devices are introduced into the smart home network, as a result of which a mesh network is formed. Mesh networks have the advantage that the individual energy transmission units and / or smart home devices incorporated into the mesh network can “work together” in a coordinated manner. This offers the possibility of selecting whether several energy transmission units transmit the electromagnetic radiation with low transmission power in a coordinated manner to the smart home device or whether the electromagnetic radiation is transmitted with high transmission power so that a maximum of energy transmission takes place and the smart home device charges in less time. In addition, this creates the possibility that the smart home devices are not only supplied with energy by the energy transmission units, but that neighboring smart home devices can share energy with one another and / or forward energy. If, for example, the state of charge of a certain smart home device is sufficiently high, it can send part of its energy to another smart home device, in particular if this other smart home device is or is out of the range of energy-sending units would only be charged by these very inefficiently.

The energy transmission units and / or the smart home devices preferably each have an identification code assigned to them and send this to the central control unit via the smart home network. This offers the advantage that the central control unit can determine particularly efficiently which energy transmission unit is transmitting with which radiation characteristic and which smart home device requests a specific charging process. The tasks can then be distributed particularly efficiently using the intelligent energy charge management.

In a preferred embodiment, the antenna arrangement of the energy transmission unit and / or the further antenna arrangement of the smart home device can map different types of transmission topologies and / or the mesh network can map different types of transmission topologies. In particular, this is possible with antenna arrangements that have several “individual” antennas. In the context of this application, different types of transmission topologies are to be understood as meaning that different points in a room can be flexibly covered with variable radiation powers. In the mesh network, for example, by coordinating the individual energy transmission unit, it can be achieved that a first smart home device receives twice as much electrical radiation as a second smart home device. If necessary, the However, conditions can also be reversed, so that the first smart room device receives only half of the electrical radiation as the second smart home device.

• eine Energie-Sende-Einheit an einer ersten räumlichen Position, wobei die Energie-Sende-Einheit umfasst
• eine Schnittstelle zum Anschluss an eine Stromversorgung,
• einen Prozessor zur Verarbeitung von Algorithmen und zum Ausführen von Steuerungsbefeh len,
• eine Antennenanordnung zum Senden und Empfangen von elektromagnetischen Wellen;
• ein Smart-Home-Geräts an einer zweiten räumlichen Position, wobei das Smart-Home-Gerät zumindest umfasst
• einen weiteren Prozessor zur Verarbeitung von Algorithmen und zum Ausführen von Steuerungsbefehlen,
• eine weitere Antennenanordnung zum Senden und Empfangen von elektromagnetischen Wellen;
• eine Energiespeichereinheit;
• ein Smart-Home-Netzwerk geeignet zum Einbringen der Energie-Sende-Einheit und des Smart-Home-Geräts in das Smart-Home-Netzwerk, wobei
• die Energie-Sende-Einheit als eine zentrale Steuereinheit für ein intelligentes Energie-Auflade-Management ausgebildet und das Smart-Home-Gerät in dem Smart-Home-Netzwerk koordiniert.

According to a second aspect of the invention, there is provided a system for charging smart home devices which is suitable for carrying out the method described above, the system comprising:

• an energy transmission unit at a first spatial position, the energy transmission unit comprising
• an interface for connection to a power supply,
• a processor for processing algorithms and executing control commands,
• an antenna arrangement for transmitting and receiving electromagnetic waves;
• a smart home device at a second spatial position, wherein the smart home device comprises at least one
• another processor for processing algorithms and executing control commands,
• another antenna arrangement for transmitting and receiving electromagnetic waves;
• an energy storage unit;
• a smart home network suitable for introducing the energy transmission unit and the smart home device into the smart home network, wherein
• the energy transmission unit is designed as a central control unit for intelligent energy charging management and the smart home device is coordinated in the smart home network.

According to a third aspect of the invention, an energy transmission unit for charging smart home devices is specified, which is suitable and designed for carrying out the method described above.

• Die Figur zeigt das erfindungsgemäße Verfahren zum Aufladen von Smart-Home-Geräten in einem Smart-Home-Netzwerk in einem Wohnraum.

In the following, preferred exemplary embodiments of the present invention are explained with reference to the accompanying figure:

• The figure shows the method according to the invention for charging smart home devices in a smart home network in a living room.

In the following, numerous features of the present invention are explained in detail on the basis of preferred embodiments. The present disclosure is not limited to the specifically mentioned combinations of features. Rather, the features mentioned here can be combined as desired to form embodiments according to the invention, unless this is expressly excluded below.

The figure shows a living room 1 of a user, the living space 1 walls 5 which are impermeable or highly attenuating to electromagnetic radiation. In the flat 1 The first energy transmission unit is a WLAN router 10a provided, which also functions as a central control unit for intelligent energy charging management. A first smart home lamp is used as a second and third energy transmission unit 10b and a second smart home lamp 10c intended. The first smart home devices are wireless radiator thermostats 15a , a second wireless radiator thermostat 15b , a third wireless radiator thermostat 15c , a fourth wireless radiator thermostat 15d , a fifth wireless radiator thermostat 15f and a sixth wireless radiator thermostat 15f intended. The dashed lines 20th symbolize the directional paths of the electromagnetic radiation that are sent by the respective antenna arrangements of the energy transmission units and the smart home devices. By means of the dashed lines 20th The energy transmission units and the smart home devices can also communicate with each other and in this way form a meshed smart home network. In order to do justice to both functionalities, the dashed lines 20th as send paths for the sake of simplicity 20th designated.

• Das erste Funk-Heizkörperthermostat 15a überprüft den Ladezustand seines Akkus und stellt fest, dass dieser wieder aufgeladen werden soll und sendet dementsprechend eine Ladeaufforderung über den Sendepfad 20 an den WLAN-Router 10a. Da der WLAN-Router 10a die einzige Energie-Sende-Einheit ist, die sich in der Nähe des Funk-Heizkörperthermostat 15a befindet, sendet nur der WLAN-Router 10a Mikrowellenstrahlung zum Aufladen an das Funk-Heizkörperthermostat 15a.

The procedure is explained in detail below:

• The first wireless radiator thermostat 15a checks the charge status of its battery and determines that it should be recharged and accordingly sends a charge request via the transmission path 20th to the wireless router 10a . Since the wireless router 10a the only energy-sending unit is located near the wireless radiator thermostat 15a only sends the wireless router 10a Microwave radiation for charging to the wireless radiator thermostat 15a .

The wireless radiator thermostats also transmit 15b , c a loading request via the send path 20th to the wireless router 10a . In this case, however, is the first smart home lamp 10b at a similar distance to the wireless radiator thermostats 15b , c like the wireless router 10a so that both of them efficiently use microwave radiation for charging to the wireless radiator thermostats 15b , send c. The decision as to which energy transmission units contribute to charging is made by the central control unit in the WLAN router 10a which either knows the spatial position of the respective smart home devices or determines this using a suitable algorithm based on the radiation characteristics of the respective antenna arrangement.

The radio radiator thermostat 15d determines that the charge status of its battery is still sufficient and as a result does not request a charge.

The radio radiator thermostats 15e , f both need to recharge their batteries. However, both are wireless radiator thermostats 15e , f due to the radiopaque walls 5 in some kind of the wireless router 10a shielded that they do not have a direct transmission path 20th can communicate with it. However, this is made possible by the formed mesh network. The radio radiator thermostat 15f sends its charge request via the radio radiator thermostat 15e , the second smart home lamp 10c and the first smart home lamp 10b to the wireless router 10a . The energy charging management knows, based on the spatial positions and a charging efficiency analysis, that the second smart home lamp 10c the radio radiator thermostat 15f due to the radiopaque wall 5 cannot charge directly. In this case, the central control unit has the radio radiator thermostat 15e on the radio radiator thermostat by means of its antenna arrangement 15f to charge. This enables smart home devices that are not connected to a power supply to be charged flexibly and efficiently.

The wireless router 10a and the smart home lamps 10b , c can send electromagnetic radiation in the range of 2.4 GHz for communication and charging. For this purpose, the transmission power of the respective energy transmission unit can be in the range from 0.1 watt to 1 watt. The energy charging management ensures that the energy sending units do not consume or send more power than the smart home devices need or request. A conventional WLAN router, which emits a power of 100 milli-watts at a frequency of 2.4 GHz, is suitable for the process. The WLAN router can send the electromagnetic radiation for charging via a channel specially set up for this purpose, or the WLAN router uses a conventional data channel if there is no other data traffic from a user, such as video streaming.

Since many people have concerns about excessive radiation exposure (keyword: electrosmog), the charging processes of the smart home system can be started or stopped depending on the presence or absence of people. Where people are located can be detected using smart home cameras or other sensors and via the smart home network to the WiFi router 10a be transmitted. If such a sensor, i.e. a presence detector, transmits the status “person is absent”, the charging process can start.

However, an emergency program can also be activated in the central control unit so that charging also takes place when people are in the house and if there is otherwise a risk that the battery condition of one of the smart home devices will become critical. In this case, however, the intelligent energy charging management determines that only this one critical smart home device is charged and the charging of the other smart home devices is postponed to a later point in time when the people are absent.

Claims (10)

A method for charging smart home devices comprising the steps of providing an energy transmission unit (10a, 10b, 10c) at a first spatial position, the energy transmission unit (10a, 10b, 10c) being connected to a power source and wherein the energy transmission unit (10a, 10b, 10c) comprises at least one processor for processing algorithms and for executing control commands, an interface to a power supply, an antenna arrangement for transmitting and receiving electromagnetic waves; Providing a smart home device (15) at a second spatial position, the smart home device (15) comprising at least one further processor for processing algorithms and for executing control commands, a further antenna arrangement for transmitting and receiving electromagnetic signals Waves; an energy storage unit; Bringing the energy transmission unit (10a, 10b, 10c) and the smart home device into a common smart home network, characterized in that the energy transmission unit (10a, 10b, 10c) as the central control unit an intelligent energy charging management for the smart home device (15) coordinated in the smart home network. Procedure according to Claim 1 , characterized in that electromagnetic waves in the microwave range are used. Method according to one of the preceding claims, characterized in that a WLAN router, a smart home adapter and / or a smart home lamp is used as the energy transmission unit (10a, 10b, 10c). Method according to one of the preceding claims, characterized in that the intelligent energy charging management determines the efficiency with which a smart home device (15) is charged. Method according to one of the preceding claims, characterized in that the first spatial position of the energy transmission unit (10a, 10b, 10c) and / or the second spatial position of the smart home device is determined by a radiation characteristic of the energy transmission unit (10a, 10b, 10c) or the smart home device (15) is determined and / or that the first spatial and / or the second spatial position is entered by a user via a web portal. Method according to one of the preceding claims, characterized in that several energy transmission units (10a, 10b, 10c) and / or several smart home devices (15) are introduced into the smart home network, and that thereby a Mesh network is formed. Procedure according to Claim 6 , characterized in that the energy transmission units (10a, 10b, 10c) and / or the smart home devices (15) each have an identification code assigned to them and send this to the central control unit via the smart home network . Method according to one of the preceding claims, characterized in that the antenna arrangement of the energy transmission unit (10a, 10b, 10c) and / or the further antenna arrangement of the smart home device (15) map different transmission topologies and / or that the Mesh network maps different transmission topologies. System for charging smart home devices suitable for carrying out a method according to Claims 1 - 8th comprising an energy transmission unit (10a, 10b, 10c) at a first spatial position, the energy transmission unit (10a, 10b, 10c) comprising an interface for connection to a power supply, a processor for processing algorithms and for executing control commands, an antenna arrangement for transmitting and receiving electromagnetic waves; a smart home device (15) at a second spatial position, wherein the smart home device (15) comprises at least one further processor for processing algorithms and for executing control commands, a further antenna arrangement for transmitting and receiving electromagnetic waves ; an energy storage unit; a smart home network suitable for introducing the energy transmission unit (10a, 10b, 10c) and the smart home device (15) into the smart home network, characterized in that the energy transmission unit (10a, 10b, 10c) designed as a central control unit for intelligent energy charging management and coordinated the smart home device (15) in the smart home network. Energy transmission unit designed to charge smart home devices and designed to carry out a method according to Claims 1 - 8th .

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