CH702483A2 - Power supply station for supplying power to an electrical load. - Google Patents

Abstract

The energy supply station according to the invention for supplying energy to an electrical consumer comprises an energy converter (26) which has a supply input (25) which can be connected to a power grid (1) and a supply output (31) which can be connected to the consumer (13). In addition, the power supply comprises a controller (27) which is designed and operable such that it detects at least one energy parameter of the connected consumer (13) and, depending thereon, specifies a corresponding control signal (Uref; Iref) for the energy converter (26).

Description

Technical area

The invention relates to a power supply station for supplying energy to an electrical load and a method for operating the power supply station.

State of the art

Fig. 1 shows a schematic diagram of how different electrical loads are charged so far. For example, if the battery of a camera 9 to be charged, the camera 9 is connected via a charging cable 8.1 to the power outlet of a suitable charger 8. The mains connection of the charger 8 in turn is connected, for example via a multiple socket 3 and a power cord 2 to the power grid 1. In addition, if, for example, the battery of a mobile phone 10 is to be charged, the mobile phone 10 is connected via a charging cable 7.1 to the supply output of a corresponding charger 7. The mains connection of the charger 7 in turn is connected, for example via the multiple socket 3 and the power cord 2 to the power grid 1. The same way of proceeding is to proceed if, for example, the battery of a navigation device 11, a monitor 12 or a notebook 13 is to be charged. This means that for the navigation device 11 is a special charger 6, for the monitor 12 is a special charger or power supply 4 and the notebook 13 is a special charger or power supply 5, since each of these electrical consumers own charging parameters or parameters for the power supply has , The camera 9, the mobile phone 10, the navigation device 11, the monitor 12 and the notebook 13 are examples of various types of electrical consumers. Thus, each type of electrical consumer needs its own charger designed specifically for this type. This solution is complex and inconvenient for the user, especially if he carries several different types of electrical consumers with them and would like to charge them out of the house, because then he always has to carry the appropriate charger for each type.

Presentation of the invention

An object of the invention is to provide a power supply station for an electrical consumer, wherein the power supply station automatically determines the energy parameters, such as current, voltage, power, charging mode or charging time automatically.

The inventive power supply station has a number of advantages. Thus, the user no longer has to have his own energy supply station for each type of electrical consumer, but can supply or charge different types of electrical consumers with energy according to the invention. The user merely connects the electrical consumer with the inventive energy supply station and the power supply station independently determines which energy parameters apply to this consumer and supplies it accordingly.

In addition, the user does not require any information about which type of electrical load which load parameters apply.

The object is achieved by a power supply station for supplying energy to an electrical consumer with the features according to claim 1.

The inventive energy supply station for supplying energy to an electrical consumer comprises an energy converter having a supply input, which is connectable to a power grid, and a supply output, which is connectable to the consumer. In addition, the power supply station comprises a controller which is designed and operable such that it detects at least one energy parameter of the connected consumer and, depending thereon, specifies a corresponding control signal for the energy converter.

Advantageous developments of the invention will become apparent from the features indicated in the dependent claims.

In one embodiment of the inventive power supply station of the supply output is designed as a USB port.

In a further embodiment of the inventive power supply station, the supply output is designed as an Ethernet connection.

In the inventive power supply station of the supply output can also be designed as RS232, EIA-422, EIA-485, I2C, CAN port.

In a further development of the inventive power supply station, a data connection for a computer is provided.

The data connection of the inventive power supply station can be designed as an Ethernet or USB port.

In addition, in the inventive power supply station, a synchronization port may be provided to synchronize the power supply station with another power supply station.

Advantageously, the control of the inventive power supply station is designed and operable so that it retrieves data from the consumer for the detection of the energy or the parameters.

According to a further feature of the invention, the controller is designed and operable such that it sets the target current and / or the target voltage as a control signal for the energy converter.

To solve the problem is also proposed that the energy converter is designed as a linear energy converter or as a primary or secondary clocked energy converter.

Moreover, it may be advantageous if the supply input is galvanically isolated from the supply output in the inventive power supply station.

In the inventive power supply station, the controller may also be designed and operable so that it specifies whether the energy converter should work as a constant current source, as a constant voltage source or as Energiesenke.

Finally, the power supply station according to the invention can have a plurality of supply outputs and a demultiplexer, which is connected on the one hand to the energy converter and on the other hand to the supply outputs.

An electrical consumer, which is suitable for operation with the inventive power supply station, advantageously has a communication device which is designed and operable to notify the controller of the power supply at least one energy parameter.

The energy supply station according to the invention can advantageously be used for charging an electrical load.

The inventive method for operating the power supply station and the consumer has the following steps. After the consumer is connected to the power supply, the controller of the power supply determines the consumer's energy parameters. Then, depending on the determined energy parameters, the controller prescribes a control signal for the energy converter and the energy converter then delivers energy with the corresponding energy parameters to the consumer.

Brief description of the drawings

In the following, the invention will be explained with several embodiments with reference to eight figures. <Tb> FIG. 1 <sep> uses a schematic diagram to show how various electrical consumers have been charged or supplied with energy so far. <Tb> FIG. 2 shows on the basis of a schematic diagram how different electrical consumers can be charged or supplied with energy in accordance with the inventive energy supply station. <Tb> FIG. 3 <sep> shows in a block diagram the basic structure of a possible embodiment of the charging station according to the invention. <Tb> FIG. 4 <sep> shows in a block diagram the basic structure of a further possible embodiment of the charging station according to the invention. <Tb> FIG. 5 shows a flowchart in which the time sequence of the individual steps taking place in the energy supply station according to the invention is shown. <Tb> FIG. 6 shows a flow chart showing the timing of the individual steps taking place in the consumer. <Tb> FIG. 7a, <sep> shows a diagram in which the course of the supply voltage over time is shown. <Tb> FIG. 7b <sep> shows a diagram showing the course of the supply current over time.

Ways to carry out the invention

The inventive power supply station can be used to provide the connected electrical loads during operation with sufficient energy. The inventive power supply station can also be used to recharge the battery of the connected consumer. The power supply station serves as a power supply and also as a charging station. In the following, the terms power station, power supply, charging station, charger and programmable power / charger (or PPS for short) are used as synonyms.

Fig. 2 shows a schematic diagram of how various electrical consumers, such as a camera 9, a mobile phone 10, a navigation device 11, a monitor 12 and a notebook 13, can be charged with the charging station 20 according to the invention. The user merely connects the corresponding electrical load 9, 10, 11, 12 and / or 13 via a charging cable 21 to the charging device 20 according to the invention, which in turn is connected via a mains cable to the power grid 1 serving as energy source. The charger 20 independently determines which charging parameters apply to this consumer and supplies it accordingly. The user does not need any information about which type of electrical consumer which energy parameters apply.

Electrical consumers can be any type of electrical equipment or components that require electrical power. These may be, for example, mobile electronic devices, rechargeable batteries, illuminants, electrical or mechatronic actuators, monitors or notebooks that support the communication protocol of the power supply station.

Depending on the country, the power grid 1 can supply different mains voltages. In Europe, the power grid usually supplies 220 or 230 volts, while in the US 115 volts and in Japan 100 volts are common. Advantageously, the power supply station 20 according to the invention can be connected to the various power grids and is thus suitable for various mains or input voltages.

Figure 3 shows in the form of a block diagram of the basic structure of a possible embodiment of the inventive power supply station 20 together with the notebook 13 as an example of a possible electrical load. As already mentioned above, it is of course also possible for another type of electrical consumer to be connected to the energy supply station 20 according to the invention instead of the notebook 13.

The power supply station 20 has an energy converter 26, the input side via a network connection 25 to the power cable 2 is connectable. On the output side, the energy converter 26 is connected to the supply input 13.1 of the notebook 13 via a supply connection 31, to which the cable 21 can be connected. About the supply terminal 31, which is also referred to as a power outlet, the notebook 13 is powered.

The energy converter 26 transforms and regulates the electrical energy, which is obtained from the power grid 1, to the consumer 10 requested values (= energy parameters). For this purpose, the energy converter 26 typically includes a switching power supply with upstream Power Factor Correction (PFC). The energy converter 26 electrically isolates the supply voltage at the supply output 31 from the mains voltage at the mains input 25. Depending on the power class, the energy converter 26 can be designed as a linear energy converter or as a primary or secondary clocked energy converter. A combination of switched and linear power supply is possible. As switched power supplies single-ended or push-pull converters can be used. The push-pull converter can be designed as a balanced, resonant, non-resonant or asymmetric half bridge or as a full bridge.

The energy converter 26 may also have a plurality of energy converters, each optimized for a specific voltage range. For example, the entire energy converter 26 may comprise a first energy converter optimized for the voltage range of up to 5 volts and a second energy converter optimized for the voltage range of 5 to 30 volts, wherein each of the two energy converters is optimized in terms of efficiency or efficiency in the respective voltage range. In this way, a voltage range of up to 30V can be covered particularly energy-efficiently.

The power supply just described is an AC / DC or AC / AC converter. The power supply can also be a DC / DC or DC / AC converter. The latter can be used for example in motor vehicles.

In addition, the charging station 20 also includes a controller 27, for example in the form of a microcontroller or microprocessor. However, the controller 27 can also be accommodated in an ASIC (Application Specific Integrated Circuit) or an FPGA (Field Programmable Gate Array).

The microcontroller can, depending on which requirements exist with respect to the interfaces, an 8-bit controller or even a complex computer with its own real-time operating system, which also allows parallel processing. For example, an embedded Linux system with an integrated Ethernet interface and web server for remote monitoring / control of the PPS 20. The controller 27 also has analog / digital and digital / analog converter for monitoring voltage, current and temperature of the energy converter 26th The digital-to-analog converter supplies the reference voltage to the power converter 26 for the correct output voltage.

The controller 27 is also connected to the terminal 31. Once the notebook 13 is connected via the cable 21 to the terminal 31, the controller 27 can communicate with the notebook 13.

In the embodiment shown in Figure 3, the cable 21 comprises a line 21.1 for power supply and one or more lines 21.2 for data transmission. The power supply line 21.1 connects the supply output 31.1 to the supply input 13.11 of the notebook 13. The data line 21.2 connects the data connection 31.2 to the data connection 13.12 of the notebook 13. However, this division into energy and data lines is not absolutely necessary. Instead, both the energy and the data transmission can take place via the same line.

So that the controller 27 can actually monitor the output voltage Uact applied to the supply output 31.1, which the energy converter 26 makes available to the electrical load 10, the output voltage Uact is also supplied to the controller 27.

In addition, the controller 27 is also supplied with a signal Iist from the energy converter 26, so that the controller 27 can also monitor the output current Iact, which the energy converter 26 makes available to the electrical consumer 10.

The controller 27 and the energy converter 26 together form a control loop. Its task is to ensure that the energy parameters determined by the controller 27, from which the controller 27 determines setpoint values for the energy converter 26, are also complied with. If the controller 27 determines, for example, a certain maximum charging current Imax as the energy parameter, then it gives it to the energy converter 26 as the desired value Iref. A control circuit integrated in the energy converter 26 then ensures that this current setpoint is maintained. The setpoint Iref is also referred to below as the reference current.

Determines the controller 27 as an energy parameter, for example, a certain maximum charging voltage Umax, it gives this the energy converter 26 as the setpoint Uref. The control circuit integrated in the energy converter 26 then ensures that this voltage value Uref is maintained. The setpoint Uref is also referred to below as the reference voltage.

Further energy parameters may be, for example, the charging duration, maximum deliverable power, interval-type charging, minimum charging current or minimum supply voltage.

In addition, the energy converter 26 may have a further control input. About this control input can be controlled with the corresponding control signal So whether the consumer 10 is to be isolated from the output of the charging station 20 galvanically.

Finally, the energy converter 26 of the controller 27 can also provide a control signal ST for temperature monitoring available. In this way, the controller 27 can detect the operating temperature of the energy converter 26 and - if the operating temperature exceeds a certain threshold - turn off the energy converter 26 or ensure that the output from the energy converter 26 power is reduced.

If the controller 27 has determined the typical electrical parameters for the notebook 13 (= energy parameters), the required setpoint values for the energy converter 26 are determined therefrom and transmitted to them. The manner in which the controller 27 determines the electrical parameters will be discussed later.

The supply terminal 31 forms the supply interface to the consumer. This interface 31 may be formed, for example, as an Ethernet interface. The Ethernet standard IEEE 802.3af (IEEE 802.3 Clause 33) describes the method of how an Ethernet-capable device, such as the notebook 13, can be powered via the Ethernet interface. In this case, the cable 21 is an Ethernet cable and designed as a twisted pair cable. For energy transfer, either the unused wires of the Ethernet cable are used, or in addition to the data signal, a DC component is transmitted via the four wires used.

In the power supply station 20, the interface 31 may be present multiple times in order to connect several consumers.

One or more of the interfaces 31 of the charger 20 may also be formed as a USB interface. The cable 21 is then formed as a USB cable. It has four wires, with two wires for data transmission, the other two wires for power supply. The USB specifications can be found on the Universal Serial Bus (USB) Implementers Forum, which is the industry consortium that issues the standards.

In addition, one or more of the interfaces 31 of the power supply station 20 may be designed as RS232 or EIA-232 interface, as EIA-422 interface or as EIA-485 interface. More information about these serial interfaces can be found at the Electronic Industries Alliance.

If required, the interface 31 can also be designed, for example, as an I2C (Inter-Integrated Circuit) interface or as a CAN (Controller Area Network) interface.

In principle, therefore, the power supply station 20 can be controlled by the consumer 13 via a standardized bidirectional interface, so that, for example, current, voltage and waveform can be adapted to the current needs of the consumer. The interface between PPS and consumer is primarily defined via the protocol and not via the physical interface. The consumer can also make inquiries to the PPS via the interface. For example, whether the required electrical quantities can be supplied at all or not (see also flow charts Fig. 4 and 5). This communication between the consumer and the mains / charger makes it possible in the future to provide only one universal, highly efficient mains / charger for a wide variety of electrical consumers.

Current, voltage and waveform can be requested by the consumer as needed. The PPS can serve both as a power source and as a current sink. For example, a consumer can tell the PPS via the protocol that the consumer's batteries should be discharged in a targeted manner. Thus, batteries can be optimally cared for in order to achieve the longest possible service life of the batteries. From the property that the consumer can control the PPS via an interface with a standardized protocol, there is the possibility of selectively generating over time varying currents or voltages with the PPS. This targeted temporal change of current and / or voltage is called waveform here. Using the protocol, the PPS can also be instructed to generate its own signal forms. As a result, the PPS can be used not only as an AC / DC converter or DC / DC converter, but also as an AC / AC or DC / AC converter, further increasing the universal use of the PPS (AC = AC, DC = DC).

The charger 20 according to the invention may also have a synchronization interface 28, 29, via which a plurality of the charging stations 20 according to the invention can be synchronized with each other in terms of time. If the charging stations 20 are programmed accordingly, the charging stations 20 can be used to generate complex multiphase signals. For example, with three synchronized charging stations 20, a three-phase system can be generated from a single-phase system. Thus, for example, a three-phase motor can be operated.

Finally, the charging device 20 according to the invention can also have a computer interface 30. Via the computer interface 30, the charger 20 according to the invention can both be programmed and controlled. The computer interface 30 may be configured, for example, for USB or Ethernet.

FIG. 4 shows in a block diagram the basic structure of another possible embodiment of the charging station 20 according to the invention. With this embodiment, a plurality of devices to be charged, for example, the notebook 13, the mobile phone 10 and the camera 9 can be charged or energized simultaneously with a single charging station 20. In addition to the above-described components, the charging station 20 additionally comprises a demultiplexer 40 and additional supply terminals 32 and 33. The demultiplexer 40 applies the energy adapted to the respective consumer 13, 10 or 9 for a specific period of time to the corresponding supply terminal 31, 32 or 33 switched. The control of the demultiplexer 40 is carried out with the controller 27.

If the terminal 13.1 of the notebook, the port 9.1 of the camera 9 and the terminal 10.1 of the mobile phone 10 are the same, the charging cable 21, 22 and 23 may be the same. Otherwise, the charging cables 21, 22 and 23 are adapted to the connection of the respective electrical consumer. The same applies mutatis mutandis to the interfaces 31, 32 and 33 of the charging station 20th

To load the connected loads in multiplex mode has the advantage that with just a single energy converter 26 more electrical consumers can be charged almost simultaneously. The multiplex operation reduces the circuit complexity, especially in the power section of the energy converter 26 considerably.

The communication between the charging station 20 and the consumers 9, 10, 13, however, can take place at any time. Whether the consumer connected to the charging station 20 is suitable for multiplex operation, the consumer of the charging station 20 with. For example, the monitor 12, which requires a continuous power supply, is generally not suitable for multiplex operation. The monitor 12 can notify the charging station 20 accordingly. In contrast, mobile phones, cameras, PDA (personal digital assistant) and notebooks are in most cases suitable for multiplex operation.

The charging mode can also be communicated by the consumer to the charging station 20. For example, a consumer may request that the charging process be completed before being allowed to switch to the next connected consumer. A consumer may also inform the charging station 20 of the minimum charging time required before switching on may take place.

A consumer may also make a request for immediate loading. This can be helpful in order to continue to ensure the operation of this consumer. If the connected loads have informed the PPS 20 of all permitted load modes, the PPS 20 is informed of all permitted load modes and can then decide whether the request for immediate loading may be complied with.

Figure 5 shows a flow chart showing how the controller 27 determines from the connected electrical load those electrical parameters (energy parameters) which are then used, for example, to properly set the charging voltage and charging current for the load. In a first step S1, the charging station 20 is connected to the power grid 1. Thereafter, the charger 20 becomes active. In step S2, which is a safety measure, the energy converter 26 is adjusted such that its output voltage Uact is, for example, 5V and its charge current Iact is a maximum of 500 mA. The monitoring of the output voltage Uist and the output current Iist takes place in an independent process or control loop, which can run independently in the energy converter 26. As soon as an electrical consumer, for example the notebook 13, is connected to the charger 20, a wake-up signal is sent to the notebook 13 by the controller 27 via the line 21. If in step S4 the notebook 13 does not acknowledge the wake-up signal, the charging station 20 waits a certain time (step S5) and then again sends a wake-up signal to the notebook 13. If the notebook acknowledges the wake-up signal, the controller 27 asks in step S6, the energy parameters of the notebook 13 from. If the notebook can not determine the energy parameters, the controller 27 waits a certain time in accordance with step S7 and then sends a wake-up signal to the notebook 13. If, on the other hand, the energy parameters are determined, the controller 27 checks in step S8 whether these energy parameters can also be met. If this is not the case, the controller 27 of the charger 20 sends corresponding information to the notebook 13 and informs him that these energy parameters can not be satisfied. The notebook 13 may then transmit to the charger 20 alternative energy parameters. If these energy parameters can be satisfied, the controller 27 provides the energy converter 26 with the required setpoint values in step S10. In addition, the controller 27 informs the notebook 13 in step S11 that the desired energy parameters can be met.

FIG. 6 shows a flowchart showing how an electrical consumer, for example the notebook 13, behaves when it is connected to the power supply unit 20 according to the invention. After the notebook 13 has been connected to the power supply unit 20 in a first step S20, it is supplied with a basic voltage of, for example, 5 volts in step S21 and thereby activated. Subsequently, the notebook 13 checks in step S22 as long as a wake-up signal is received until this is the case. As soon as the wakeup signal (step S23) has been received, the notebook 13 acknowledges the wakeup signal and checks in step S24 whether the power supply unit 20 wants to query the notebook's energy parameters. If this is not the case, the step S24 is repeated or alternatively waited for a certain period of time (step 25) and then checked again if a wake-up signal has been received. If the notebook 13 determines that the energy parameters are to be transmitted to the power supply 20, the notebook 13 determines the state of charge of its battery in step S26, determines its energy parameters therefrom and sends them to the power supply 20. Then the notebook 13 checks in step S27, whether the power supply 20 supplies energy with the corresponding energy parameters. If not, alternative energy parameters are transmitted to the power supply unit 20 in step S28. If energy is supplied by the power supply 20 with the corresponding energy parameters, the energy flow to the internal load is activated in step S29. In addition, in step S29 the notebook checks whether all electrical and thermal values are within the permissible range. If problems occur, the energy flow to the internal consumer is interrupted. This control process runs automatically in the background. During the charging process, this control process is monitored continuously in step S30 and - as long as no irregularities occur - continued. If, on the other hand, an exceptional situation occurs, the energy flow to the internal consumer is immediately interrupted in step S31, and the communication between the power supply unit 20 and the notebook 13 is continued in step S22.

The two timing diagrams according to FIGS. 7a and 7b show, by way of example, the profile of the voltage U and of the current I at the output 31 of the power supply 20 when a notebook 13 compatible with the power supply 20 is connected. The time t is plotted on the x-axis of the timing diagrams. The supply voltage U is plotted on the y-axis of the timing diagram according to FIG. 7a and the supply current I is plotted on the y-axis of the timing diagram according to FIG. 6b. The voltage, current and time axes are not linear. The illustrations according to FIGS. 7a and 7b are merely illustrative. The current and voltage curves may look completely different under different conditions.

In the following, the current and voltage curves at the individual times t0 to t9 are explained with reference to FIGS. 7a and 7b.

At time t0, the power supply 20 is connected to the power grid 1. In this case, the power supply unit 20 is not yet galvanically connected to the notebook 13. At the output of the power supply 20 are 5V.

At time t1, the power supply unit 20 is galvanically connected to the notebook 13. Due to the 5V voltage supplied by the power supply 20, the notebook 13 wakes up and requires 50mA during operation. In fact, not the whole notebook 13 wakes up, just the battery control of the notebook. To keep it simple, but in the following is only spoken by the notebook 13. The power supply unit 20 thus awakens the notebook 13 with a wake-up signal, which is transmitted to the notebook 13 via the communication interface 31. After the acknowledgment of the wakeup signal by the notebook 13, the power supply unit 20 queries the desired electrical parameters (= energy parameters) of the notebook 13. Thus, the communication between the power supply 20 and the notebook 13 is established (see also flowcharts according to FIGS. 5 and 6). The notebook 13 requests a current limit of 4A and a maximum voltage of 15V (energy parameters = maximum current Imax and maximum voltage Umax). The voltage should increase within a defined period of time to the nominal value of 15 volts. The power supply unit 20 confirms to the notebook 13 the required electrical values (= energy parameters). On the basis of this message, the controller 13.3 of the notebook galvanically connects the battery of the notebook to the output 31.1 of the energy converter 26.

From time t2, the voltage is increased with the requested slope, until at time t3 at 12V the maximum allowable current of 4A is reached. From then on, the power is held by the controller 26 of the power supply 20 to the maximum permitted by the notebook 4A.

At time t4, the power consumed by the notebook decreases. The voltage is then increased slightly until the maximum current of 4A is reached again. Between times t2 to t5, the power supply 20 operates as a constant current source.

From the time t5, the power consumption of the notebook continues to drop and the voltage therefore increases with the slope required by the notebook 13 to the maximum value of 15V, which is reached at time t6. The power supply 20 operates from now on as a constant voltage source. Since the power consumption of the notebook 13 continues to decrease, the notebook 13 instructs the power supply 20 at time t7 to lower the voltage to the holding voltage of 5V in a defined time.

At the time t8, the holding voltage of 5V is reached, the notebook 13 separates the battery galvanically from the output 31.1 of the power supply 20. The notebook 13 is still waiting for inquiries from the power supply 20. Thus, the notebook 13 at any time energy from the power supply 20 request. After lowering the voltage to the 5V holding voltage, the controller 27 in the power supply 20 can turn off all unneeded power parts, maintained only the holding voltage and cyclically query the notebook 13. In this way, the power consumption in the power supply 20 can be minimized.

The foregoing description of the embodiments according to the present invention is for illustrative purposes only, and not for the purpose of limiting the invention. Various changes and modifications are possible within the scope of the invention without departing from the scope of the invention and its equivalents. For example, devices other than those shown in FIG. 2, such as a Playstation, can be connected to the charging station according to the invention. In addition, not all steps shown in Figs. 5 and 6 are required.

LIST OF REFERENCE NUMBERS

[0072] <Tb> 1 <sep> mains <Tb> 2 <sep> power cable <Tb> 3 <sep> multiple socket <Tb> 4 <sep> Monitor Power Supply <Tb> 4.1 <sep> charging cable <Tb> 5 <sep> notebook power adapter <Tb> 5.1 <sep> charging cable <tb> 6 <sep> power supply for navigation device <Tb> 6.1 <sep> charging cable <tb> 7 <sep> power supply for mobile phone <Tb> 7.1 <sep> charging cable <tb> 8 <sep> power supply for camera <Tb> 8.1 <sep> charging cable <Tb> 9 <sep> Camera <Tb> 9.1 <sep> Connection <Tb> 9.11 <sep> Power Connection <Tb> 9.12 <sep> Data Transfer Connection <tb> 9.3 <sep> Control in the camera <Tb> 10 <sep> Mobile Phone <Tb> 10.1 <sep> Connection <Tb> 10.11 <sep> Power Connection <Tb> 10th 12 <sep> Data Transfer Connection <tb> 10.3 <sep> Control in the mobile phone <Tb> 11 <sep> navigation device <Tb> 12 <sep> Monitor <Tb> 13 <sep> Notebook <Tb> 13.1 <sep> Connection <Tb> 13.11 <sep> Power Connection <Tb> 13.12 <sep> Data Transfer Connection <tb> 13.3 <sep> Control in the notebook <Tb> 20 <sep> charger <Tb> 21 <sep> charging cable <tb> 21.1 <sep> Power transmission line <tb> 21.2 <sep> Data transmission line <Tb> 22 <sep> charging cable <tb> 22.1 <sep> Power transmission line <tb> 22.2 <sep> Line for data transmission <Tb> 23 <sep> Charge Cable <tb> 23.1 <sep> Power transmission line <tb> 23.2 <sep> Data transmission line <Tb> 25 <sep> Network Connection <Tb> 26 <sep> energy converter <Tb> 27 <sep> Processor <Tb> 28 <sep> synchronization interface <Tb> 29 <sep> synchronization interface <Tb> 30 <sep> PC interface <Tb> 31 <sep> Supply Output <Tb> 31.1 <sep> Electricity <Tb> 31.2 <sep> Data Transfer Connection <Tb> 32 <sep> Supply Output <Tb> 32nd 1 <sep> Electricity <Tb> 32.2 <sep> Data Transfer Connection <Tb> 33 <sep> Supply Output <Tb> 33.1 <sep> Electricity <Tb> 33rd 2 <sep> Data Transfer Connection <Tb> 40 <sep> demultiplexer <tb> S1-S31 <sep> Steps 1 to 31 <Tb> Uist <sep> actual voltage <Tb> Iactual <sep> actual current <tb> Uref <sep> reference or reference voltage <tb> Iref <sep> reference or reference current <tb> So <sep> Control signal for galvanic isolation <tb> ST <sep> Control signal for temperature monitoring

Claims (15)

1. energy supply station for supplying energy to an electrical consumer, with an energy converter (26), - Which has a supply input (25) which is connectable to a power grid (1), and --With a supply output (31) which is connectable to the consumer (13), - With a controller (27) which is designed and operable so that it detects at least one energy parameter of the connected load (13) and depending on a corresponding control signal (Uref; Iref) for the energy converter (26) pretends. Second power supply station according to claim 1, wherein the supply output (31; 32; 33) is designed as a USB port. 3. Energy supply station according to claim 1, wherein the supply output (31; 32; 33) is designed as an Ethernet connection or serial data transmission connection. 4. Power supply station according to claim 1, 2 or 3, wherein a data connection (30) is provided for a computer. 5. Energy supply station according to claim 4, wherein the data connection (30) is designed as an Ethernet or USB port. 6. Energy supply station according to one of the claims 1 to 4, wherein a connection (28, 29) for synchronization with a further power supply station (20) is provided. 7. Energy supply station according to one of the claims 1 to 6, wherein the controller (27) is designed and operable such that it retrieves data for detecting the energy parameter from the consumer (10). 8. Energy supply station according to one of the claims 1 to 7, wherein the controller (27) is designed and operable such that it as the control signal for the energy converter (26) the target current (Iref) and / or the target voltage (Uref) pretends. 9. Energy supply station according to one of the claims 1 to 8, wherein the energy converter (26) is designed as a linear energy converter or as a primary or secondary clocked energy converter. 10. Energy supply station according to one of the claims 1 to 8, wherein the supply input (25) from the supply output (31) is electrically isolated. 11. Energy supply station according to one of the claims 1 to 10, wherein the controller (27) is designed and operable so that it specifies whether the energy converter (26) should work as a constant current source, as a constant voltage source or as Energiesenke. 12. Energy supply station according to one of the claims 1 to 11, with a plurality of supply outputs (31, 32, 33) and a demultiplexer (40) which is connected on the one hand to the energy converter (26) and on the other hand to the supply outputs (31, 32, 33) , 13. Electrical consumer for a power supply station according to one of the claims 1 to 12, with a communication device (13.3) which is designed and operable to notify the controller (27) of the power supply (20) at least one energy parameter. 14. A method for operating a power supply according to one of the claims 1 to 13, - In which the controller (27), after a consumer (13) is connected to the power supply (20) determines the energy parameters of the consumer (10), - In which the controller (27) depending on the determined energy parameters, a control signal (Uref; Iref) for the energy converter (26) specifies, and - In which the energy converter (26) then energy (U, I) with the corresponding energy parameters to the consumer (13) outputs. 15. Use of the power supply station according to one of the claims 1 to 14, for charging an electrical load (13).