CH708109B1 - Uninterruptible Power Supply (UPS) for electronic devices. - Google Patents

Abstract

Method for the uninterruptible power supply for an electronic device with the aid of an energy store (1), which consists of at least one supercapacitor, characterized in that the energy store (1) is charged when the power supply (2) is connected and the energy store (1) discharges is supplied via a socket (3) and the desired stable voltages and the necessary power until the electronic device is turned off, the input voltage with a charge controller (11) is fed to the energy storage (1) and the output voltage, both with input voltage present as well as with a failed input voltage, for an electronic device is provided.

Description

[0001] This invention relates to an uninterruptible power supply (UPS) for electronic devices according to the preamble of claim 1.

In the case of a power failure or unplugging the power plug, a computer system does not have the ability to shut down properly. To prevent data inconsistencies, computer systems and electronic devices must be properly shut down. It is therefore used UPS, which turn on in case of power failure in the computer system and shut down this properly. So that enough energy is available for this process, such UPSs are often equipped with batteries, which ensure the power supply during this time.

Therefore, for example, the use of application servers in computer networks, which execute application programs, in particular for embedded systems (embedded systems) to realize only with relatively large software and hardware costs.

Examples of applications in the embedded area are, for example: Vending machine with user interface, which must be easily disconnected from the power supply. With the invention, a "normal" computer software can now be developed, and the developer does not have to take any special precautions. On an industrial computer, data can be logged in a database. The development can be done with modern and efficient development tools. So far, special precautions had to be taken so that the data would not be destroyed in the event of a power failure. In a medical device, the power supply during a power failure can be ensured by the invention. The inventive UPS remains maintenance-free (no replacement of lead accumulators). An information display can be controlled with normal computer software. The invention protects against power failures and ensures operation after a power failure without the risk of destroying the file system.

Many existing UPS systems draw the energy in a power failure of lead-acid batteries. These are maintenance-intensive, represent a considerable investment, have a large space requirement and must be replaced at regular intervals. For example, buffering a computer system in a hospital requires a large number of such lead-acid accumulators, which regularly require large-scale maintenance.

The present invention now has the task to improve an uninterruptible power supply (UPS) for computer systems and electronic devices of the type mentioned in such a way that it requires no maintenance, can be accommodated in the computer system and the current bridging ensures that the computer system shuts down automatically and properly in the event of a power failure, or bypasses the power interruption, so that the electronic device continues to run without interruption.

This object is achieved by a device having the features of claim 1. Further features and embodiments will become apparent from the dependent claims, and the advantages thereof are explained in the following description.

The invention has the advantage that very simple, maintenance-free devices for integrated, simple and complex computer systems can be produced. This can provide electronic equipment with economically very cheap equipment, where previously complete server infrastructures with screen, keyboard and mouse were necessary so that the customer or service partner could power up and shut down the electronic device when he wanted to disconnect it from the power. In particular, for ERP systems (Enterprise Resource Planning Systems) with programs and databases for access from multiple workstations, often a UPS with maintenance-intensive lead acid batteries had to be used so that not all data and processes are aborted in a power outage uncontrolled and while data is lost.

For example In the industrial sector, the presented method and the devices provided for it are used with simple means to ensure that the operating system is shut down automatically and properly in the event of a power failure. Thereby, e.g. Products for the small business sector, typically for small and medium-sized businesses, are disconnected from the power supply without any problems and without a user interface. As a result, cheap standard motherboards, operating systems and software can be used in applications for which previously special hardware and software had to be used.

In the drawing shows: <Tb> FIG. 1 <SEP> Block diagram of an ATX UPSU <Tb> FIG. 2 <SEP> Block diagram of a 20W UPSU

The figures represent possible embodiments, which will be explained in the following description.

It is presented a method in which the uninterruptible power supply of an electronic device is ensured by means of an energy storage device 1 for a pre-scheduled duration. This energy storage 1 consists of at least one capacitor. The capacitors used are called super, double-layer or ultra-capacitors.

This energy storage 1 is charged whenever the power supply 2 is connected to a voltage source. As soon as the voltage source and thus the supply 2 fails, the energy storage device 1 is discharged and supplies via the socket 3 the desired stable voltages and the necessary control signals to the communication connection 6 for necessary and pre-planned time. With the voltage regulator 8, the output voltage at the socket 3 is prepared. The socket 3 may be for an ATX UPSU an ATX connector, a two-pin power connector or a direct connection to an electronic device on a circuit board. The voltage regulator 8 is used so that the socket 3 supplies a predefined, stable voltage to the electronic device.

The whole system can also be controlled by a microcontroller 5. This regulates e.g. when connected to a voltage source supply 2 via the switch 9 and the voltage regulator 8 (Figure 1), the desired stable voltages for the electronic device to the socket 3 and the necessary control signals at the communication port 6. In case of failure of the power source, the switch 9 is opened, and the output voltage is conditioned by the boost converter 13. At the same time, the UPS informs the electronic device via communication port 6 which action is to be triggered.

Fig. 1 shows an example of the structure of an uninterruptible power supply for ATX, a so-called ATX UPSU.

A terminal 7 serves on the one hand the configuration of an automatic power-on by a jumper 16 is set. On the other hand, a switch-on switch 17 can be connected to the connection 7, as a result of which the switch-on process can be triggered manually. The circuit has a microcontroller 5 for the regulation of the processes. The controlled processes, which are triggered by a signal through the supply 2 via the connection 7 and the PS_ON 10, include these functions: Switching the voltage regulator 8 on and off Charge control of the energy storage device 1 by the charge controller 11, Monitoring the current across the shunt resistor 12, Processing the signal at port 7 The processing and transfer of the information and signals to the communication port 6 of the motherboard.

A switch 9 ensures the switching from normal operation in the power failure operation, so that the energy in the event of failure of the feed 2 is obtained from the energy storage 1. A voltage regulator 8 is provided for the generation of the necessary ATX voltages. As energy storage 1 serve e.g. so-called double-layer capacitors. The charge controller 11 ensures the regulation of the charging power for the energy storage device 1. The shunt resistor 12 measures and supplies the information about the current output by the energy storage device 1. A boost regulator 13 is turned on and off by the microcontroller 5, ensuring that the transformation of the voltage of the energy storage device 1 to the intended constant voltage (e.g., 12 VDC) occurs. The communication terminal 6 gives the main board the on and off command. The circuit has a socket 3 for the ATX connection, which ensures controlled via the communication port 6, the power supply of the motherboard. A peripheral port 4 is provided for powering peripherals, such as a solid state disk.

The operation is described as follows: Normal operation: About the terminal 7, either automatically with a jumper 16, or with a power button 17, the behavior of the device relative to the socket 3, the peripheral terminal 4 and the communication port 6 connected electronic device set. This is done by closing switch 9. Subsequently, the motherboard is commanded via the communication port 6 to turn on. The motherboard then requests power-up via PS_ON 10, whereupon all voltages are provided by voltage regulator 8. Parallel to this process, the energy store 1 is charged via the charge controller 11 with the maximum power defined in the microcontroller 5.

Buffering circuit: If the supply 2 fails, the switch 9 opens, and the voltage from the energy store 1 is transformed by the up-converter 13 to 12 V. After a predefined waiting time, the motherboard is signaled via the communication port 6 that the power supply has failed, and at the same time informed that the operating system has to be shut down. The energy store 1 is then discharged until one of the following cases occurs: Safety cut-off: The maximum current, measured via the shunt resistor 12, has been reached. Proper Disconnect: The motherboard above PS ON (10) prompts for shutdown.

After arrival of one of the two cases, the boost converter 13 switches off and thus interrupts the power supply.

Upon actuation of the power button 17 during operation, the command for switching off by the microcontroller 5 via the communication port 6 is forwarded to the motherboard. After shutting down the operating system, PS_ON 10 tells you that the power can be turned off.

The operation of ATX has not been detailed above, since this is officially standardized. Upconverters are called boost converters in English. These generate a higher voltage from a lower voltage. Buck converters, on the other hand, are called buck converters and produce a lower voltage from a higher voltage.

The motherboard is often called motherboard. The communication port 6 communicates with at least one pole. The information of the new device with the electronic device may also be transmitted via serial interface such as e.g. RS-232, UART (Universal Asynchronous Receiver Transmitter), USB (Universal Serial Bus), I2C, SPI (Serial Peripheral Interface).

Alternatively, the communication can also be done by "terminal 15". This provides a voltage as long as the power supply is present on the power supply 2 and switches it off as soon as the connected device has to be shut down.

If the input voltage to supply 2 does not have the necessary voltage value or voltage fluctuations can occur at supply 2, an optional voltage converter 15 can be used which steps up or down the input voltage to the required voltage. Thus, the optional voltage converter 15 may be a boost converter, a buck converter or an up / down converter as required.

Fig. 2 shows the block diagram of a 20W UPSU.

A UPS not only has the task to shut down a complex computer system, but can also bridge failures of the power source or irregularities in the power supply. Not in every case, a signal is sent via the communication port 6 to the electronic device.

Due to innovative shapes and arrangements, the inventive UPS can be built smaller than 150 mm x 102 mm x 50 mm. This makes it possible to accommodate this UPS with a motherboard in a housing.

The inventive solution can also be partially or fully integrated both in terms of the spatial arrangement and in the electronic structure of a motherboard.

Claims (8)

1. A method for uninterruptible power supply (UPS) for an electronic device using a UPS system with an energy storage device (1), which consists of at least one supercapacitor, characterized in that the energy store (1) is charged when the supply (2 ) of the UPS system is connected to a voltage source and the energy store (1) is discharged and via a socket (3) provides the stable voltages and the necessary power until the electronic device is turned off, the input voltage with a charge controller (11) is led to the energy storage (1) and the output voltage, both at present input voltage and at a failed input voltage, is provided for an electronic device. 2. A method for uninterruptible power supply according to claim 1, characterized in that when the power supply (2) a microcontroller (5) via a switch (9) and a voltage regulator (8) provides the stable voltages for the electronic device, wherein in case of failure of Power supply of the switch (9) is opened and the output voltage by a boost converter (13) is processed. 3. A method for uninterruptible power supply according to claims 1 and 2, characterized in that at a terminal (7), a jumper (16) together with the microcontroller (5) ensures an auto-power-up configuration. 4. UPS system for carrying out the method according to claim 3, characterized in that the power supply connected to a source (2) via the charge controller (11) to the energy storage device (1) is connected, wherein the energy store (1) via an up-converter (13) and the charge controller (11) via the socket (3) delivers stable voltage. 5. UPS system according to claim 4, characterized in that a communication port (6) has at least one pole. 6. UPS system according to claim 4, characterized in that the microcontroller (5) with the jumper (16), the charge controller (11), the switch (9), the up-converter (13), the voltage regulator (8) and over the socket (3) is connected to the electronic device, the voltage regulator (8) being connected via the socket (3) to an ATX connection of a motherboard and via a peripheral connection (4) to a peripheral device. 7. UPS system according to claim 4, characterized in that the uninterruptible power supply has the maximum dimensions of 150 mm x 102 mm x 50 mm. 8. UPS system according to claim 4, characterized in that an optional voltage converter (15) is arranged in front of the feed (2).