AT514268B1 - Loss-free or low-loss power supply - Google Patents

Abstract

The invention relates to a lossless or low-loss power supply (1), and a method for power recovery, for electrical consumers. In this case, electrical energy is supplied from the public grid via a capacitive current limit (2) and a bridge rectifier (3) in an energy store (4), from which the electrical energy can be removed for a subsequent electrical load. A possible load or demand-dependent energy removal from the energy store (4) is determined by a measuring controller (6) and thus bridged via the switching element (7) of the AC voltage input or the DC voltage output or various diodes of the bridge rectifier (3). As a result, the electrical energy which was taken in a network quarter period in the following network quarter period is wholly or partly returned to the public power grid. The circuit (1) according to the invention is a classic capacitor power supply with energy return control. Thus, no or only low energy is destroyed in the power supply, resulting in a lossless or low-loss power supply.

Description

description

LOSS-FREE BZW. LOSS-POWERED POWER SUPPLY AND METHOD FOR POWER SUPPLY

The invention relates to a lossless or low-loss power supply, which a elektri¬schen consumer, such. an electronic circuit, from the public energy grid. In this case, a method is used, which controls the removal of energy from the public network demand-dependent in load fluctuations, i. returns again if it is not needed.

Electronic circuits for building automation are in modern Gebäudebzw. Homes increasingly indispensable to be able to control, for example, the operation of all elektri¬scher equipment inside and outside of buildings comfortably. Local operation by switching or manually adjusting the respective device is due to the ever-increasing collection of modern control systems in the living area no longer timely , However, when modern networked control systems are used for facilities, they usually also require connection to the public energy network, both in terms of permanent communication and remote maintenance. In particular, the large number of distributed electronic devices in the building unnecessarily increases energy consumption (hidden consumers), making such "intelligent" building control systems unattractive for low-energy or passive houses.

For the connection of a low-power electronic device to the public network you need therefore in future a power supply with low performance, ie a "zero-power power supply". Such electronic devices are usually control devices, which if necessary bring the shading electrically into the desired position, switch illuminations on or off, open or close windows, or generally transfer all equipment into and out of buildings adjust electrical drives. If this control unit consumes little power, then the associated power supply only needs a separating transformer (own power 3 to 5 watts) if galvanic isolation is required for reasons of safety. If not, a capacitive power supply that is state of the art and therefore already available on the market is usually sufficient. In principle, two capacitors are connected in series via a rectifier, which leads to a capacitive voltage division. Because of the 90 ° phase shift between current and voltage, the series-network capacitor suitable for this purpose generates no power dissipation, only reactive power. However, with each half cycle, the capacitor is recharged after the rectifier, which causes the voltage at this to rise steadily when no electrical energy is taken from the capacitor. Therefore, a voltage limitation, e.g., VDR or Zener diode, is required, which naturally results in losses in the form of heat. Thus, this is a lossy power supply.

The present invention is therefore an object of the invention to provide a loss-free or low-loss power supply (power supply) for distributed Gebäudebedien- or Steuerungselektro¬nik which load-dependent of the public network taken electrical energy partially or completely returns and thereby reduces the power loss in the power supply almost zero. One can thus speak of a "zero-power power supply".

This is inventively solved by the subject matters of the independent claims. Advantageous embodiments are the subject of the dependent claims.

The prior art is based on the general idea to charge a Speicherkonden¬sator via the public grid by a capacitive series resistor via a bridge rectifier. In this case, the voltage level on the storage capacitor is limited by an overvoltage element, whereby electrical energy is converted into heat, which leads to losses in the power supply.

To keep these losses in the power supply low, it must be ensured that the energy taken from the network is returned to the network, if this is not needed. This allows load-dependent energy extraction from 0 to 100%. For this purpose, the two diode paths of the bridge rectifier must be short-circuited via a switch for the positive as well as the negative half-wave. In the event of a short circuit, the electrical energy absorbed in a quarter-network period is completely returned to the network in the following quarter network period. If the short circuit between the two AC voltage terminals of the bridge rectifier, so the rectifier losses are also eliminated. In the event that there are only two load cases (standby and active), a balanced energy balance in the energy store (e.g., condenser, battery, ...) must be provided, i. The supplied electrical energy must be the same. Since electronic control systems are mostly in standby, the power supply can be designed for this standby power. Nevertheless, depending on the needs for short periods, the controller must perform activities. For this activity, more electrical energy is needed for the electronic circuit for a short time. In the case of capacitive power supplies already available on the market, this short-term higher energy withdrawal is used as the basis for the power balance, whereby most of the time (standby) the remaining "excess energy" in the power supply has to be destroyed.

In order to give rise in particular no "excess energy", the bridge rectifier is operated specifically, that is either in the half or full wave rectification, being supplied in the full wave rectification in both half-waves energy from the grid in the energy storage becomes. The switching between half-wave and full-wave rectification takes place via a switching element which, depending on demand, short-circuits a diode of the bridge rectifier in the negative half-wave. The energy removal from the power supply is monitored and thereby the switching element is controlled so that the transition between the two rectifier principles is carried out continuously. With this method, a load-dependent energy extraction between 50 and 100% is possible, whereby the power loss in the power supply is reduced.

A further advantageous embodiment of the solution according to the invention is the development of a simple integrated circuit (IC), since no electronic special components are required for this structure. In addition, with the simple under-tested process of all digital circuits, an IC can be designed which can then be made available for the construction of "Green Electronics".

Further important features and advantages of the invention emerge from the subclaims, from the drawings and from the associated description of the figures with reference to the drawings.

1 shows a block diagram of the power supply according to the invention with load-dependent energy extraction from 0 to 100%. [0011] FIG.

[0013] FIG. 2 is a block diagram of the power supply according to the invention with load-dependent energy extraction of 50 to 100%.

According to FIG. 1, the power supply unit 1 according to the invention has a capacitive Strom¬begrenzung 2, a bridge rectifier 3, and an energy storage 4. The electrical energy is supplied via this capacitive voltage divider in the energy storage 4, which can then be removed via a coupled consumer. In the event that little to no energy is removed from the energy store 4, the switching element 7 can short-circuit the bridge rectifier 3 at the output via the measuring controller 6 for a correspondingly long time. Thus, the electrical energy extracted in the previous quarter-network period is completely returned to the network in the following quarter-network period. If actual electrical energy is required, the switching element 6 opens the switching element 7 as required, and the bridge rectifier 3 again supplies energy to the energy store 4. In this variant, the overvoltage element 5 assumes a purely protective function and no power dissipation will occur therein.

With this described method, the public network torn off electrical energy is returned as needed. If the short-circuiting with the switching element 7 takes place at the input of the bridge rectifier 3, the losses at the bridge rectifier 3 are additionally eliminated. It is possible to speak of an energy return control, which can be improved in that removal and return takes place six times within one network period, and not as in the classic peak rectifier circuit, which always draws the energy from the network at the voltage apex, which leads to peak load in the public network.

According to FIG. 2, the power supply 1 according to the invention has a capacitive Strom¬begrenzung 2, a bridge rectifier 3, and an energy storage 4. The electrical energy is supplied via this capacitive voltage divider in the energy storage 4, which can then be removed, for example, via a coupled consumer. In the event of the occurrence of excess energy at the energy storage 4, this is destroyed at the overvoltage element 5. If the measuring controller 6 recognizes that more energy is being taken from the energy store 4, then the switching element 7 is opened and thus switched over to full-wave rectification, whereby more energy is transferred from the network into the energy store 4. If the energy removal goes back, the measuring controller 6 closes the switching element 7 and thus switches to half-wave rectification, whereby the energy store 4 is recharged only in half a network period. In particular, there is a continuous switching between half-wave and full-wave rectification, which also very much suits the energy extraction from the public grid.

Claims (7)

1. circuit (1), in particular for the power supply of electronic circuits, be¬steht from: - a storage capacitor (4) which is connected via a diode at the positive pole of the bridge rectifier (3), - a series network capacitor (2), which is connected to an AC voltage input of the bridge rectifier (3), and - a switching element (7), controlled by a measuring controller (6), which is parallel to the AC input or DC output of the bridge rectifier (3), characterized in that the switching element (7 ) short-circuits the AC input or DC output of the bridge rectifier (3) depending on the energy drawn from the storage capacitor (4). 2. circuit (1), in particular for the power supply of electronic circuits, consisting of: - a storage capacitor (4) which is connected to the positive pole of the bridge rectifier (3), - a series network capacitor (2) connected to an AC voltage input of the Brü Corner rectifier (3) is connected, and - a switching element (7), controlled by a measuring controller (6) which is parallel to egg ner diode of the bridge rectifier (3), characterized in that the switching element (7) this diode of the bridge rectifier (3) short circuits depending on the energy removal from the storage capacitor (4). 3. The circuit (1) according to claim 1, characterized in that depending on the energy extraction from the energy store (4), measured via the measuring controller (6), the switching element (7) is driven so that the recorded electrical energy of a network quarter period in the following Net quarter period is returned to the electric network, if this is not taken from a connected Ver¬braucher from the energy storage (4). By this method, no power dissipation arises at the security element (5). 4. Circuit (1) according to claim 2, characterized in that, depending on the energy extraction from the energy store (4), measured via the measuring controller (6), the switching element (7) is driven so that the absorbed electrical energy in only one Netzviertelperiode in the next Netzviertel¬ period is returned to the electrical network, if it is not removed from a connected consumer from the energy storage (4). 5. A circuit (1) according to claim 1 and 3, characterized in that the removal and return of the electrical energy takes place several times in the network period to prevent peak loads in the network. 6. The circuit (1) according to claim 2 and 5, characterized in that via the measuring controller (6) the minimum or maximum energy extraction from the energy storage (4) is detected and thereby the rectifier via the switching element (7) between half and full wave rectification switches. 7. circuit (1) according to claim 2, 5 and 6, characterized in that the load or demand-dependent continuous switching between half and full wave rectification takes place. For this 1 sheet drawings