Identification apparatus for backup-type power supply systems

An identification apparatus for backup-type power supply systems aims to be used on a backup-type power supply system which includes real power supply devices and dummy power supply devices to form a N+1 architecture to output power. It has signal generation means located on the real power supply devices and dummy power supply devices to generate real identification signals and dummy identification signals of different potentials and a signal detection means to receive the identification signals to identify the real power supply devices and dummy power supply devices. Thereby operators can clearly understand coupling and installation conditions of the power supply devices of the backup-type power supply system to perform power risk management.

FIELD OF THE INVENTION

The present invention relates to an identification apparatus for backup-type power supply systems and particularly for a backup-type power supply system that includes real power supply devices and dummy power supply devices to form a N+1 architecture to output power.

BACKGROUND OF THE INVENTION

The conventional backup-type power supply system generally includes a plurality of power supply devices formed in a N+1 architecture. Takes 1+1 architecture as an example, it includes two power supply devices. It means that it allows malfunction occurred to one power supply device while another power supply device still maintains normal supply of power. In such a backup-type power supply system the power supply devices share a common structure. In other words, a plurality of power supply devices shares a common chassis and a controlling power integration back panel. In practice, if a higher safety power factor is not considered (such as the power consumption at the rear end electronic device is lower), a real power supply device and a dummy power supply device could commonly share a same structure. For instance, on the 1+1 architecture, only one real power supply device is installed, while a dummy power supply device is installed on another space. The dummy power supply device usually cannot supply power. Due to the constraint of installation space, the dummy power supply device generally has a specification, dimension and profile as that of the real power supply device. But it has a cooling air fan installed inside to avoid affecting the airflow, vibration and mechanical strength of the entire structure. Its power comes from the real power supply device through electrically connecting to a power integration back panel. Moreover, as the power supply device has to equip with safety self-inspection function, after the dummy power supply device is connected to the power integration back panel, it also can output a Power Good (PG) signal.

In the condition in which the dummy power supply device and the real power supply device are used in a mixed manner, if malfunction occurs to either of the dummy power supply device or the real power supply device, the controlling power integration back panel usually will generate a unusual alarm signal. But due to the dummy power supply device and the real power supply device are connected to the back panel through a connector of a standard specification (or a common panel), the monitor people at the remote end cannot distinguish from the alarm signal whether the malfunction occurs to real power supply device or the dummy power supply device unless they actually go to where the backup-type power supply system is installed to do onsite inspection. Hence to the monitor people at the remote site who have to monitor many backup-type power supply systems, they cannot immediately confirm the safety factor of the backup-type power supply systems. This seriously affects risk management capability.

SUMMARY OF THE INVENTION

The primary object of the present invention is to solve the aforesaid disadvantages. The present invention provides an identification means to identify dummy power supply devices and real power supply devices. Through an identification approach which may be a potential detection mode or an identification code coding mode, operators can clearly understand coupling and installation conditions of the power supply devices in the backup-type power supply system so that they can perform the risk management effectively.

Another object of the invention is to provide a display means outside the backup-type power supply system to display the installation conditions of the dummy power supply devices and the real power supply devices after having been determined by the identification means.

Yet another object of the invention is to send installation condition signals of the dummy power supply devices and the real power supply devices to a remote monitor center through the Internet after having been determined by the identification means.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Please refer toFIG. 1for the schematic circuit block diagram of a first embodiment of the present invention. The backup-type power supply system includes N+1 power supply devices and a power integration back panel30connecting to the power supply devices to integrate power output. The power supply devices includes a real power supply device10and a dummy power supply device20. The invention provides an identification signal generation means to allow the real power supply device10and the dummy power supply device20to generate a real identification signal and a dummy identification signal of different signal levels, and also provides a signal detection means to receive the identification signals to determine coupling and installation conditions of the real power supply device10and the dummy power supply device20.

The circuit block diagram of the first embodiment adopts a potential detection mode. The identification signal generation means includes installing potential detection points of different potentials on the real power supply device10and the dummy power supply device20. The potential detection points include a ground connection point12on a connection port11which is electrically connected to the real power supply device10and the power integration back panel30, and a floating connection point22on another connection port21which is electrically to the dummy power supply device20and the power integration back panel30. The signal detection means includes a signal detector31located on the power integration back panel30and connected to the potential detection points. When the backup-type power system is activated, the signal detector31detects through a linear resistor voltage. As the real power supply device10has the ground connection point12, the identification signal obtained from the real power supply device10has a zero potential. On the other hand, the dummy power supply device20has the floating connection point22, the identification signal obtained from the dummy power supply device20is a signal of a positive potential or a negative potential. If the signal detector31is an A/D converter, the potential signals at the potential detection points are converted to digital signals to inform operators. The invention can receive the identification signals through a display means to indicate the installation conditions of the real power supply device10and the dummy power supply device20. The display means may be a display lamp set40located outside the backup-type power system, or a communication unit32installed on the power integration back panel30. The communication unit32has a communication interface to transmit the identification signals to a remote monitor center50. The communication interface may be selected from RS-232, RS-384 or I2C. The signal detector31may also be a communication interface to directly transmit the digitized identification signals to the remote monitor center50. Thereby the operators not only can clearly determine the installation conditions of the real power supply device10and the dummy power supply device20through the display lamp set40on spot without making mistaken judgment of the power safety factor due to look alike appearance of the real power supply device10and the dummy power supply device20, they can also clearly perform power risk management based on the clear understanding of the installation conditions of the real power supply device10and the dummy power supply device20through the communication interface at the remote communication center50without going onsite to do inspection.

Refer toFIG. 2for the schematic circuit block diagram of a second embodiment of the present invention that adopts an identification code coding mode. The connection ports11and21of the real power supply device10and the dummy power supply device20have respectively a signal generator13and23to generate different identification codes for the real power supply device10and the dummy power supply device20. For instance, “0” for the real power supply device10and “1” for the dummy power supply device20. Thus when the signal detector31receives the identification codes from the real power supply device10and the dummy power supply device20, the installation conditions of the real power supply device10and the dummy power supply device20can be clearly determined. Similarly, through the display lamp set40and communication unit32, operator onsite or at the remote monitor center50can perform power risk management as desired.