FR2882865A1 - Wireless telephony network`s transceiver station/relay antenna supply device for use with power supply network, has super-capacitors with total energy reserve, and supply network`s AC voltage analyzing device to transmit power loss alarms - Google Patents

Abstract

The device has super-capacitors (4) accumulating and restoring, during a predetermined duration, electrical energy corresponding to a power of several kilowatts to have a total energy reserve. A power supply network`s AC voltage analyzing device (3) transmits alarms, in case of power loss at an input of an AC/DC voltage converter (2), through an information transmission system (7) towards a central alarm reception device (8). The super-capacitors are connected at the output of the AC/DC voltage converter and supplied with a nominal DC voltage. The information transmission system transmits information such as breakdowns and eventual encountered damages, towards the central alarm reception device.

Description

Power supply for transmitting station

  This invention relates to the field of power supply systems. The invention relates more particularly to power supplies connected to the electrical network delivering an alternating current and supplying a nominal DC voltage used to power the transmitting receiving stations, also called relay antennas, forming the mobile telephone radiotelephone network.

  Mobile broadcast receiving stations are also called, regardless of the generation of mobile phones, base stations and are powered by power bays. A transmitting station uses a DC voltage supplied to it by a power supply bay. The power supply bays are composed of batteries, charged by a DC voltage supply coming from a converter, the converter transforming the alternating voltage of the electrical network into a DC voltage generally of 48V. The structure of the bays, which includes several electric batteries, allows to have a reserve of energy constituted by the electric charge of the batteries. The power reserve allows the bay to provide a DC voltage for example of about 48V to the transmitting station, autonomously generally more than 15 minutes, in case of power failure. The analysis of the operation of the telephone network makes it possible to measure and quantify an availability of the order of 99.5%. The unavailability due to the non-functioning of the power supplies often represents approximately 10% of the total unavailability, ie a network unavailability due to the non-functioning of the transmit / receive station power supply of the order of 0.05%.

  However, such power bays are electrical equipment which requires a large amount of equipment, which have a large mass often greater than 300 kg and which require a large available space. Because power arrays are large, it is often necessary to protect them with expensive infrastructure. The arrays also require frequent maintenance with regard to the batteries.

  It is known in the prior art systems for converting energy from an alternating voltage into a DC voltage. It is also known in the prior art elements for analyzing a voltage. Recently, capacitors capable of accumulating electrical energy corresponding to an available power of a few kilowatts have been known, these capacitors often being called supercapacitors or supercapacitors, or else ultracapacities, the storage capacity of which is related to the existence of an electric charge at the carbon / liquid electrolyte interface. Current power supply arrays with a range in general of more than 15 minutes only partially prevent failures of transmitting and receiving stations in the event of an incident on the electrical network because the duration of the incidents is often greater than this. autonomy, although their frequency is very low. The incidence of such failures on the availability of the radiotelephone network is overall very low while the device provided, as specified above, requires significant work, besides the fact that the equipment is heavy and expensive to implement.

  The object of the present invention is therefore to eliminate one or more of the disadvantages of the prior art by creating an assembly making it possible to provide a food easily handled by a person, of a weight, at most at present, of the order of 30 kg. no longer requiring maintenance of the batteries, always resulting in a low unavailability of the telephone network while still allowing to detect a failure.

  This objective is achieved thanks to a power supply for a transmitting station 30 of a radiotelephone network comprising at least one AC voltage DC voltage converter and a load using the nominal DC voltage, characterized in that it comprises: supercapacitors making it possible to accumulate and restore, for a predetermined duration, an electrical energy corresponding to a power of several kilowatts, all the supercapacitors connected to the output of the converter and supplied under a nominal DC voltage having a total energy reserve which guarantees the autonomy of a transmitting station for the predetermined duration in the absence of power supply via the electric power supply network; it comprises a system for detecting energy drop at the input of the converter and a system for sending information to a central device for receiving alarms; the system for detecting a drop in energy emits, in a time less than the predetermined duration, at least one energy fault alarm via the system for sending information to the central device for receiving alarms.

  According to another particularity, the power supply may possibly transmit various other alarms via the information sending system.

  According to another particularity, the AC voltage DC voltage converter is capable of outputting a nominal DC voltage regardless of the AC input voltage greater than or equal to an operating threshold.

  According to another particularity, the fault alarm is triggered when the AC input voltage has a value lower than the operating threshold of the converter AC input voltage.

  According to another particularity, the information emitted during the triggering of a fault alarm contains the identification of the antenna, the geographic location of the bay associated with the antenna and the type of fault detected.

  According to another particularity, the converter's energy input detection system and the information sending system are both powered by the supercapacitors.

  According to another particularity, the value of the operating threshold of the AC input converter voltage is 70% of the nominal AC input voltage.

  In another feature, the supercapacitors are connected directly to the load.

  In another feature, the supercapacitors are connected to a second converter which is connected to the load.

  The invention, with its features and advantages, will emerge more clearly on reading the description given with reference to the appended drawing given by way of non-limiting example in which FIG. 1 represents the receiving station power supply device. of a radiotelephone network.

  The invention will now be described with reference to FIG. 1. The power supply for a receiving station of a telephone network is connected to the power supply network which supplies an alternating voltage (1), for example in France. , 220V. This voltage is converted into a nominal DC voltage, for example 48V, by a continuous AC voltage converter (2). The converter (2) has an operating range which enables it to supply a DC voltage of 48V as long as the value of the AC voltage is equal to or greater than an operating threshold, the operating threshold being for example chosen from the order 70% of the nominal value, in this example of 220V. In order to be able to trigger an alarm if the input voltage (1) falls, the voltage of the input power network of the converter (2) is analyzed by an analysis device (3). The analysis device (3) for example measures the AC voltage supplied by the power supply network. The analysis device (3), adapted and set to operate with the converter (2) will emit one or more alarms when the converter (2) can not function properly, a case of degradation of operation being that the voltage drops in below the operating threshold, chosen for example of the order of 70% of its nominal value of 220V.

  The analysis device (3) communicates with the information transmission system (7) by known electronic communication means. In the event of a power failure, the information transmission system (7) is capable of sending coded information that raises the energy fault alarm to a centralized alarm receiving device (8). The alarm receiving device (8), in connection with a not shown supervision system, will allow the management of failures and interventions to be performed if necessary. The coded information transmitted by the transmission system (7) includes information on the nature of the failure and any damage encountered to determine whether an intervention is necessary or not and also geographical location information of the failure allowing a quick onsite intervention. The DC output of the converter (2) is connected to capacitors (4), also commonly referred to as supercapacitors, which can supply energy corresponding to several kilowatts for a given time. Supercapacitors are indeed needed to power a transmitting station and provide, for a given period, as much power as electric batteries. The use of several supercapacitors increases the energy reserve. The electrical charge of the capacitors (4) must constitute a reserve of energy which provides sufficient autonomy to ensure the operation of the transmitting station for the predetermined duration and thus transmit the various alarms, preferably typically between one and five seconds , enough time to seamlessly transmit the useful set of alarms. This autonomy with respect to the power supply network makes it possible, of course, for the system using the 48V DC voltage (5) not to undergo degradation in its operation in the event of micro-cuts or brief voltage dips, which may appear on the voltage. electric (1).

  Voltage dips are voltages less than the minimum voltage threshold guaranteed by the power grid operator. The average duration of brownouts and voltage dips will also influence the setting of the determined period of autonomous operation of the power supply in the absence of power supply via the electrical network (1). The combination of the converter (2) and supercapacitors (4) leads to a good regulation of the DC voltage (5), in the present example of 48V. The voltage of 48V (5) across the supercapacitors (4) is also used to power the input voltage analysis device (3) and the information transmission device (7). The system for transmitting alarms in the event of a power failure, consisting of the analysis device (3) and the transmission system (7), forms part of the power supply for the transmitting station, which 'is powered only by a single power point: the input of the converter (2), connected to the mains is 220V AC power supply. When an energy fault, for example more than a few seconds appears, the autonomy of a few seconds (of the order of three seconds for example) that provides the energy reserve of supercapacitors (4) allows, in this case time, the voltage analysis system (3) transmits at least one energy fault information to the information transmission system (7), and then to the information transmission system (7) after receiving the energy fault information, sending complete coded information to the centralized alarm receiving device (8). This complete information includes the nature of the failure and other information stored by the device (7), useful for troubleshooting with, among other things, geographical location. Transmission of alarms from the information transmission system (7) to the centralized alarm receiving device (8) can be carried out by radio and / or wire transmission. The time required for good transmission was estimated at less than five seconds.

  The operation of the power supply of a transmitting station is therefore the following: in the event of a break of duration shorter than the determined duration (for example from three to five seconds), an alarm is sent to the supervision but the station transmission reception continues to operate. In case of a break of duration greater than the determined duration, the supervision system notes that the transmitting station is no longer functioning, but the energy loss information has been received, allowing the supervision system to know the cause. and locating the failure of the transmitting-receiving station to trigger the intervention of the maintenance crews.

  In a first embodiment of the invention, the supercapacitors can be directly connected to the load, that is to say at the input of the transmitting station.

  In a variant or second embodiment of the invention, the supercapacitors are connected to a second converter itself connected to the load and therefore to the input of the transmitting station. This second converter thus advantageously makes it possible to regulate the DC voltage even more effectively before feeding the load.

  It should be obvious to those skilled in the art that the present invention allows embodiments in many other specific forms without departing from the scope of the invention as claimed. Therefore, the present embodiments should be considered by way of illustration, but may be modified within the scope defined by the scope of the appended claims, and the invention should not be limited to the details given above.

Claims (9)

CLAIM   1. Power supply for transmitting station for a radiotelephone network comprising at least one AC voltage DC voltage converter and a load using the nominal DC voltage, characterized in that: it comprises supercapacitors for accumulating and to restore, for a predetermined duration, an electrical energy corresponding to a power of several kilowatts, all the supercapacitors connected to the output of the converter and supplied under a nominal DC voltage having a total reserve of energy which guarantees autonomy a transmitting station for the predetermined duration in the absence of power supply by the power supply network; it comprises a system for detecting energy loss at the input of the converter and a system for sending information to a central device for receiving alarms; the energy drop detection system transmits, in a time less than the predetermined duration, at least one energy fault alarm via the system for sending information to the central device for receiving the alarms .   2. Power supply according to claim 1, characterized in that the power supply can possibly emit various other alarms via the system of sending information.   3. Power supply according to claims 1 to 2, characterized in that the AC voltage DC voltage converter is capable of outputting a nominal DC voltage regardless of the input AC voltage of greater than or equal to operating threshold.   4. Power supply according to claims 1 to 3, characterized in that the fault alarm is triggered when the AC input voltage has a value lower than the operating threshold of the converter AC input voltage.   5. Power supply according to claims 1 to 4, characterized in that the information emitted during the triggering of a fault alarm contains the identification of the antenna, the geographical location of the bay associated with the antenna and the type of antenna. detected fault.   The power supply according to claims 1 to 5, characterized in that both the converter power drop detection system and the information sending system are energized by the supercapacitors.   7. Power supply according to claims 1 to 6, characterized in that the value of the operating threshold of the AC input voltage of the converter is 70% of the nominal AC input voltage.   8. Power supply according to claims 1 to 7, characterized in that the supercapacitors are connected directly to the load.   9. Power supply according to claims 1 to 7, characterized in that the supercapacitors are connected to a second converter which is connected to the load.