WO1996010859A1 - Electrical switching and control arrangement - Google Patents

Abstract

The present invention concerns an electrical supply arrangement for a mobile radio network base station accommodated in a cabinet, the supply arrangement comprising two separate modular units of which one is in the form of an a.c. unit and the other is in the form of a d.c. unit. The d.c. unit comprises a circuit for supplying current to a consumer operated with direct current from an a.c. network, the charging current being limited but the discharge current being unlimited.

Description

 DESCRIPTION

Electrical switching and control device

A switching and control device according to the preamble of claim 1 takes over the electrical power supply of the base station of a mobile radio network with a predetermined DC voltage. In addition, such a switching and control device also has an administrative function, as follows: The high security standard of such base stations requires a backup battery in order to be able to operate in the

Power failure to ensure the function of the base station. This buffer battery must, as is known, be connected in parallel to the rectifiers. In the event of a power failure on the network side, the backup battery is now switched to the power supply instead of the rectifier. This switching function is controlled by the switching and control unit. On the other hand, the buffer battery must be kept in full operational readiness with a predetermined maintenance current during network operation. This function is also controlled by the switching and control device.

The diverse tasks described above are supplemented by the requirement that the so-called AC side of the switching and control device is on the one hand subject to the various national-specific safety standards and on the other hand also to be adapted to the national-specific network voltages and network frequencies.

Furthermore, from EP 514 072 circuits for supplying power to a consumer operated with direct voltage from an alternating current network are known, the alternating current phases of which are fed to the consumer as direct current by means of rectifiers, a buffer battery lying parallel to the input terminals of the consumer.

ORIGINAL DOCUMENTS They are used, for example, in the case of personal computers for the power supply in the event of a power failure, for example to keep an internal clock running.

Such circuits can be constructed very simply due to the low consumer currents.

It is assumed that the consumer currents are essentially in the order of magnitude of the charging currents.

In contrast, such a circuit is more difficult if the charging currents and the consumer currents differ greatly from one another, as is the case, for example, with the power supply to base stations of a mobile radio network.

In particular, the requirement is relevant that the buffer batteries have to be stressed by years of charging, while they still have to work with a very high discharge current.

These contradictory requirements should be realizable by the invention.

However, a compact construction which is essentially independent of the heat development should also be made possible, so that the prerequisites for installation in globally standardized base stations are given.

It is therefore an object of this invention to further develop the switching and control device in such a way that no adaptation of the direct current side to national regulations for base stations of mobile radio networks is necessary, and that the direct current side is operated with the lowest load, the lowest aging and the lowest ¬ stem wear and tear of the backup battery ensures its long-term function and nevertheless and essentially independent of Age of the backup battery satisfied a high consumer demand.

This object is achieved by the invention in the circuit mentioned at the outset by the features of claim 1.

On the one hand, the invention has the advantage that the entire electrical switching and control device is functionally divided in such a way that only the AC side of the mains connection, as a separate AC unit, has to be adapted to the national-specific requirements. The AC unit forms a compact housing that can also be easily replaced in the cabinet.

The invention has recognized that only the AC side of the switching and control device has to be adapted to the national requirements. It is a finding of the invention that even the direct current part of the switching and control device can be functionally counted with the radio telephone network station. It is therefore not necessary to adapt the direct current part to national regulations. Consequently, the direct current part (DC unit) of the switching and control device can be designed identically for all base stations worldwide, regardless of the geographic location of the network station.

For this reason, particular attention is paid to this invention in view of the rapidly expanding radio telephone networks with regard to cost-effective series production.

Although it is not harmful in principle, it is also proposed to equip the AC unit exclusively with the switching and control devices on the AC side. Consequently, the functional limit of the AC unit ends where an AC output is to be provided for each of the AC phases, which leads to an associated rectifier. In this context, the rectifier output should then be connected to the DC input side. Since the required DC voltage for the base station is already available at this point, the entire subsequent DC unit can be designed in an identical manner worldwide.

The invention has the further advantage that the battery charging current can be limited essentially to the usual approx. 10% of the nominal capacity, while the discharge current remains unaffected by this.

This is achieved in that the discharge circuit is parallel to the charge current limiter.

The resistance of the discharge circuit s is preferably low, so that the discharge current remains essentially unlimited

In this case, the discharge current was at a very low level, the z. B. is less than 10 ohms, so that the vo consumer drawn from the backup battery current is determined only by consumers.

A dynamic adaptation of the charging current to the respective battery charge state is preferred. For this purpose, it is advisable to provide an electrically controlled potentiometer whose potentiometer position can be adjusted depending on the charge level of the backup battery.

It should open the potentiometer when the charging current decreases and vice versa.

In order to eliminate mechanical wear as far as possible, we also proposed to use a semiconductor circuit breaker as a charging current limiter. In this case, the temperature of the semiconductor circuit breaker should be monitored by a separate cooling fan control circuit controlled by a temperature sensor.

In addition, for safety reasons, there can be a temperature-dependent opener in the parallel circuit of the control circuit, which is, however, subordinate to the temperature-dependent control circuit of the cooling fan.

The normally closed contact only switches in the parallel circuit above a temperature that can no longer be cooled by the cooling fan provided.

A diode blocking in the charging direction can preferably be provided for the discharge circuit. As an alternative to this, a short-circuit diode can be connected from the buffer battery to the consumer, which, however, would have to be combined with a protective diode for the charging current limiter.

Furthermore, it can be advantageous to make the maximum charging current adjustable in predetermined steps via a bridge circuit. This applies in particular to an AC network, where optionally only one or two or three of the AC power phases can be tapped. If the power requirement of the consumer can therefore only be met with three alternating current phases, the charging current for the buffer battery must also be increased accordingly.

It is also proposed to manufacture the modules in modular construction. On the one hand, housing-related heat build-up can be avoided in this way, which is why power components in particular can also be integrated into the modules. On the other hand, there is no need for additional housings, since the modules are fitted into prefabricated module rails in the cabinet.

The units should then preferably have the operating elements on their front sides and the necessary cables on their rear sides. wear connections. It is taken into account that the cabinets for receiving the inserts can already be pre-wired or pre-wired, so that only the insert modules then have to be placed.

It is also proposed to also manufacture the rectifiers in this design. This not only results in a uniform front board for the switching and control device including rectifiers, but also the possibility of cross-connection-free and thus completely interference-insensitive cabling on the rear of the modules.

This aspect is additionally favored if the rectifiers are flanked as a common block by the AC unit and the DC unit. The AC inputs of the rectifiers can be arranged on a common line, like the DC outputs.

With regard to the pre-wired cabinets, it can be advantageous to arrange the supply and control lines in a double rear wall of the slide-in housing, in order to be able to better shield the interference that is always present. In this case, it is proposed to build the double rear wall of the insert housing in a box-like manner from shielding material.

In addition, it is proposed to accommodate the AC units, the rectifiers, the DC units and the backup batteries in a separate cabinet.

With this design, there is the advantage of international adaptability to existing cabinet systems for such network stations.

The invention is explained in more detail below on the basis of exemplary embodiments. Show it:

FIG. 1: a basic circuit diagram for an electrical switching and control device for base stations of a mobile radio network; Figure 2: a basic circuit diagram for the power supply of a consumer operated with DC voltage;

FIG. 3: a basic circuit diagram for a control circuit according to the invention;

Figure 4: Front view of the switching and control device according to this invention;

Figure 5: Rear view of the switching and control device according to this invention;

Figure 6: Connection diagram according to Figure 3;

Figure 7: Front of the back of the insert.

Unless otherwise stated below, the following applies

Description always for all figures.

FIG. 1 shows a functional diagram of a supply device 1 in cooperation with a base station 2 of a mobile radio network according to this invention.

Such a base station 2 is fed from a network connection 3 with electrical current from the public network.

As is known, this is an alternating current of a given voltage and frequency.

This alternating current can have one or more alternating current phases 102 (see FIG. 2). A rectifier 4.1-4.3 is provided for each of these AC phases. The direct current generated in this way is fed into the mobile radio network 5 and used there for signal transmission in a manner known per se.

Parallel to the applied potential of the rectifier (s) 4, the input terminals 106, 107 (FIG. 2) of the mobile radio network 5 a buffer battery 6, which has a number of cells corresponding to the operating voltage.

The function: In normal operation, the base station 2 is supplied with energy by the AC source 3.

For this purpose, the high mains voltage is transformed to the required level. Then rectification takes place. With this step-down and rectified AC voltage, the network 5 is supplied. At the same time the operation of the rectifier and additionally the charging operation of the batteries are controlled by means of the switching and control device 1. In this case, a low charge current is constantly conducted through the buffer batteries, the so-called trickle charge.

The control takes place via the special control unit 17, which is part of the switching and control device 1 (dashed line).

If the current fed to the mains connection 3 fails, there is an "alarm" and the buffer battery 6 comes into operation. At this moment, the switching and control device switches by means of the switching point 18 to draw current from the buffer battery 6 into the mobile radio network 5. The switching point 18 is also part of the switching and control device (dash-dotted line).

If necessary, in order to prevent a complete discharge of the buffer battery 6, when the voltage drops below a voltage

Umin the buffer battery 6 from the mobile network who separated.

Figures 2 and 3 show further details on the circuit for the power supply of the DC-operated consumer 5. The circuit has a connection to an AC network 3rd A corresponding number of alternating current phases 102 is tapped from the alternating current network 3. Each of these AC phases 102 is fed to a rectifier 4.1, 4.2, 4.3. In the present case, three AC phases are removed from the network. As a result, three rectifiers are also provided.

The respective equipolar outputs of the rectifiers 4.1 - 4.3 are switched to a potential. The circuit 104 formed in this way consequently carries a direct current of a predetermined maximum level. The consumer represented by equivalent resistor 5, which is the mobile radio network operated with direct current, sits in the circuit 104.

Parallel to the input terminals 106, 107 of the consumer is the buffer battery 6, which has a number of individual cells adapted to the required consumer voltage.

The buffer battery 6 is located in a so-called parallel circuit 109 to the consumer circuit 104.

It is now essential that a control circuit 110 is located in the parallel circuit 109 of the buffer battery 6. The control circuit 110 has a charging current limiter 111. This will be discussed with reference to Figure 3. In parallel with the charge current limiter 111 is a discharge circuit 112, which is the prerequisite for the discharge current to be essentially independent of the charge current.

For this purpose, in the present case the discharge circuit 112 is a diode 113 which blocks in the charging direction, but which essentially has an electrical resistance in the order of up to approximately 10 ohms in the discharging direction. However, diode 113 preferably has a forward resistance of less than one ohm. As already indicated in FIG. 2, but as can be seen better in FIG. 3, the charging current limiter 111 is an electrically controlled potentiometer. The d potentiometer is therefore adjusted electrically. It is provided that the potentiometer closes with increasing charging current and opens with buffering current in the buffer battery 6.

A semiconductor power switch 114 fulfills all of these requirements, as can be seen from FIG. 3. Such a semiconductor circuit breaker can be implemented by a so-called Pow MOSFET. Such a power MOSFET serves as a limiter of the charging current by converting the power not required for charging the Pu ferbatterie 6 into heat according to the principle of an electrically controlled potentiometer. Di is carried out by means of a voltage comparison at the sensing resistor 13. This will be discussed later.

It is now essential that a control circuit 115 is assigned to the power MOSFET, which is activated by a temperature sensor 116. The temperature sensor 116 taps the temperature of the power MOSFET in a suitable manner. For this purpose, a temperature sensor can be attached to the heat sink of the power MOSFET. The temperature exceeds a predetermined value, e.g. B. 45 degrees Celsius, the temperature sensor closes the relay circuit, which is the relay 117. The relay picks up u the relay switch 118 closes the cooling fan control circuit 119. Accordingly, the motor 120 of the cooling fan 121 starts, so that the semiconductor circuit breaker 114 can be cooled. The air flow from the cooling fan 121 sweeps over the heat sink of the power MOSFET and provides for convective Thermal transport.

It should be noted that the cooling ventilator control circuit is a circuit operated with normally open 118. The closer 118 is operated by a corresponding relay circuit. Furthermore, a temperature-dependent opener 122 must be provided in the parallel circuit 109 of the control circuit 110.

This is an opener 122, which interrupts the power supply to the buffer battery 6 as soon as the temperature sensor 123 belonging to the opener 122 measures a temperature above a predetermined maximum temperature. The predetermined maximum temperature can, for. B. 110 degrees Celsius. In any case, it is below the destruction temperature for the semiconductor power switch 114. In this case, the current supply would be interrupted and the control circuit 110 can cool down.

As can be seen from FIG. 3, there is a diode 113 in parallel with the power MOSFET, which can be referred to as a freewheeling diode in the discharge circuit.

As an alternative to this, a so-called short-circuit diode 124 can also be provided between the buffer battery 6 and the consumer 5, but preferably in conjunction with a protective diode 125 so as not to destroy the semiconductor power switch.

In addition, it should be pointed out that, according to FIG. 2, not all three AC phases have to be tapped. The number of AC phases tapped depends on the power requirement of the consumer.

To take this fact into account, the present circuit provides a bridge circuit 126.

For this, three different input resistors are connected in parallel. Each input resistor serves as a current limiting resistor. The current is limited to specified values. In the case of the upper current limiting resistor 127, the current is limited to 10 amperes, for example, while in the case of the middle limiting resistor 128 it is e.g. B. to 20 amps and in Case of the lower limiting resistor 129 may be limited to 30 amps.

The basic control of the power MOSFET is done via the sensing resistor 130, which is located in the supply line to the Buffer 6 battery. Via the branch line provided there, part of the current led to the buffer battery 6 is passed on the input side to the operational amplifier 131, which in turn controls the semiconductor power switch 114 via the temperature-controlled break contact 122. The control is thus dependent on the voltage drop across the sensing resistor 130, which is a measure of the charging current present.

In this way, the power MOSFET is automatically opened with decreasing battery current, so that a charging current control takes place, which is dependent on the current state of charge of the buffer battery 6.

On the other hand, the discharge current is determined practically only by the consumer 5 via the extremely low electrical resistance of the discharge circuit, in particular the diode 113.

In addition to this, Figure 4 shows that the entire switching and control device 1 consists of two separate units 17, 18 be.

It is therefore a so-called AC unit 17, which is provided with all switching and control devices on the AC side. In particular, this AC unit 17 has a main switch 9, a power junction box 11, and a predetermined number of bridge plugs 24, the function of which can be checked if necessary via LEDs 25.

In addition, an automatic circuit breaker 10, preferably as an emergency stop switch, can be provided. It is essential that an AC unit is designed as a small and compact structural unit which is provided with all the necessary switching and control devices which are either prescribed by the national authorities or are necessary on the network side.

The DC unit 18 differs from this. In this case, e.g. B. measuring devices 27 as well as circuit breakers 10, switches and LEDs 25 may be provided.

The essential difference between the AC unit 17 and the DC unit 18 is, however, that the DC unit only has the switching and control devices which are on the DC side for controlling charging operation or rectifier operation, or Battery operation is necessary including the circuit as it is the subject of Figures 2 and 3.

It is accordingly not necessary for the DC unit 18 to adapt to any safety regulations or network-side conditions. As a result, the DC unit can be manufactured regardless of national requirements. The entire mobile radio network station is therefore only adapted via the AC unit 17.

A special feature is that both units 17, 18 are designed in a modular design. It is therefore inserts that can be detected and handled by means of handles 26. As can be seen, the inserts on their front sides 15 each have all operating elements accessible from the outside. The cabling of the slots is on the back, which will be discussed later.

As a further special feature, the rectifiers 4.1 - 4.3 are designed in a modular design. Like the AC unit and the DC unit, they have a continuous front board, which can optionally also be equipped with light-emitting diodes 25. In addition, the handles 26 on the rectifiers 4.1 4.3 are also present.

Another special feature here are the three rectifiers - one rectifier for each AC phase - arranged centrally and directly with respect to each other. The rectifiers form a rectifier block, which is flanked on the opposite sides on one side by the AC unit 17 and a on the other side by the DC unit 18. Here, too, the connection is seamless and immediately adjacent. As a result of the horizontal arrangement, as shown in FIG. 2, any heat development of the power components is taken into account. The heat produced can flow off freely, heating up any other structural units.

Nevertheless, the overall block 23 is so small in relation to the interior solutions of the cabinet 8 that the buffer battery can also be accommodated in this cabinet 8 with a cell battery corresponding to the required voltage. Such a cabinet 8 is commercially available and essentially determined by the Ford tion, including the subsequent base stations 2. As a result of this requirement, the base station can therefore be accommodated together with the switching and control device 1 according to this invention in cabinets of the same size and construction, although a national-specific device adaptation of the AC unit is necessary for each switching and control device.

As FIG. 4 shows, the slide-in units are assigned to a slide-in housing which, according to FIG. 7, has fixed counterparts 20 in its rear wall 21 for the connections 12 of the supply and control lines.

For this it is helpful first of all, the rear side 16 d of the entire slide-in unit, consisting of AC unit 17, the directives tern 4.1 - 4.3, the DC unit 18, to be viewed from behind (ε. Fig. 5).

It can be seen that the rear side 16 of the entire slide-in unit is provided with all the necessary connections 12 for the supply and control lines of the devices.

Although the connections are designed differently, for the sake of simplicity they are designated with the same reference numerals 12.

Furthermore, FIG. 6 shows a corresponding circuit diagram for the functional wiring from the rear view of the plug-in units. In this case, there is a central AC input at the AC unit 17, from which a horizontal wiring to the AC inputs of the rectifiers 4.1-4.3 goes.

Accordingly, the connections for the AC inputs to the rectifiers 4.1-4.3 lie on a horizontal line. Parallel to this, but at a distance, the rectifiers also have DC outputs arranged on a horizontal line, which are connected to one another and lead to the DC input of the DC unit 18. In addition to grounding, a consumer lead 5 to the mobile radio network is also provided. The particular advantage of this modular construction with a corresponding horizontal device arrangement is consequently a crossover-free cabling of the rear side of the insert. In order to be able to easily assemble the modular units, a look at the slide-in housing 19 according to FIG. 7 is helpful.

FIG. 7 shows the front of the insert rear of the insert housing 19. From the view shown, the inserts are assembled from the front. The rear wall 21 is provided in accordance with the arrangement according to FIGS. 5 and 6 with counterparts 20, which here too have the same reference numerals for the sake of simplicity. As can also be seen from FIG. 7, the insert housing 19 has a double rear wall 22. The entire wiring runs between the rear panels. This offers the advantage of good shielding with immunity to interference.

Accordingly, the double rear wall 22 is constructed in a box-like manner, so that all current-carrying cables sit within a sheet metal box which has a shielding function in a manner known per se.

REFERENCE SIGN LISTING

1 switching and control device

2 base station of a cellular network

3 Mains connection 4.1-4.3 rectifier

5 cellular network, consumer, equivalent resistor 6 buffer battery

8 closet

9 switches

10 circuit breaker

11 Junction box 12 Connection for supply and control section

15 front side

16 backside

17 AC unit

18 DC unit 19 slide-in housing

20 counterpart

21 rear wall

22 double rear wall

23 Overall block 24 jumper plugs

25 LED

26 handle

27 measuring devices

102 alternating current phase 104 current circuit

106 input terminal

107 input terminal 109 parallel circles

110 control circuit

111 charge current limiter

112 discharge circuit 113 diode

114 semiconductor power switch, power MOSFET

115 control circuit

116 temperature sensors

117 relay 118 relay switch

119 Cooling fan control circuit

120 engine

121 cooling fan

122 NC contacts 123 temperature sensors

124 short-circuit diode

125 protection diode

126 bridge circuit 127-129 limiting resistor 130 sensing resistor

131 operational amplifiers

Claims

PATENT CLAIMS

1. Electrical switching and control device (1) for a base station of a mobile radio network (2) housed in a cabinet (8) operated with direct current, in which a rectifier is connected to an alternating current network (3) of each alternating current phase (102) (4) and in parallel with it a chargeable buffer battery (6) is assigned, which is parallel (109) to the input terminals of the consumer (5), the respective operation of the rectifier (4) or buffer battery (6) ( Charging, current draw in the event of a failure of the AC network, rectifier operation with or without charging the buffer battery) is managed by the switching and control device (1), characterized in that

1.1 the switching and control device (1) consists of two separate units (17/18), of which

1.2 one (17) exclusively contains the switching and control devices on the alternating current side (AC unit), and of which

1.3 the other (18) has only the switching and control devices on the direct current side (DC unit), and contains a control circuit (110) with charging current limiter (111) which

1.4 is seated in the parallel circuit (109) of the backup battery (6), 1.5 being connected to the charge current limiter (111) in parallel with a discharge circuit (112) 1.6 electrical resistance is so low that the discharge current thereby remains essentially unlimited, and that

1.7 the charging current limiter (111) is an electrically controlled potentiometer which opens when the charging current decreases.

2. Circuit according to claim 1, characterized in that 2.1 the charge current limiter (111) is a semiconductor power switch (114), and that

2.2 the control circuit (110) has a temperature sensor (116)

2.3 a cooling fan control circuit (119) as a function of the temperature of the semiconductor power switch

(114) controls.

3. Circuit according to one of claims 1 or 2, characterized in that in the parallel circuit (109) of the control circuit a temperature-dependent switched opener (122) εitzes.

4. Circuit according to one of claims 1-3, characterized in that the discharge circuit (112) has a blocking in the loading direction de diode.

5. Circuit according to one of claims 1-4, characterized in that the discharging circuit (112) has a short-circuiting diode (124) between the battery and the consumer and preferably a protective diode (125) between the charging current limiter and the consumer (105).

6. Circuit according to one of claims 1-5, characterized in that the maximum charging current is adjustable via an adjustable bridge circuit (126).

7. Electrical switching and control device (1) according to claim 1, characterized in that the two units (17/18) are designed in modular construction, the al inserts on their front sides (15) the operating elements (switches (9), circuit breakers (10), power junction boxes (11)) and on their rear side (16) carry the connections (12) for the supply and control lines.

8. Electrical switching and control device according to claim 7, characterized in that the rectifiers (4) are also designed in a modular design, which also carry their connections (AC connection, DC connection) on the rear side (16).

9. Electrical switching and control device according to claim 8, characterized in that the rectifier (4) centrally and the two structural units (17, 18) are arranged on εich opposite rectifier outer sides (overall block (23)).

10. Electrical switching and control device according to claim 7, characterized in that the plug-ins are assigned to a slide-in housing (19) which in its rear wall (21) has fixedly arranged counterparts (20) for the supply and control lines.

11. Electrical switching and control device according to claim 10, characterized in that the supply and control line counterparts (20) are firmly wired, preferably within a double rear wall (22) of the plug-in housing (19).

12. Electrical switching and control device according to one of claims 1 - 11, characterized in that the outer dimensions of the AC / DC units are so smaller than the inner dimensions of the barrier (8) that both units with a free space for the / the rectifiers (4) and the backup battery (6) can be inserted into the cabinet (8).