DE19817398A1 - Electric points heating control unit with switch control unit for controllable coupling of heating current circuit to power supply e.g. for railway network - Google Patents

Abstract

The switch control unit (5) contains a power part (5b) with an electronic controlled adjusting element, which is controllable at the load circuit side of the at least one heating current circuit, and is coupled to the power supply (2,3,4) including a switch (2), a transformer (3) and a line (4).

Description

The invention relates to an electrical switch tion control device with a switching control unit controllable coupling of at least one point heating circuit ses to a power supply.

Such devices are used to control electrical Switch heating systems used, as z. B. in the railroad network of the Deutsche Bundesbahn and used by the registration be made. Usually the power ver supply for the electric point heating in this case from Railroad contact wire branched off, the switching control unit the switch heating circuit or circuits as required to the energy company Power supply for the contact wire is connected and disconnected. One ago Conventional switching control unit has such a purpose named heating contactor as a coupling, the line connection mechanically opening and closing switching element. A sol The heating contactor is subject to mechanical Ver wear and is mechanically limited Switching frequency and therefore a relatively high temperature switching hysteresis in the range of typically 5 K or more, what a corresponding additional consumption of electrical energy has the consequence.  

The invention is the technical problem of providing development of an electrical point heating control device of type mentioned above, which has a high durability has and an energy-efficient operation of the or the assigned heating circuits.

The invention solves this problem by providing it an electrical point heating control device with the Features of claim 1. Included in this facility the switching control unit a power unit with an elek tronically controlled actuator, the load circuit side the we at least one heating circuit controllable to the power ver supply coupled. The use of such an electronic controlled actuator instead of a mechanically switching Actuator avoids any mechanical wear and tear enables an almost unlimited number if controlled correctly Durability of the actuator and thus the facility in total velvet. In addition, the switching frequency of such an electric nisch controlled actuator with correct control na almost unlimited, resulting in a comparatively small Temperature switching hysteresis of e.g. B. only 1 K can achieve what again to noticeable energy savings in the electri heating of the associated switches.

In a device further developed according to claim 2 the electronically controlled actuator from one High efficiency triac thyristor module formed. A sol Ches semiconductor power switch module is advantageous for AC power supplies suitable by both positive and negative voltage polarity of the load circuit "ignited", d. H. can be switched on.

In a device further developed according to claim 3 the control circuit used to control the electronically controlled actuator is used, advantageously by the load to be opened and closed controlled by the actuator circuit electrically isolated. In a further embodiment  this measure is the galvanic decoupling according to claim 4 tion realized in that the control circuit one or several serial, electronic optocoupler circuit breakers includes. The respective optocoupler Lei is preferred circuit breaker according to claim 5 such with zero voltage switchability. This allows the actuator as a whole be designed as a so-called zero voltage switch, d. H. the switching takes place in voltage zero crossings of the load circuit. Together with the galvanic decoupling Control circuit and load circuit reduced or avoided this causes so-called EMC problems.

In an advantageous development of the invention according to saying 6 is the power section with the electrically controlled Actuator and thus the facility as a whole on a lei Power supply voltage up to about 470 V and / or a Lei power supply current rating up to 250 A or more, what the facility especially for use in iron Railway point heating systems with energy supply from the driver makes wire suitable.

In a device further developed according to claim 7 the respective heating circuit with a so-called Prosi fused fuse. Has such a fuse a very high breaking capacity.

A further development of the invention according to claim 8 provides partial cooling options for the electrical used Components of the power section of the switching control unit, by mounting the components on a heat sink and / or actively acted upon by a cooling air flow during operation become.

In a device developed according to claim 9 an RC element and / or for protection against surge peaks a varistor parallel to the electronically controlled actuator switched into the load circuit.  

An advantageous embodiment of the invention is in the Drawings shown and will be described below. Here show:

Fig. 1 is a schematic block diagram of part of an electrical point heating system with associated point heating control device and

FIG. 2 is an overview circuit diagram of a part of the switch heating control device of FIG. 1 that is essential to the invention.

Fig. 1 shows schematically only a part of an electrical point heating system of interest here for the needs-based heating of one or preferably several points of a railroad track provided at the relevant rail location. The electrical energy required for switch heating is taken from a contact wire 1 of the railway line, which in the usual way on a high voltage of z. B. is 15 kV and an alternating current with a frequency of 16 _^2/3 Hz, depending on the application, 50 Hz, leads. A high-voltage transformer 3 can be coupled to the contact wire 1 via a conventional mast switch 2, and a high-voltage fuse (not shown) can be provided in the feed line. On the output side, the transformer 3 via a two phase SiGe connecting line 4 to a subsequent Schaltsteuerein unit 5 a two-phase AC voltage of z. B. 462 V. The switching control unit 5 is part of a point heating fed by the energy of the transformer 3 , which usually comprises several such switching control units in a parallel arrangement for a respective group of one or more point heating elements in a parallel arrangement.

About the respective switching control unit 5 can preferably several, equipped with the necessary electrical Weichenheizele elements heating circuits 6 , z. B. up to sixteen sol che heating circuits per switching control unit to the power supply formed by the transformer 3 are controllably coupled and uncoupled, for which purpose each switching control unit comprises a diagnosis-capable control part 5 a and a power part 5 b with one or more electronically controlled actuators, the load circuit of which assigned heating circuits 6 controllably coupled to the transformer 3 . The Schaltsteu ereinheit 5 is preferably housed in a control cabinet, at least the heat-generating components of the power section 5 b are mounted coolable by being mounted on a conventional heat sink, which conducts heat via solid-state heat conduction and / or cooling lines and / or from one active cooling air flow can be cooled. In the latter case, a filter fan with an outlet filter element and a regulator unit for temperature-controllable cooling air regulation is seen for the control cabinet.

Fig. 2 shows the circuit structure of the half of the respective switching control unit 5 belonging to a phase of the two-phase switch heating power supply, the other half of which has a symmetrical structure for the other phase and therefore not shown further. The switching control unit 5 is also referred to as a valve and its two halves as the respective valve side. As can be seen from Fig. 2, each valve side has a triac thyrister module 7 , z. B. the conventional type SKKT 162 / 18E from SEMIKRON, as an electronically controlled actuator to the loadkreisein on the input side via a corresponding input terminal 8 a and a prosistor 9, the supply voltage from the transformer 3 is applied. This is forwarded by the actuator 7 depending on the switching state to the load circuit output side 8 b with load resistor EL, on which the or the controlled Wei Chen heating circuits are. In parallel with the triac 7 , an RC element with a resistor R7 and a capacitor C1 is switched to protect the triac 7 from surge peaks. For this purpose, a varistor, not shown, can also be provided in parallel.

A first triac gate terminal 7 a is resistance level via a first gate consisting of a parallel circuit of a resistor R5 and a diode D1 to the output side of the Prosistors 9 is connected, while the other triac gate terminal 7 also b have such a gate resistance level of a resistor E6 and a diode D2 and is connected to the overvoltage protection EC element to the prosistor output side. Furthermore, the two triac gate connections 7 a, 7 b are connected to one another via three serial resistors E2, E3, E4.

To control the triac 7 is a DC control circuit 10 , z. B. with a 5 V DC voltage, provided in series with a resistor El and three optocoupler semiconductor switch components 11 , 12 , 13 , the opto-coupler functionality of these components 11 to 13 for galvanic decoupling of the control circuit 10 from the circuits controlled thereby worries. About the first-mentioned optocoupler switch module 11 , for. B. such a her conventional type SFH 610 A, the control circuit 10 is a wide rer DC circuit, z. B. with a 24 V DC voltage, which functions as a detection circuit and monitors the functionality of the switching control unit. In addition, this additional DC circuit can be used to activate a 230 V AC circuit. In addition, the control circuit 10 may include a thermal switch, which uncouples the TTL control signal when an excessive temperature occurs and thereby gives the system the opportunity to cool down again sufficiently. When using a heat sink, the thermal switch is preferably mounted on this.

About the other two optocoupler switch modules, which are z. B. can be of the type SITAC-BRT 23, the galvanically decoupled activation of the triac 7 . For this purpose, the two circuit breaker modules 12 , 13 on the load circuit side are connected in parallel with one of two neighbors of the three resistors E2, R3, R4 between the two triac gate connections 7 a, 7 b. The associated parallel resistors E2, E3 are high-resistance resistors with a balancing function. The third resistor R4, on the other hand, is used to set the control current. By using the two optocoupler switch modules 12 , 13 in a serial arrangement for the triac control, the voltage load is halved for each of the two, so that they can be used without problems for the described case of a 462 V supply voltage. The selected circuit structure can withstand voltage fluctuations of up to 30% without any problems. In addition, the circuit shown can be dimensioned without difficulty so di that a heating current of 250 A and can be controlled per valve.

Another advantage of the circuit structure shown in FIG. 2 is its zero voltage switching capability. For this purpose, for the optocoupler circuit breaker modules 12 , 13 , which are used for triac control, those with zero-point switching capability, also referred to as so-called vibration package control, are used, such as the aforementioned module of the BET 23H type. The functionality of a zero voltage switch is known per se, so that it need not be discussed in more detail here. With this method, switching takes place when there is a voltage zero crossing on the load side. The use of the optocoupler switch modules 12 , 13 prevents the occurrence of EMC problems or in any case reduces such EMC effects. A control with TTL signals is implemented via the control circuit 10 .

The structure shown in FIG. 2 each of its two valve sides enables the switching control unit 5 with the triac thyrister module 7 provided in it for each of the two phases, a very effective use of the control part 5 a with energy-optimized control algorithms. When used correctly, the electronically controlled actuator 7 has a practically unlimited switching frequency and thus allows the temperature switching hysteresis to be reduced to very low values of 1 K and less, which enables noticeable savings in the energy consumption of the point heater. Since the switching control unit does not contain any mechanically moving parts, it is not subject to mechanical wear and therefore has an almost unlimited durability if properly controlled. Further advantages of the electrical switch heating control device according to the invention, in particular compared to conventional control devices with a heating contactor, can be seen in the fact that the service life of the switch heating elements, mostly heating rods used for this purpose, can be extended, the installation of several actuators is easier possible, if necessary redundancy of the control circuit is provided and the high availability of the point heating system is achieved.

Claims (9)

1. Electric point heating control device with

• - A switching control unit ( 5 ) for controllably coupling at least one point heating circuit ( 6 ) to a power supply ( 1 to 3 ),

characterized in that

• - The switching control unit ( 5 ) includes a power section ( 5 b) with an electronically controlled actuator ( 7 ), the load circuit side of the at least one heating circuit ( 6 ) controllably coupled to the power supply ( 2 to 4 ).

2. Electrical switch heating control device according to claim 1, further characterized in that the electronically controlled actuator is formed by a triac thyristor module ( 7 ) ge. 3. Electrical switch heater control device according to claim 1 or 2, further characterized in that the control circuit ( 10 ) for controlling the electronically controlled actuator ( 7 ) is galvanically decoupled from the load circuit. 4. Electronic point heater control device according to claim 3, further characterized in that the control circuit ( 10 ) via one or more serial, electronic optocoupler circuit breakers ( 12 , 13 ) is electrically isolated from the load circuit ( 8 a, 8 b) . 5. Electrical switch heating control device according to claim 4, further characterized in that the respective electronic optocoupler circuit breaker ( 12 , 13 ) is a sol cher with zero voltage switching capability. 6. Electrical switch heating control device according to one of claims 1 to 5, further characterized in that the power part ( 5 b) with the electronically controlled actuator ( 7 ) to a power supply voltage up to about 470 V and / or a power supply current up to at least 250 A. is designed. 7. Electrical switch heater control device according to one of claims 1 to 6, further characterized in that egg ne Prosistor fuse ( 9 ) is provided for the at least one heating circuit. 8. Electric switch heater control device after a of claims 1 to 7, further characterized in that we at least part of the power section components on one Heatsink is mounted and / or in operation by a cooler air flow is applied. 9. Electrical switch heating control device according to one of claims 1 to 8, further characterized in that an RC element (R7, C1) and / or a varistor is looped in as a surge protection in the load circuit in parallel with the electronically controlled actuator ( 7 ).