The present invention relates to a relay controller for driving an excitation winding of a relay, and a relay device for switching loads.
When relays are used, high-side or low-side switches that connect an excitation winding of the relay to the operating voltage are used. In this case, the term high-side or low-side identifies the position of the switch relative to the load, which in this case is the excitation winding of the relay. A high-side switch is connected by one terminal to a battery, and a low-side switch is connected by one terminal to a reference potential, usually earth. A relay with a high-side switch is illustrated in
A current-saving relay driving system reduces the current after the pull-in of the relay armature, that is to say shortly after switch-on, in order thus to reduce the power consumption of the switched-on relay. Such a circuit arrangement for the operation of a relay is disclosed in DE4410819. In DE4410819, a switch T1 bridges a holding resistor R4, which sets the holding current of the excitation winding of the relay. As a result of the bridging of the resistor R4, a higher pull-in current is available at the first moment of switching on the excitation winding.
For commutation purposes, a commutation voltage has to be applied counter to the current direction via the excitation winding; the higher said commutation voltage, the more rapidly the energy of the excitation winding is reduced and the faster the commutation becomes. A diode reverse-connected across the excitation winding can be used for commutation purposes, such that the commutation current can flow through the then conducting diode, as is illustrated in
As illustrated in
In automobiles, in particular, in which the petrol consumption is directly dependent on the current requirement of the electronics used, solutions which reduce the current consumption of the electronics and hence the CO2 emissions of the automobile, are inexpensive to manufacture and have a long service life are becoming important.
One aspect of the present invention provides a relay controller and a relay device in which the excitation current of a relay is controlled in current-saving fashion in a simple manner.
The relay controller for controlling an excitation current of a relay comprises a first terminal, which is connected to an excitation winding of the relay, a second terminal, which is connected to a commutation device of the relay, wherein the relay controller, when the relay is turned on, controls the excitation current through the excitation winding of the relay in such a way that through the excitation winding there flows firstly a pull-in current and, after a pull-in time has elapsed, through the excitation winding there flows a holding current that is lower than the pull-in current, and wherein the relay controller, when the relay is switched off, feeds a commutation current that flows through the excitation winding to the commutation device through the first terminal and through the second terminal of the relay controller.
The relay controller preferably lies in the freewheeling path of the relay. The relay controller controls the temporal sequence of the pull-in operation of the relay. If the high-side switch or the low-side switch turns the relay circuit off, the relay controller conducts the freewheeling current or the commutation current to the commutation device. The voltages at the terminals of the relay controller remain limited to low values. By contrast, the switch-side terminal of the excitation winding can oscillate freely, its voltage swing preferably being limited by the breakdown voltage of the switch. It is also possible to use mechanical or other inexpensive switches.
The relay controller can be designed to control the excitation current only after a current that flows, after the switching-on of the switch, through the commutation device into the second terminal energizes the relay controller. For this purpose, the commutation device has to enable the flow of the current switched by the switch to the relay controller. For this purpose, by way of example, the commutation device can be embodied as a resistor. After the switch has been switched on, current firstly flows via the commutation device through the second terminal into the relay controller and thereby starts the latter. At this moment no excitation current can be provided by the relay controller. Once the relay controller is ready for operation, the excitation current can also be provided.
The relay controller can be designed to detect the current that flows after the energization of the relay through the switch, through the commutation device into the second terminal, in order thus to determine a turn-on instant, wherein this turn-on instant determines the start of the pull-in time. This state can be detected for example by a power-on reset circuit that monitors the internal supply voltage. A power-on reset circuit monitors an internal supply voltage and generates a signal as soon as the internal supply voltage exceeds a specific threshold. After the detection, a capacitor or a counting device can be reset. The start of the relay controller then determines the start of the pull-in time.
The relay controller can be designed to detect the excitation current. If the excitation current exceeds a threshold, the capacitor or the counting device can be reset. The exceeding of the excitation current threshold then determines the start of the pull-in time.
The relay controller can have a fifth terminal, wherein a switching on and a switching off of the relay controller can be determined by means of a circuit connected to the fifth terminal. The excitation current of the relay can be switched on or off with a signal via the fifth terminal or can be determined by means of a circuit connected to the fifth terminal. The relay controller can switched be on or off with a signal via the fifth terminal.
The relay controller can be designed to determine the hold current. After the pull-time has elapsed the pull-in current can be reduced to a lower hold current. The hold current has to be large enough to hold the relay on. For an efficient operating of the relay it is useful to reduce the hold current as much as possible. The relay controller can have a sixth terminal, wherein the excitation current through the excitation winding, the hold-current can be determined by means of a circuit connected to the sixth terminal or with a signal via the sixth terminal
The device can comprise a temperature sensor circuit comprising a temperature sensor for detecting the temperature of the relay controller. The temperature sensor circuit can be designed to implement measures for reducing the power consumption of the relay controller if a maximum temperature is exceeded. One measure for reducing the power consumption of the relay controller can consist in turning off the current through the excitation winding.
In one embodiment, the relay controller draws a current from the second terminal during operation. The relay controller thus utilizes the current flowing through the commutation device for its own supply, with the result that there is no need for a further terminal for providing a supply voltage. The current that flows through the commutation device is limited by the relay controller since only the current required for supplying the relay controller flows.
The relay controller can have a third terminal, which is connected to the second reference potential, for example earth. The voltage between the first terminal and the third terminal can be limited by means of a voltage limiting device. The relay controller can thus limit the voltage upon reduction of the current after the pull-in of the armature. If the relay controller is jeopardized by an increased temperature, for example, the voltage limiting device protects the relay controller against high voltages.
The third terminal can preferably be connected to the reference potential. An internal supply voltage can be established between the second terminal and the third terminal. Between the first terminal and the third terminal, the relay controller can comprise a current source and a second switch for providing an excitation current.
Between the first terminal and the second terminal, the relay controller can have a first switch for controlling the commutation current.
The first switch of the relay controller can be a diode. In one embodiment, the cathode of the diode of the first switch is connected to the second terminal of the relay controller. The first switch of the relay controller can be a MOS transistor or a bipolar transistor.
The relay controller can have an undervoltage sensor between the second terminal and the third terminal, for detecting an undervoltage.
If the undervoltage sensor detects an undervoltage, the relay controller can reset the pull-in time to a predetermined value. The relay controller can thus indirectly change over to a higher current, or to a maximum possible current, in order that the relay operating contacts remain closed even when there is a low voltage between the first and the second reference potential.
The relay controller can comprise a second switch provided in parallel with the current source that provides excitation current, said second switch bridging the current source if the undervoltage sensor detects an undervoltage. The relay controller thus provides a maximum possible current in order that the relay operating contacts remain closed even in the case of a low voltage.
In a further exemplary embodiment, the current source provides only the holding current, and for the pull-in of the relay, the second switch bridges the current source during the pull-in time.
The relay controller can have a fourth terminal, wherein the pull-in time can be determined by means of a circuit connected to the fourth terminal.
A relay device for switching loads comprises: a relay, a relay controller comprising at least two terminals for controlling the relay, a commutation device, wherein the commutation device is coupled in parallel with the excitation winding of the relay via a first terminal and a second terminal of the relay controller, a switch, wherein the excitation winding of the relay, the relay controller and the switch are coupled in series.
In a relay device for switching loads, the relay controller can be integrated with the relay in a housing. The integration of the relay controller into the relay has the advantage that for example the handling and stockkeeping can be greatly simplified. In the case of integration, the relay controller can be coordinated precisely with the relay, with the result that a simplification of the relay controller can be afforded.
In a relay device for switching loads, the switch can be a high-side switch.
In a relay device for switching loads, the switch can be a low-side switch.
In a relay device for switching loads, the commutation device can contain at least one resistor.
In a relay device for switching loads, the commutation device can contain at least one zener diode.
Embodiments are explained in more detail below with reference to the following drawings.
A resistor 430 as commutation device 400 in accordance with
An arrangement comprising a low-side switch is possible analogously to this and is shown in
If the high-side switch 211 is switched off, the entire arrangement is without current and the relay is switched off. In other words, the switch 320 of the relay 300 is open, with the result that no current can flow through the terminals 321, 322 of the relay 300. This state corresponds, in
a shows a switching voltage Vsw between the terminal of the excitation winding 311 and the third terminal 503 of the relay controller.
b shows an output voltage Vro between the first terminal 501 of the relay controller 500 and the third terminal 503 of the relay controller.
c shows an excitation current Irel that flows into the terminal 311 of the excitation winding through the excitation winding 310.
d shows a supply current Irs of the relay controller that flows into the second terminal 502 of the relay controller 500.
The instants t1 to t5 in
After the relay controller 500 has started, the start instant of the pull-in time can be determined and defined. The excitation current Irel rises continuously, and the relay operating contact 320 of the relay 300 closes before the excitation current Irel has reached the magnitude of the predetermined pull-in current of the relay 300. The output voltage Vro remains for as long at a low level which can correspond to a minimum drain voltage of a MOS transistor or a minimum collector voltage of a bipolar transistor.
In addition to a current source that can be embodied as a current source transistor, a second switch that can be embodied as a switching transistor is also possible in order to minimize the output voltage further. The excitation current can be detected, in which case the exceeding of a threshold can determine a start instant of the pull-in time. If the predetermined pull-in current has been reached, the excitation current Irel rises further until it is limited by the sum of the resistances if the pull-in current is provided by a switch. If the pull-in current is provided by a current source, the excitation current Irel does not rise further.
The output voltage Vro settles to a value given by the supply voltage Vs, the pull-in current and the internal resistance of the excitation winding 310. Independently of this, the potential at the second terminal 502 of the relay controller 500 assumes a value given by the internal resistance of the commutation device 400, the supply voltage Vs and the supply current Irs.
At the instant t2, after the pull-in time has elapsed, the relay controller 500 switches the excitation current from the value of the pull-in current to a predetermined value of a holding current. The holding current can be chosen such that it is lower than the pull-in current, but high enough that the relay operating contact 320 of the relay 300 remains closed.
The instant t2 can be determined by a predetermined pull-in time. The instant t2 can also be determined by the relay controller 500 detecting the instant at which the excitation current has reached the value of the pull-in current and permitting a predetermined pull-in time to elapse after this instant.
The energy difference arising from the difference of the pull-in current and of the holding current of the excitation current can be dissipated via the commutation device 400 by the excess excitation current being conducted through the first 501 to the second 502 terminal of the relay controller 500 to the commutation device 400. A current resulting from the difference of the supply current Irs and of the excess excitation current then flows from the second terminal 502 of the relay controller 500. While the excitation current decreases, a voltage that can be higher than the supply voltage Vs is established by the commutation device at the first terminal 501 and second terminal 502 of the relay controller 500. This voltage can be limited by a voltage limiting circuit, which can be within or outside the relay controller 500 and can be e.g. a zener diode.
Once the energy difference arising from the difference of the pull-in current and of the holding current of the excitation current has been dissipated, the instant t3 has been reached. The output voltage Vro settles to a value given by the supply voltage Vs, the holding current and the internal resistance of the excitation winding 310.
Depending on the magnitude of the supply voltage Vs, conditions in which the relay controller 500 cannot provide a sufficient excitation current can arise in this or a preceding state. An undervoltage sensor circuit 570 detects if the supply voltage is too low to provide a sufficient excitation current, and initiates measures for increasing the excitation current. One measure is to bridge the current source by means of a switch having a low voltage drop.
Depending on the magnitude of the supply voltage Vs, conditions in which the power consumption of the relay controller 500 exceeds the permissible power consumption can arise in this or a preceding state. An increased power consumption can occur in the current source that provides the excitation current. The relay controller 500 can have a temperature sensor circuit 560 that initiates measures for reducing the power consumption of the relay controller 500 if a maximum temperature is reached. One measure is to reduce the excitation current. If this measure is unsuccessful, the excitation current can be completely turned off.
The relay is switched off by the high-side switch 210, 211 being switched off. In
This application is a Continuation in Part of U.S. patent application Ser. No. 12/465,678, which was filed on May 14, 2009. The U.S. patent application Ser. No. 12/465,678 claimed benefit of German Patent Application 102008023626.8, which was filed on May 15, 2008. The entire contents of the prior filed applications are hereby incorporated herein by reference.
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Number | Date | Country |
---|---|---|
4325578 | Feb 1995 | DE |
4410819 | Aug 1996 | DE |
69702314 | Dec 2000 | DE |
102004010914 | Sep 2005 | DE |
69731438 | Nov 2005 | DE |
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Number | Date | Country | |
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20120002341 A1 | Jan 2012 | US |
Number | Date | Country | |
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Parent | 12465678 | May 2009 | US |
Child | 13232746 | US |