NL9400394A - Circuit. - Google Patents

Description

Circuit

The invention relates to a circuit for the electronic switching of electronic elements, electrical elements or electromechanical elements by means of semiconductors, as can be used for, for example, mains switches

In the known mechanical mains switches, switching is effected mechanically by means of mechanical parts. Such a mechanical construction is sensitive to defects and contamination. This is all the more true in an environment with a hostile environment. When the switch is to be used in an environment where there is a risk of explosion, the construction of the switch is subject to expensive requirements regarding the explosion safety of the switch. Also, a mechanical design of a switch implies limitations with regard to the design of the housing, which makes protection against the risks described above with the aid of that housing difficult and expensive. In addition, the maintenance and cleaning of a mechanical switch in connection with the above is difficult and expensive.

The above drawbacks could be overcome by electronically switching electronic, electrical or electromechanical elements, such as a relay, with semiconductors. However, authorities and inspection bodies such as KEMA and V.D.E. for safety reasons, refuse to approve electronic switching of electronic, electrical or electromechanical elements in, for example, switches with semiconductors, because failure of the semiconductor in the existing systems may result in energization of the system and the switched element.

The object of the invention is to obviate the drawbacks of the known circuit.

To this end, the circuit for switching electronic, electrical or electromechanical elements by means of semiconductors according to the invention is characterized in that the energy transfer from the switching element to the switched element is effected by a voltage-transmitting element, the switching element and the switched element galvanically separates.

According to another characteristic of the circuit according to the invention, the voltage-transmitting element is formed by a transformer.

According to yet another feature of the circuit according to the invention, it is provided with means in the primary circuit, by means of which the maximum energy transfer is limited, such that the circuit is protected in the event of a short circuit in the switching element.

According to yet another feature, the means in the primary chain for limiting the maximum energy transfer is formed by a series resistor.

Normally, when the electronic, electrical or electromechanical element is to be switched, the switching element, a semiconductor, passes an alternating current through the primary coil of a transformer, which then generates an alternating voltage in the secondary coil. This voltage, rectified or not, drives the electronic, electrical or electromechanical element. In the event of a short circuit or interruption of the switching element, a direct current or no current will flow through the primary coil. In both cases no voltage is generated in the secondary coil and the switched element cannot be energized in any way. According to an embodiment of the present invention, a series of resistors in the primary circuit limits the maximum energy transfer, so that the circuit is protected in the event of a short circuit in the switching element, the semiconductor. Also defects in any peripheral electronic, electrical or electromechanical elements can in no way lead to energization of the switched element.

The configuration according to the invention guarantees that the electronic, electrical or electromechanical elements, for example a relay, cannot be energized in any way by any possible defect in the switching element.

The invention will now be further elucidated with reference to a drawing of an exemplary embodiment. The figure relates to a circuit diagram for the electronic switching of a relay by means of a semiconductor, such as can be used in, for example, a mains switch.

As shown in the figure, the switching element 2, in this embodiment a transistor 2, is included in the circuit 1. If an alternating voltage with favorable chosen properties is applied to input 3, the transistor 2 will cause an alternating current to flow to the primary winding 4 of the voltage-transmitting element 5, in this embodiment the transformer 5. A favorable choice of the transformer, which can efficiency of the circuit, for example, is a highly coupled transformer for the 10 KHz. area. The transformer in this case has a 1: 1 transfer ratio and low core losses, which ensures efficient energy transfer. Given the low voltages, there are no extreme requirements for the insulation between the primary and the secondary winding of the transformer. In this case, a 10 KHz signal must be offered to the transformer for a short time. This creates an alternating voltage across the terminals of the secondary winding 6 of the transformer 5. In this exemplary embodiment, this voltage is rectified across rectifier bridge 7. The voltage is then applied to the switched element 8, in this exemplary embodiment a relay 8. In this exemplary embodiment the relay 8, which consists of an armature with two switching contacts 9 and 10 and an excitation winding 11, placed in a hold switch configuration? when a signal in the form of the above-mentioned AC voltage is briefly applied to the transistor 2, the relay 8 will be energized and will remain energized until the connection between the protective circuit breakers 12 and 13 is broken. An interrupt contact can optionally be included as an off switch at this location in the circuit. In this exemplary embodiment, the circuit is therefore only active for a very short time, namely only at the time of switching. In this exemplary embodiment, the series of resistor 14 in the primary circuit limits the maximum direct current in the primary chain, in the case of a short circuit in transistor 2. Furthermore, in the figure a resistor 15 and two capacitors 16, 17 are indicated. A direct current flows through the conductive path 18. The conductive path 19 allows a signal to be given in the form of an alternating voltage with properties that allow the current to make transistor 2 and transformer 5 perform their respective functions. The conductive path 20 is the mass.

In this embodiment of the invention, the energy required for the switched element of the invention is generated by a converter or generator circuit. Many variants are conceivable on this embodiment, all of which remain within the scope of the invention. such as a full bridge converter, a half bridge converter, an isolated forward converter, an isolated flyback converter, the non isolated step up converter, the non isolated step down converter, etc.

In another embodiment according to the invention, the various parts of the circuit can be integrated. More in particular, it is possible to integrate the resistor 14 in the transformer 5 serving as a voltage-transmitting element, by a favorable choice of the ohmic resistance of the primary winding 4. An embodiment is also conceivable in which the transformer 5, the optional rectifier 7 and relay 8 are integrated.

In yet another embodiment, the circuit can be combined with a piezoelectric element, which provides a voltage pulse upon contact. This voltage pulse serves as a sign for energizing the circuit.

In another embodiment, the circuit is extended with a microcontroller where the voltage pulse is applied to the microcontroller.

In yet another embodiment of the invention, the microcontroller is provided with software. The microcontroller processes the offered signals and in turn, based on the software stored in the microcontroller, controls the circuit for switching electronic, electrical or electromechanical elements by semiconductors, by offering a signal to the switching element in the form of a current suitable for the switching element and the voltage-transmitting element to perform their respective functions.

In yet another embodiment according to the invention, the above-described configuration of the circuit with a piezoelectric element and a microcontroller is extended with a variable current limitation and current control system. When the variable current limiting and current control system are conveniently connected to the microcontroller, it is possible to have the information of the variable current limiting and current control system processed by the microcontroller. This makes it possible to have the microcontroller switch off the power if the preselected values are exceeded on the basis of preselected decision criteria.

In another exemplary embodiment according to the invention, the variable current limiting and current control system consists of a specially designed transformer, which consists of only one or even one winding. The thickness of a wire has been chosen to be sufficient for the current to be measured. This makes the voltage drop across the primary winding extremely small. The secondary winding is done in such a way that the secondary voltage is (straight) proportional to the current through the primary winding. As a result, the voltage on the secondary winding is a direct indication of the current in the primary winding. The secondary voltage thus measured is compared with an adjustable reference voltage. In summary, four states are now conceivable: no current, overload, short circuit and normal current. The current is qualified by using predetermined margins for exceeding the reference voltage when comparing the secondary voltage with the reference voltage.

In another embodiment according to the invention, a status indication system, for example in the form of a display with LEDs, is connected to the microcontroller in the above-described configuration, so that it is possible to monitor the status of the system.

In another embodiment according to the invention, the above-described configuration of the circuit with a piezoelectric element, a microcontroller, a variable current limiting and current control system and a status indication system is incorporated in a fully enclosed, environmentally resistant housing.

The invention is not limited to the above-described exemplary embodiments. Many variants are conceivable using the invention.

Claims (17)

Circuit for the electronic switching of electronic, electrical or electromechanical elements by means of semiconductors, characterized in that energy transfer from the switching element to the switched element is effected by a voltage-transmitting element, the switching element and the switched element completely galvanically separated from each other. Circuit according to claim 1, characterized in that the voltage-transmitting element is a transformer. Circuit according to claim 1 or 2, characterized in that it is provided in the primary circuit with means by which the maximum energy transfer is limited such that the circuit is protected in the event of a short circuit in the switching element. Circuit according to claim 3, characterized in that the means are formed by a series of resistors in the primary chain. Circuit according to claims 1 to 4, characterized in that the energy required for the switched element is generated by a converter. Circuit according to claims 1 to 5, characterized in that the switched element is formed by a relay. Circuit according to claims 3,4,5 or 6, characterized in that the resistor is integrated in the transformer by a favorable choice of the ohmic resistance of the primary winding of the transformer. Circuit according to claims 1 to 7, characterized in that the voltage-transmitting element, the rectifier, if present, and the switched element are integrated. Circuit according to claims 1 to 8, characterized in that the circuit is combined with a piezoelectric element, which gives a voltage pulse on contact. Circuit according to claim 9, characterized in that the circuit is combined with a microcontroller which processes the signals presented by the piezoelectric element. Circuit according to claim 10, characterized in that the microcontroller, on the basis of the signal supplied by the piezoelectric element, applies signals to the circuit in the form of a current suitable for the switching element and the voltage-transmitting element to perform their respective tasks. to fulfill. Circuit according to claim 11, characterized in that the configuration is extended with a variable current limiting and current control system, such that these, in combination with the piezoelectric element and the microcontroller, make it possible to control and control the current. Circuit according to claim 12, characterized in that the variable current limitation and the current control system are formed by a transformer advantageously designed for this purpose. Circuit according to claim 13, characterized in that the configuration is extended with a status indication system, such that this, conveniently connected to the microcontroller, makes it possible to monitor the status of the system. Circuit according to claim 14, characterized in that the microcontroller has software which enables the microcontroller to control the configuration on the basis of predetermined criteria and values. Circuit according to any of the preceding claims, characterized in that the configuration is contained in a fully enclosed, environmentally resistant housing. Circuit according to any of the preceding claims, characterized in that it is incorporated in a switch, more particularly a mains switch.