NO870996L - AA PROTECTOR CONNECTOR CONSUMER CONVERSION. - Google Patents

Description

The invention relates to a coupling device to protect a consumer against overvoltages. as stated in the introductory part of patent claim 1.

In the case of a known switching device of this kind, a ballast resistor is inserted between the switching device's input and output. A voltage limiter consisting of a series connection of an ohmic resistor and a switching element which has two ant ipara1e11 connected thyristors is connected in parallel with the disconnection output, i.e. with the consumer. Limitation of the voltage on the consumer to a maximum permissible peak value is effected by connecting the ohmic resistor when the voltage on the consumer reaches a value corresponding to the voltage limiter's cut-in threshold. This way of limiting voltage, however, has the decisive disadvantage that the ohmic resistance has a linear current-voltage character in the socket, and an increase in the voltage at the input corresponds to a proportional increase in the voltage on the consumer when the voltage limiter is connected.

There are also known switching devices where non-linear components, in particular components with an exponential characteristic work in para11e11kob1 mg to the consumer. Among these devices is also a voltage-dependent resistor, a varistor, which is characterized by a maximum permissible permanent dr in ftsspenmg and a so-called var istor voltage which lies at the breaking point in the varistor's exponent ie11e characteristic. Using a varistor in permanent operation is only possible if the maximum permissible rated voltage on the consumer is lower than the varistor's permissible permanent dr in fts voltage. This condition implies a considerable limitation in the possibility of using varistors.

The invention is therefore based on the task of developing a switching device in accordance with the introductory part of patent claim 1 so that the linear characteristic for the voltage limiter according to the introductory part of patent claim 1 is replaced with a non-linear, steeply exponentially rising characteristic, and that careful dimensioning of the voltage limiter's components ensures that the non-linear components can be used without risk of destruction.

According to the invention, this task is solved with a voltage limiter which exhibits a series connection with a limiter and a switch element.

The limiting varistor has an inherently symmetrical current-voltage characteristic and is therefore suitable both for limiting a direct voltage on the consumer and for limiting a variable 1 voltage, i.e. positive and negative voltages.

The limiting varistor's limiting ability is provided by the steeply exponential rise in the characteristic above where the voltage was large.

Advantageously, in the voltage limiter, a limiting response istor is used if the istor voltage is equal to or greater than the maximum value of the rated voltage that can appear on the consumer. In addition, the istor voltage cannot be less than a maximum permissible peak value of the voltage on the consumer, a peak value for which the components of the consumer to be protected are maximally dimensioned.

An electronic switch consisting of a semiconductor material or also an electromechanical switch, e.g. a relay. Appropriately, the switch element draws the weakest possible blocking current in the blocking position. In the conductive state, the switch element has a small ggennorn 1 iping resistance so the voltage drop on the switch element can be ignored in relation to the voltage drop on the limiting varistor. Advantageously, these properties are fulfilled by a thyristor which is characterized by a holding current at which, during step 1, the thyristor flips back to the blocking 1 position, and at the zero flip voltage, at which, during step 1, the thyristor itself fires, in the positive voltage range. In the negative voltage range, the thyristor behaves like a zener diode and is therefore appropriately used when a DC voltage is to be limited, which can also be a pulsating DC voltage.

Furthermore, the thyristor can also be used as a switch element if an alternating voltage appears at the input to the coupling device, but only a direct voltage is required at the consumer. For this purpose, the occurring alternating voltage is transformed into a direct voltage by means of a rectifier coupling connected in front of the switching device.

To limit alternating 1 voltages on the consumer, bi-directional switch elements are used appropriately. There can e.g. two thyristors are used in an anti-parallel connection, but a triac is advantageously used for the rectional limitation of a voltage on the consumer. A triac has, according to its origin, a symmetrical characteristic and is therefore suitable for connecting alternating voltages.

For the control of the used switch element, the voltage limiter can also have a pass-through switch whose task is to close the switch element when the voltage on the consumer exceeds the voltage limiter's switch-on point. For this purpose, the control switch does not have a characteristic with a threshold value that is either equal to the voltage limiter's switch-in switch 1 or at least is in a functional relationship with the threshold. Appropriately, the voltage limiter's inputs should be equal to or less than the maximum peak value of the consumer voltage. However, since the limiting varistor's characteristic does not have an ideal, infinitely large steepness, the input voltage is chosen to be less than the maximum peak value of the consumer voltage, so that a certain tolerance range can still be passed through on the characteristic up to the peak value. Downwards, the entry range for the voltage limiter's switches is determined by the maximum value of the rated voltage on the consumer. Advantageously, however, the area between the variator voltage and the maximum permissible peak value of the consumer voltage is chosen as the starting range for the voltage limiter's cut-in threshold.

For switching on the switch element, the pas tyring coupling can e.g. a zener diode with protection resistor is connected in parallel with the consumer. But also a diac with foot resistance or a trigger diode connected in parallel with the consumer can be used to control the switch element. Advantageously, however, a control varistor is connected in series with a resistor in parallel with the consumer.

The voltage limiter's control link can also have the task of opening the switch element so that the limiting varistor is disconnected. For this purpose, the controller does not have an additional threshold value that corresponds to or is assigned to the voltage limiter's cut-out threshold 1. To realize the cut-out threshold, the same components or connections as indicated above, in the case of inco1ings take place 1 one. However, the choice of components when it comes to dimensioning is made with a view to the application in the tripping threshold of the voltage limiter. Advantageously, a logic circuit with the task of distinguishing between rising and falling flanks of the voltage on the consumer can be used if there is no need to distinguish between switch-on threshold and switch-off threshold. Thereby, it will be possible to determine that the voltage limiter's input and output connections are independent of each other.

A control cob1 mg that causes both switching on and off of the switch element can be beneficial when using a switch element with two control inputs, e.g. a thyristor tetrode with two drive gates or a GTO thyristor (gate-turn-thyristor), but also by a transistor.

If a thyristor, a triac or another thyristor-like component is used as a switching element, one can advantageously take advantage of the fact that these components have a so-called holding current, if during step 1 the components tilt back to the latch in position 1 .

Appropriately, with respect to dimensions, the thyristor and limiting varistor are selected and matched in relation to each other such that when the voltage limiter's tripping threshold is undercut by the consumer voltage, a tripping current through the limiting varistor is smaller than the mentioned holding current for the thyristor. In this connection, it is appropriate to ensure that the voltage limiter's tripping threshold is equal to or greater than the maximum value of the rated voltage on the consumer.

In the case of limiting a changing 1 voltage on the consumer, a component with unsymmetrical characteristics can be used in the controller to determine the disconnection threshold in the positive and also in the negative voltage range, such as e.g. a zener diode. Conveniently, the voltage limiter's control coupling is then operated in a rectifier-bridge connection, so that only voltages of one polarity appear on the non-linear component, such as e.g. the zener diode.

When using a thyristor or of a tyr istor 1 igning semiconductor component such as e.g. a f i relay diode or a triac as a switching element of the voltage limiter, one can advantageously waive the use of any drive coupling if the thyristor's zero-flip voltage corresponds to the voltage limiter's input coupling 1. The switch-off threshold is then appropriately assigned to the thyristor's holding current.

Further favorable designs of the invention are characterized in the independent patent claims.

In the following, two embodiments of the invention will be explained in more detail with reference to the drawing. Fig. 1 shows a switching device with a thyristor as switching element and with a control varistor in the control circuit. Fig. 2 shows a var istor character istik with a drawn straight rectifier working line and indicating the voltage values that are decisive for the dimensioning of the switching device. Fig. 3 shows another switching device with a triac as a switching element and a zener diode in a rectifier bridge connection as a control connection.

At the entrance 10 to the coupling device S in fig. 1 is located

a voltage source 1 which emits a direct voltage. On the direct voltage, there may be stored overvoltages such as

manifests itself in voltage spikes.

At the output 20 from the connection device S, a consumer 4 is connected in parallel and is protected against overvoltages.

Between the input 10 to and the output 20 from the coupling device S, a ballast resistor 2 is inserted, which summarizes the ohmic losses in a noise correction filter 1 and parasitic ohmic losses in the coupling device, which e.g. the ohmic losses in the wires.

The voltage limiter 3 of the switching device S is connected in parallel with the consumer 4 and is formed by a series connection consisting of a limiting resistor 31 and a switch element 32, and a control switch 33, which is also parallel to the consumer 4.

The limiting varistor 31 has a characteristic with a varistor voltage UVAR and a permanent dr in ft voltage UDVAR which lies below the istor voltage UVAR. The varistor voltage of the limiting varistor 31 is below the maximum value UNMAX

of the rated voltage on the consumer 4 (cf. Fig. 2). The permanent operating voltage UDVAR for the limiting varistor 31 is below the minimum value UNO of the rated voltage on the consumer 4.

A thyristor 321 with a gate 3211 for switching on the thyristor 321 is used as the switch element 32. The thyristor 321 has a holding current, when it slides back to the locked position.

Påstyringkob1 none consists of a påstyring ingsvar istor 331 and

a control resistor 332 in a power connection which is parallel to the consumer. The midpoint clamp 333 between the control varistor 331 and the control resistor 332 is here connected to the control electrode 323 for the switch element 32, here with the gate 3211 of the thyristor 321.

The control varistor 331 has a var istor voltage UAVAR which is approximately equal to the switch-in threshold 1 and UINN for the voltage limiter 3 at the switching device S. The var istor voltage UAVAR on the control varistor 331 is higher than the var istor voltage UVAR on the limiter istor 31 and is equal to or less than the maximum permissible peak value UMAX of the consumer the voltage on the consumer 4.

If the voltage on the consumer 4 switches 1 exceeds a UINN for the voltage limiter 3, a current that is sufficient to ignite the thyristor 321 passes through the control thyristor 331 to the gate 3211 of the thyristor 321. Thus, the limiting varistor 31 is switched on and limits the voltage on the consumer 4 to a value which in the ideal case of infinitely steep characteristic for the limiting varistor 31 corresponds to was in the large voltage, but which due to the finite steepness of the characteristic lies insignificantly above the varistor voltage UVAR. If the value of the noise voltage on the consumer 4 falls below the cut-out 1 a UUT for the voltage limiter 3, a threshold that lies between the maximum value UTMAX and the cut-in threshold UINN, a cut-out current I UT, which is smaller than the holding current, passes through the limiting varistor 31 in accordance with its characteristic for the thyristor 321, so the thyristor 321 flips back to the off state. Thus, the limiting varistor 31 is switched off.

Fig. 3 shows another design example of the coupling device S. With this coupling, the voltage limiter exhibits

3.1 in series with the limiting varistor a bit in rectional switch element 32.1, which is a triac 321.1. The Triassic 321.1

has, according to its origin, symmetrical characteristics, and thus it is ensured that an alternating voltage can be limited at the output from the coupling device S.

Control cable 33.1 of the voltage limiter 3.1 has a rectifier bridge connection with rectifier diodes 334.1, whose input port 338.1 is parallel to the consumer 4, and whose output port 339.1 is in a series connection with two protection resistors 337.1 and a zener diode 335.1 polarized in the blocking direction. The outlet terminal 336.1 is connected to the gate 3211.1 of the triac 321.1.

A UINN input for the voltage limiter 3.1 is, thanks to the connection of the zener diode 335.1 with a rectifier bridge connection, equated with the zener voltage of the zener diode 335.1 with regard to absolute value. The tripping threshold UUT for the voltage limiter 3.1 is determined by the main current for the triac 321.1. If the voltage on the consumer 4 exceeds the switch-on threshold UINN in terms of amount in the negative or positive direction, a current passes through the zener diode 335.1 which is limited by the protection resistors 337.1. From the output terminal 336.1 there then goes to the street of the triac 3211.1 a current sufficient to light the triac 321.1. The limiting varistor 31 is connected and limits the voltage on the consumer 4 absolutely calculated to a value in the range of the istor voltage UVAR. The limiting varistor 31 remains connected as long as the voltage on the consumer absolutely falls below the cut-off threshold UUT. The current through the limiting varistor 31 is then, in terms of absolute value, smaller than the holding current for the triac 321.1, which thereby flips back to the latch in the 1 position and disconnects the limiting varistor 31.

Claims (8)

1. Coupling device (S) to protect a consumer (4) against an overvoltage greater than a maximum permissible peak value (UMAX), comprising an input (10) for connection to a voltage source (1), an output (20) for connection of the consumer (4), as in nominal operation has a rated voltage located between a minimum value (UNO) and a maximum value (UNMAX), a ballast resistor (21) between the input (10) and the output (20) and a voltage limiter (3) containing a series circuit with a resistor and a switch element (32) and is parallel to the output (20), and which exhibits a switch-on switch 1 (UINN) and a switch-off switch 1 (UUT), characterized by that there serves as resistance a limiting varistor (31) with a var istor voltage (UVAR) and a maximum permissible continuous operating voltage (UDVAR), that the limiting varistor (31) was too large voltage (UVAR) is equal to or greater than the maximum value (UNMAX) of the rated voltage on the consumer (4), and this maximum value (UNMAX) is equal to or greater than the limiting varistor's (31) maximum permissible continuous operating voltage (UDVAR), that the voltage limiter (3) output 1 input 1 (UUT) is equal or greater than the maximum value (UNMAX) of the rated voltage on the consumer (4), and that the voltage limiter (3)'s input is 1 (UINN). equal to or less than the maximum permissible peak vedi (UMAX) of the consumer voltage. 2. Coupling device as specified in claim 1, characterized in that the voltage limiter (3) has a control connection (33) with the connection threshold (UINN) for control of the switch element (32). 3. Coupling device as stated in claim 2, characterized by that the control connection (33) consists of a series connection with a control varistor (331) with the largest voltage (UAVAR) and a control resistor (332), and that the midpoint clamp (331) between the control variable (331) and the control resistor (332) is connected to a control electrode (323) at the switch element (32). 4. Coupling device as specified in claim 3, characterized in that the absolute value of the control varistor's (332) varistor voltage (UAV) is greater than the absolute value of the limiting varistor's (31) varistor voltage (UVAR). 5. Coupling device as specified in one of claims 1-4. characterized by that a thyristor (321) with a holding current serves as the switching element (32), and that the voltage limiter's (3) tripping current 1 (UUT) corresponds to a voltage drop on the limiting varistor (31) with an associated tripping current (IUT) which is equal to or less than the thyristor's (321) holding current. if during step 1 see the thyristor (321) tilts back to the blocking position. 6. Coupling device as stated in one of the claims 1-4, characterized in that in the case of an alternating voltage at the input (10) to the coupling device (S) a bit is arranged in the rectiona11 switch element (32.1) in the voltage limiter (3.1). 7. Coupling device as stated in claim 6, characterized by that the voltage limiter (3.1) exhibits a double-bridge connection with an input port (338.1) and an output port (339.1), that the input port (338.1) is connected to the output (20) of the coupling device (S), and that the control switch (33.1) of the voltage limiter (3.1) is parallel to the output port (339.1). 8. Coupling device as stated in claim 1, characterized by that a thyristor (321) also serves as a switching element (32). a holding current and a zero-flip voltage, that the voltage limiter (3) switch-on threshold (UINN) is equal to the zero-flip voltage of the thyristor (321), and that the tripping threshold (UUT) of the voltage limiter (3) to responds to a voltage drop on the limiting varistor (31) with an associated cut-off current (IUT) which is equal to or less than the thyristor's (321) holding current (IH), when the thyristor (321) falls below this the thyristor (321) flips back to the block in the 1 position.