HU194458B - Low-distortion semiconductor relay - Google Patents

Abstract

Field of the Invention The present invention relates to an optical separator for an input of an interrupted semiconductor relay controller via an input interface, and a power switch is connected to the switch output by means of a polarity adapter. The object of the semiconductor relay according to the invention is that a logic gate (3) is placed between the optical separator (2) and the power switch (5), the logic gate (3) is connected to the output of the power switch, the optical separator (1) being connected to one of its inputs. 2), the other input is connected to the overcurrent monitor (4) and the sensor input (23) of the overcurrent monitor (4) is connected to the power switch (5). Figure 1 -1-

Description

FIELD OF THE INVENTION The present invention relates to a semiconductor relay with a transistor, which is connected to an input of a relay controller via an optical adapter, which is powered by a power switch via a polarity adapter.

Such a semiconductor relay is manufactured, inter alia, by Siemens, which is described in pages 69-74 of Booklet 2 of 1980, Siemens Components. pages.

Such well-known semiconductor relays can replace conventional electromechanical and reed relays. They provide greater reliability, lifetime, smaller size and noiseless switching.

The switching and operating characteristics of currently known semiconductor relays are discussed in detail in, for example, "Semiconductor Relays in Practice" (Yearbook of Radio Technology, '1981, Zrínyi Katonai Kiadó, Budapest, p. 29). Further solutions are disclosed in US 4,339,670. Zero Voltage Switching AC Relay Circuit.

The output switch of the known semiconductor relays contains a transistor or FET for lower switched voltages and a triac or thyristor for higher voltages. The disadvantage of such a solution is that the AC signal is distorted due to a voltage surge at the zero crossing of the signal when higher voltages are applied. Some applications are also made difficult by the high transient resistance of the switches (eg 70 Ω at 100 mA) and current-dependent or slow switching time (0.5 to 2 tns) relative to the fast operation of electronic circuits.

A further disadvantage of the known semiconductor relay is that they are sensitive to overcurrent and the resulting errors can only be known directly. In addition, large switching currents require a significant holding current to continuously close the contact.

Due to the above disadvantages, it is not always possible to establish contact networks from current semiconductor relays.

The object of the present invention was to overcome the above disadvantages, to provide a circuit realization suitable for the design of contact networks and to provide a solution insensitive to the harmful effects of overcurrent.

The object has been achieved by the introduction of a semiconductor relay with a circumscribed kits with a logic gate between the optical isolator and the power switch, the logic gate being connected to the output of the power switch, one of its inputs being connected to the optical separator and the other and the overcurrent monitoring sensor input is connected to a power switch.

Preferably, for good galvanic isolation, it comprises a dc-to-dc converter which has a transformer disconnection in the ac voltage section and the output of which is the power braid of the optical disconnector output circuit, the logic gate, the overcurrent monitor.

In one embodiment of the resistivity semiconductor relay according to the invention, a current monitoring resistor in the overcurrent monitor is connected from the sensor input to the reference ground, a serially coupled delay, a combiner, a logic OR gate, and a further input to the logic OR gate. a capacitor and a series-connected diode, a differentiator and a switch are connected in parallel, and a feedback resistor is connected between this input and output of the logic OR gate.

Preferably, the power switch comprises a grounded emitter-connected transistor, the base of the transistor is connected to a logic gate, its collector is connected to a polarity adapter, and its emitter is connected to an overcurrent sensor input.

In a further embodiment of the solid state relay relay according to the invention, the polarity adapter comprises a rectifier diode bridge, one terminal of the diode bridge being connected to a reference point, the opposite terminal being connected to a power switch and the other two terminals forming the output of the arrangement switch.

According to another embodiment of the invention, the polarity comprises a diode bridge supplemented by polarizing resistors and a potentiometer, the two points of the diode bridge forming the switch output of the arrangement, the switch outputs being connected symmetrically from the reference point and the bridge element diodes. From the switch outputs, additional bridge element diodes are connected to the two ends of the potentiometer and the potentiometer control point is connected to the power switch.

In a further embodiment of the semiconductor relay according to the invention, an overvoltage protector is inserted between the two switching outputs of the arrangement in the polarity adapter.

In a further embodiment, an overcurrent indicator is connected to the overcurrent monitoring output.

In another embodiment, the overcurrent indicator is a light emitting diode.

The transistor semiconductor relay of the present invention will be described with reference to the exemplary embodiment, wherein:

Figure 1 is a block diagram of a low-frequency semiconductor relay, a

Figure 2 shows a possible switching of the overcurrent monitor, a

Fig. 3 shows the layout of the power switch and the first version of the polarity adapter, a

Figure 4 shows the layout of the power switch and the second version of the polarity adapter.

A power switch 5 is connected to the input 29 of the semiconductor relay controller, as shown in Figure 1, via an input adapter 1, an optical separator 2, and a logic gate 3. The power switch 5 is connected to output 30 via the polarity adapter 6, the output of logic gate 3 is connected to the power switch 5 and its input is connected to the optical divider 2 and the overcurrent monitor 4. A power switch 5 is connected to the input 23 of the overcurrent monitoring sensor and an overcurrent indicator 28 is connected to its output, for example a light emitting diode.

The actuator signal of the semiconductor relay with a capacitance is applied to the input 29 and the switching function is performed by the output 30.

The adapter 1 and the optical separator 2 are constructed in a manner known in the art. The adapter 1 contains transistor or other transducer, current limiting and interference suppression elements, and the optical separator 2 is a conventional optocoupler. The total galvanic separation is provided by the 31 equations-21

194,458 • an AC to DC converter having a transformer disconnection in its alternating voltage circuit.

The power switch 5 comprises, as shown in Fig. 3, a grounded emitter switching transistor 7. The base of the transistor 7 is connected to the output of the logic gate 3, its emitter is connected to the input 23 of the overcurrent monitoring sensor, and its collector is connected to the polarity adapter 6.

The polarity adapter 6 consists of a diode bridge 8 and a surge protector 9 positioned between the two outputs 30 as shown in FIG. The two opposite points of the diode bridge 8 are connected to the switch outputs 30, the third point to the reference ground and the fourth point to the power switch 5.

The overcurrent monitor 4 of the distorted semiconductor relay normally switches a signal to the logic gate 3 which causes the control signal from the input 29 to drive the power switch 5 through the logic gate 3 through the optical divider 2. The transistor 7 of the power switch 5 is in a conductive state as a result of a control signal at input 29. Any polarity signal at the outputs 30 causes current to flow through the collector, emitter of transistor 7. The rectifier diode bridge 8 ensures that the polarity of the signal at the output 30 does not influence the direction of current flowing through transistor 7. The transistor 7 and the diode bridge 8 are protected against overvoltage by the surge protector 9. A Zener diode or varistor can be used for this purpose. The current applied to the switch outputs 30 flows through the diode bridge 8 polarity diodes, the collector, emitter and input 23 of transistor 7 to operate the overcurrent monitor 4. If the flow rate exceeds a given limit, the overcurrent monitor 4 drives the logic gate 3 to a state which, independently of the control signal of the input 29, interrupts the current closed circuit through the power switch 5, i.e. the outputs 30 are open.

An overcurrent indicator 28 is also connected to the output of the overcurrent monitor 4. This is the case when the output current 30 is interrupted by the overcurrent monitor through logic gate 3 due to an overload current exceeding the allowable current level, it warns of overcurrent by optical signaling.

Figure 4 shows a variant of the polarity adapter 6. This differs from the solution shown in Fig. 3 in that the diode bridge diodes 24, 25, 26, 27 are supplemented with resistances 10.11 and a potential field 12. From the reference point, a series of resistors 11 and 24 diodes lead to one of the terminals of output 30 and then to one end of the potentiometer 12. Thus, symmetrically, a further series of resistors 10 and diodes 25 are connected from the reference point to the other terminal of output 30 and then to the other end of potentiometer 12. The control point of the potentiometer 12 is connected to the collector of the transistor 7 of the power switch 5.

By default, the control signal applied to the input 29 causes the transistor 7 to conduct, so that auxiliary current flows through the following path starting from the reference point in the two branches of the diode bridge 8, provided that the reference point voltage is positive. On the one hand through the resistor 11 and the diodes 24, 26 and on the other hand through the resistor 10 and the diodes 25, 27. The two auxiliary currents are terminated on the potentiometer 12, connected together via the control point and transistor 7. If, in this state, the output terminals 30 have an AC or DC signal having an amplitude less than the voltage drop caused by the auxiliary current flowing through the diodes 26 and 27, the current generated by the signal at the output 30 is terminated by the potentiometer 12 and 27 . The output 30 then exhibits a low output resistance to the associated elements. If the current flowing through the output terminals 30 is greater than the auxiliary current flowing through the diodes 26, 27, the differential current flows through one of the diodes 26, 27, the potentiometer 12 and the transistors 7, respectively. The overcurrent monitoring function of this variant is the same as previously known.

Figure 2 illustrates an embodiment of an overcurrent monitor. In this connection, a current resistor 13 from the sensor input 23 to the reference earth, a delay 14, a comparator 15, a logic OR gate 16 and a further delay 17 connected in series to the logic gate 3 are connected. From one of the other inputs of the logic OR gate 16 to the reference ground, a capacitor 19 and a series-connected diode 20, differentiator 21 and switch 22 are connected in parallel, and a resistor 18 is connected between this input and output of the logic OR gate 16.

The path of current applied to the switch output 30 is closed through transistor 7 and current monitor resistor 13. If the current at the outputs 30 and thus at the current monitor resistor 13 exceeds a critical value, the overcurrent monitor 4 interrupts the current path through logic gate 3. The increased voltage at the current monitor resistor 13 with the timing defined by the delay 14 - which disables the very short overcurrent shocks by tilting the comparator 15 which actuates the logic gate 3 through the logic OR gate 16 and receiving the other input controls the transistor 7 independently of the control signal.

As the output of logic OR gate 16 tilts, the arrangement of feedback resistor 18 and capacitor 19 will provide a disable signal to the other input of logic OR gate 16, regardless of any resetting of comparator 15. This means that due to the disappearance of the overcurrent, the control path of the input 29 will not automatically close the current path.

The logic OR gate 16 with its associated feedback resistor 18 and capacitor 19 thus performs a storage function. Switch 22, differentiator 21 and diode 20 serve to clear the storage, i.e. reset the array. Switch 22 can only reset the arrangement if the current monitor resistor 13 does not have a higher current than the allowable value. Otherwise, the effect of the switch 22 is prevented by the differentiator 21, so in the event of an overload it is not possible to close the outputs 30 of the semiconductor relay switch until the overcurrent is eliminated,

The distorted semiconductor relay according to the invention can advantageously be used to form contact networks, in particular due to the low output resistance and fast switching time. A further advantage is that they can be easily identified from the adverse effects of possible overload by the signal of the built-in overcurrent indicator.

Claims (9)

A clustered semiconductor relay having an optical divider connected to an input of a relay controller via an input adapter, and a power switch coupled to said switch output, wherein said optical separator (2) is a logic gate (5) between said power switch (5). 3) is located, the logic gate (3) is connected to the output of the power switch (5), one of its inputs is connected to the optical separator (2), the other input is connected to the overcurrent monitor (4) and the overcurrent monitor (4) ) is connected to the power switch (5). A semiconductor relay according to claim 1, characterized in that it comprises a dc-to-dc converter (31) having a transformer disconnection in its ac voltage section and output from the output circuit of the optical disconnector (2), the logic gate. (3), provides the power supply for the overcurrent monitor (4). The semiconductor relay according to claim 1 or 2, characterized in that in the overcurrent monitor (4), a current monitoring resistor (13) from the sensor input (23) to the reference ground, and a delay (3) connected in series to the logic gate (3). 14), a comparator (15), a logic VAGV gate (16) and a further delay (17) connected from the other input of the logic OR gate (16) to the reference earth by a capacitor (19) and in parallel a diode (20) connected in series; 21) and a switch (22) are connected, and a feedback resistor (18) is connected between this input and output of the logic OR gate (16). 4. Semiconductor encoder according to any one of claims 1 to 3, characterized in that the milk power switch (5) comprises a grounded emitter (7), a base of the transistor (7) with a logic gate (3), a collector with a polarity adapter. 5 (6), and its emitter is connected to the input (23) of the overcurrent monitor (4). 5. A semiconductor relay according to any one of claims 1 to 3, characterized in that the polarity adapter (6) comprises a rectifier diodes (8), one of the terminals of the diode bridge (8) at the reference point and the opposite terminal at the power switch (5). is connected, and the other two terminals form the output of the switch. 6. A semiconductor relay according to any one of claims 1 to 3, characterized in that the polarity adapter (6) comprises a diode bridge (8) supplemented with resistors (10, 11) and a poten'5 ciometer (12), the two points of the diode bridge (8) being comprising a switch output (30), a series of resistors (10, 11) and a bridge element connected in series to the switch outputs (30) symmetrically to the reference point 2q diodes (24, 25) are connected, from the switch outputs additional bridge element diodes (26, 27) are connected to both ends of the potentiometer (12) and the control point of the potentiometer (12) is connected to the power switch (5). 7. A semiconductor relay according to any one of claims 1 to 3, characterized in that an overvoltage protector (9) is inserted in the polarity adapter (6) between the two switching outputs (30) of the arrangement. 8. A semiconductor relay according to any one of claims 1 to 3, characterized in that a An overcurrent indicator (28) is connected to the output of the overcurrent monitor (4). The semiconductor relay according to claim 8, characterized in that the overcurrent indicator (28) is a light emitting diode.