CS229554B1 - Measurement Point Trigger Circuit Wiring - Google Patents

Abstract

The subject of the invention is a circuit connection for fault signaling of measuring points implemented by semiconductor components, which summarizes all the requirements that may be placed on such a circuit in industry. The connection is particularly suitable for production in the form of a hybrid integrated circuit. The above is achieved by a connection that generally consists of a delay circuit part for delaying the input signal to eliminate sensitivity to unwanted pulses, a part for optical signaling, acoustic continuous signaling, acoustic intermittent signaling, a part for fault clearance and circuit integrity testing.

Description

The invention relates to the circuitry of a fault signaling circuit of measuring points suitable for mass production in the form of a hybrid integrated circuit useful for many fault signaling applications in industry and elsewhere.

So far, the most common way of signaling faults of measuring points is signaling by means of relay elements connected in a logic sequential circuit. These types of alarm signals are currently the most widespread under different type designations and are still produced by many manufacturers. The disadvantages of these signaling systems are the high power consumption, often the low reliability, the robustness of the whole equipment and the unsuitability in some types of environment as with the danger of explosion or fire, which is due to the use of relay elements. They enable processing of only the fault signal of the monitored measuring point, which is determined by closing the switching contact of the relay. The evaluation of the fault signal, which is given in another form, for example by a break contact, a transistor, a thyristor, etc., requires further auxiliary circuits. Additional auxiliary and timing relays are required to accomplish other secondary functions such as flashing light, acoustic signaling, alarm delay and the like. On a global scale, there is a general trend towards switching to semiconductor devices in this area, and most recently in the form of integrated circuits.

The previously described drawbacks eliminate the circuitry of the measuring point fault signal circuit according to the invention, which consists of a circuit where the input terminal from the external expansion element is directly connected to the input transistor base, the input terminal from the external switching element is connected to the input transistor base via protective resistor, the positive voltage supply terminal is connected to the input transistor collector, the input transistor emitter is connected to the first control terminal, the time constant resistor r, the first resistor divider and, if the second thyristor is part of the circuit, its anode, the time constant resistance τ is connected to the positive pole of the time constant capacitor τ and the emitter of the second transistor, or the time constant resistance τ as an external off-circuit element is connected between the first control terminal and the second control terminal connected to the emitter of the second transistor time constants τ between the second control terminal and the zero potential terminal of the supply voltage, further the base of the second transistor is connected to the collector of the third transistor, with the first resistance of the resistive divider and the second resistance of the resistive divider, the collector of the second transistor is connected to the base of the third transistor; connected to a discharge resistor and through a protective resistor, a forward diode to the control electrode of the first thyristor, or, if the thyristor is an external circuit component, to a third control terminal. Further, the terminal of the external expansion element is connected to the anode of the first thyristor and the cathode of the first thyristor, or the fourth control terminal, if the thyristor is an external component of the circuit, is connected via a protective resistor, forward diode to the control electrode of the second thyristor. or if the second thyristor is an external component of the fifth control terminal, then through the forward diode to the auxiliary terminal, through the protective resistor and the forward diode to the continuous acoustic signal terminal, through the resistor and the forward diode with the base of the transistor, the collector of the switching transistor as well as the collector of the sixth transistor, the cathode of the second thyristor, or the sixth control terminal if the thyristor is an external component of the circuit and the resistor diode in the reverse direction and protective resistor to the signal test terminal, the pulse voltage input terminal is connected via a protective resistor based on switching transistor, the emitter of this transistor is connected via protective resistors to bases sixth and seventh transistor, emitter sixth transistor is connected through a protective resistor and a forward diode to the output terminal of the intermittent acoustic signaling, the output transistor collector is connected to the optical signal output terminal.

On the one hand, the emitter of the sixth transistor via the emitter resistor, on the other hand the emitter of the seventh transistor, on the one hand the emitter of the transistor, on the other hand the first cathode resistor potential supply voltage.

This measurement point fault signaling circuit is particularly well suited for manufacturing as a hybrid integrated circuit and as such can be considered as a universal solution, accepting all the requirements that this circuit must meet, for example in the harsh chemical and chemical environments of both functional and functional safety, reliability and easy maintenance. The circuit allows processing of the fault signal not only from the switching element but also from the expansion element, which can be made both by relay contacts and by semiconductor devices. Sensing and control elements in the semiconductor design are minimally loaded and the whole circuit has considerably lower power consumption compared to the solution with relay elements. A significant reduction in the dimensions of the equipment is also a benefit.

The accompanying drawings show a fault signal circuit according to the invention, in which FIG. 1 shows the circuit itself, and FIG. 2 shows a particular embodiment of the fault signal circuit with external elements.

In Fig. 1, the signal is applied either to the input terminal 1 from the external expansion element or to the input terminal 2 from the external expansion element and either directly in the first case or through a protective resistor RI in the second case based on the input transistor TI. TI ensures minimal load of external switching or expansion elements, protective resistor RI provides protection of input transistor base TI against overload. The signal from input transistor T1 is applied to the fault signaling delay circuit. The delay circuit is designed to delay the signal coming from the input transistor T1 as needed, thereby ensuring that the output pulse from the delay circuit is only transmitted if the input signal is permanently present for a time constant r, which is given by the resistance of time constant τ R2 and the capacitance of time constant τ Cl. This ensures that the alarm module will only respond to an input signal that has a minimum duration given by the time constant τ and will not respond to a shorter input signal. As a switching element in the delay circuit, a second transistor T2 and a third transistor T3 in the so-called two-phase diode are used. The mode of this switching element is set by the first and second resistor divider R3 and R4. The output pulse from the delay circuit is taken from the discharge resistor RS through which the capacitance of the time constant τ Cl is discharged when the switching member is closed.

This output pulse is then routed via a protective resistor R6 and possibly a protective diode D1 to the control electrode of the first thyristor Tyl, which serves as a memory element for keeping the failure coming until the operator opens the "fault clearance" button connected to the terminal 5 circuit of the first thyristor Tyl. The cathode resistor R18 serves to provide a minimum holding current value of the first thyristor Tyl so that it remains closed when the pulse on the control electrode is terminated. A signal is drawn from this resistor, which is applied to the control electrode of the second thyristor Ty2 via a protective resistor R7 and possibly a protective diode D2. The cathode resistor R17 is used to set the minimum holding current value of the second thyristor Ty2 so that it remains in the closed state until the fault has ended.

The signal taken from the cathode resistor R17 is delayed by the time constant τ after the input signal and terminated at the same time. This signal is routed through a protective resistor R10 based on the terminal transistor T4. Upon the arrival of this signal, the transistor T4 switches the signal lamp connected to the optical signal output terminal 11.

In addition, a signal providing power to the optical and acoustic fault signaling circuits is taken from the resistor R18. This signal can be taken from the terminal of the auxiliary devices fi and can be used to control auxiliary and auxiliary devices up to a maximum power consumption of 0.3 A. The D3 separator ensures that the fault signal circuit is not influenced by signals from external devices. A continuous signal taken from the cathode resistor R18 via a protective resistor RS and a decoupling diode D4, which switches the continuous audible alarm horn via an external switching circuit, will appear at the continuous alarm terminal 7,

In the event that the fault lasts longer than the delay time τ of the delay circuit and ends before the operator presses the pushbutton, the transistor T4 will be energized via a working resistor R9 and a decoupling diode D5 to ensure that the optical circuits and acoustic signaling will not interfere with each other. To control the indicator lamp and terminal transistor T4, a voltage can be applied to the test lamp terminal 8 via an external switching element. This signal is applied via a protective resistor R11 limiting the maximum selected current and a diode DS providing mutual interference based on terminal transistor T4.

A pulse voltage from an external source is applied to the pulse voltage input terminal 8 via a protective resistor R12 based on a switching transistor T5. It is used for impulse switching and supply of voltage pulses to transistors T7 and TB. Transistor T7 is used for closing the transistor T4 for intermittent optical signaling function. A signal is drawn from the emitter resistor R1B via a protective resistor R15 and a diode D7 to the intermittent acoustic signal terminal 10, which switches the intermittent acoustic signal horn through an external switching circuit. The protective resistors R13 and R14 provide the required current to the bases of transistors T7 and TB. Emitter resistor R1B, emitters of transistor T7 and terminal transistor T4, cathode resistors R17 and R18, second resistor of resistive divider R4, discharge resistor RS and time constant capacitor τ Cl are connected to the supply voltage neutral potential terminal 12.

FIG. 2 illustrates the specific wiring of two fault signaling modules according to the invention in conjunction with an alternative source module that complements the fault signaling with some external circuits. The first module of the fault signaling represents the application of the switching element of the measured physical quantity to the input terminal 2, while in the second module the expansion element is connected to the input terminal 1. The positive voltage supply 3 is supplied with stabilized supply voltage from the stabilized source. terminals 23 of the power module. The grounding push-button is connected between the positive voltage supply terminal and the terminal 5. The signaling test switch button is connected between the positive voltage supply terminal and the test signal terminal 8, either for each module individually or for multiple modules in group or even centrally. The optical signal bulbs are connected to the respective unstabilized supply voltage, in this case terminal 22 of the source module, and the output terminal of the optical signaling 11. From the continuous acoustic signal terminal 7, a signal is applied to terminal 27 of the source module where the switching element is located. a thyristor that switches the horn connected between the terminals 25 and 26 of the power module. The source module also includes a pulse voltage source, 9 fault signaling. From the intermittent acoustic signal terminal 10, a signal is applied to terminal 28 of the power module, and the switching element located there intermittently switches the horn connected between terminals 20 and 21. Power is applied to terminals 30 and 31 of the power module. Zero potential of the supply voltage is connected to terminal 24 of the power module and is connected to terminal 12 of the fault signaling module, and in the event of a break-out contact of the measured physical quantity being connected via terminal 1 to terminal 1. Terminal 32 of the power module is connected to ground.

Claims (1)

Subject Wiring of the measuring point fault signal circuit, characterized in that the input terminal (1) from the external expansion element is directly connected to the base of the input transistor (Tlj), the input terminal (2) from the external switching element is connected to the base of the input transistor (Tlj resistor (R1), positive voltage supply terminal (3j connected to input transistor (TI) collector, input transistor emitter (Tlj connected to first control terminal (4), time constant τ (R2), first resistor resistance) divider (R3j and if the second thyristor (Ty2) is part of the circuit, then with its anode, the time constant resistance τ (R2j is connected to the positive pole of time constant capacitors τ (Cl) and the emitter of the second transistor (T2) or the constant τ (R2j as an external off-circuit element connected between the first control terminal (4) and the second control terminal (13) connected to the emitter of the second transistor (T2), as well as j as a capacitance of time constant τ (Cl) between the second control terminal (13) and the neutral potential terminal of the supply voltage (12), the base of the second transistor (T2) is connected to the collector of the third transistor (T3) and the second resistor divider (R4j, the collector of the second transistor (T2) is connected to the base of the third transistor (T3J, the emitter of the third transistor (T3) is connected to the discharge resistor (R5) and through the protective resistor (R6) in the forward direction with the control electrode of the first thyristor (Tyl) or, if the thyristor is an external circuit component, with a third control terminal (14), the terminal (5) of the external expander is connected to the anode of the first thyristor (Tyl); the cathode of the first thyristor (Tyl), or the fourth control terminal (15) if the thyristor is an external component of the circuit, is connected via a protective resistor (R7J, a protective diode (D2j in the second thyristor (Ty2) or, if the second thyristor (Ty2) is an external component of the circuit with the fifth control terminal (16), further through the forward diode (D3) to the terminal of the auxiliary devices (6), through the protective resistor (R8) and the isolating diode (D4) in the forward direction to the continuous acoustic signal terminal (7), through the working resistor (R9) and the isolating diode (D5) in the forward direction with the base of the transistor (T4) the switching transistor (T5) and also the collector of the sixth transistor (T6), the cathode of the second thyristor u (Ty2), or the sixth control terminal (17) if the thyristor is an external circuit the output transistor (T4), which base is connected to the collector of the seventh transistor (T7) and via the reverse diode (D6) and the protective resistor (R11) to the test terminal signal The pulse voltage input terminal (9) is connected via a protective resistor (R12) based on a switching transistor (T5), the emitter of this transistor is connected via protective resistors (R13, R14) to the bases of the sixth and seventh transistors (T7). , T6), the emitter of the sixth transistor (T6) is connected through the protective resistor (R15) and the diode (D7) in the forward direction with the output terminal of the intermittent acoustic signaling (10), the collector of the output transistor (T4) is connected with the output terminal of the optical signaling (11), while the emitter of the sixth transistor (T6) through the emitter resistor (R16), the emitter of the seventh transistor (T7), the emitter of the transistor (T4), the first cathode resistor (R17) and the second cathode resistor (R18) , on the one hand, the resistance of the resistive divider (R4), on the other hand the discharge resistor (R5) and, on the other hand, the negative pole of the capacitor of time constant τ (Cl) are connected to the terminal (12).