SE462125B - ELECTRONIC SECURITY TEMPERATURE LIMITER - Google Patents

Description

The dynamic signal is used in the invention, i.e. a variable, continuous signal from the oscillator, as a setpoint for the controller to achieve that the levels in normal operation change within the control circuit, while in the event of a malfunction they remain constant, whereby faults can be detected in a technically simple manner and can be used to disconnect the monitor. the unit.

An embodiment of the invention is shown in the drawing and is described in more detail below.

In the drawing, Fig. 1 shows a block diagram of an electronic safety temperature limiter, Fig. 2 a wiring diagram of a threshold switch, Fig. 3 a wiring diagram of a capacitor recharge circuit, and Fig. 4 a wiring diagram of a monostable flip-flop.

The same reference numerals refer to the same parts in all the figures in the drawing.

The i_fig. The electronic safety temperature limiter shown in Fig. 1 consists of an oscillator 1, two impedance converters 2, which are optional and thus shown in dashed lines in Figure 1, a setpoint sensor 3, an actual value sensor 4, a threshold value switch 5, a capacitor recharging switch 6, connected trigger connection 7, a reset key 7 'and two relays 8 and 9. Components 1 to 6 then form a controller. The reset key 7 'includes two switches 7'a and 7'b. The first relay 8 is a working relay and comprises a relay coil 8a and a closing contact 8b. The second relay 9 is a bistable locking relay and comprises a relay coil 9a and an opening contact 9b. Below is the assumption that soil is the reference potential for these devices. Furthermore, a further control device 10 and an energy supply source (not shown) are provided. The latter is, for example, the burner in a heating system.

The output of the oscillator 1 is connected via the optional first impedance converter 2 to the input of the setpoint sensor 3, the output of which in turn is led to a first input of the threshold switch 5. The output of the setpoint sensor 4 is connected to a second input of the threshold switch 5, side of the optional second impedance converter 2 is led to the parallel-connected inputs of the capacitor recharging coupling 6 and the trigger coupling 7.

The setpoint sensor 3 is a voltage divider, which for example consists of two resistors R1 and R2 connected in series, one pole of the series connection R1; R2 being grounded. The setpoint sensor 4 is also a voltage divider, which contains a temperature sensor 11, which is connected in series with a series connection, which for example consists at least of a resistor R3 and a diode D1. The voltage divider D17R3; l1 of the setpoint sensor 4 is supplied by a direct voltage VCC, the reference pole of which is on earth, a 462 125 pole of the temperature sensor 11 lying on ground and its other pole connected to the series connection R3: D1 forms the output of the setpoint sensor 4. The two impedance converters 2 are generally identically constructed. One pole of the relay coil 8a is connected to the output of the capacitor recharging circuit 6, while its second pole is grounded, the output of the trigger circuit 7 is connected via the opening contact of the first switch 7'a to a first pole of the relay coil 9a, and the supply voltage VCC is across the second the opening contact of the switch 7'b connected to the second pole of the relay coil 9a. Assuming that the second relay 9 is a residual relay, the closing contact of the first switch 7'a connects the DC voltage VCC with the first pole of the relay coil 9a and the closing contact of the second switch 7'b to the second pole of the relay coil 9a. An additional supply voltage V "CC, for example an alternating voltage of 220 volts, supplies the control device 10 via the contacts 8b and 9b of the two relays 8 and 9 connected in series.

The output signal of the oscillator 1 can have an arbitrary characteristic shape. In a preferred embodiment, it is rectangular. In this case, the oscillator 1 is an unstable flip-flop and may, for example, be constructed as described in Linear Databook, pages 5 - 47, National Semiconductor Corporation. The two impedance transducers 2, which are connected to the oscillator 1 and the threshold value switch 5, respectively, consist of, for example, amplifiers constructed by means of an operational amplifier, each having an amplification factor of one.

The threshold switch ES contains a preferred embodiment a comparator and is then constructed in accordance with Figure 2. The trigger coupling 7 is, for example, a monostable flip-flop, the wiring diagram of which is shown in Figure 4.

The threshold switch 5 shown in Figure 2 contains a comparator 12, which is supplied by the direct voltage VCC and whose output via a resistor R4 is also supplied with the direct voltage VCC.

The first input of the threshold switch 5 is connected via a resistor R5 to the non-inverting input of the comparator 12, and its second input is connected via a resistor R6 to the inverting input of the comparator 12, the output of the comparator simultaneously being the output of the threshold switch 5.

The inverting input of the comparator 12 also lies on earth via a capacitor C1.

The capacitor recharging circuit 6 shown in Figure 3 consists of two capacitors C2 and C3, three transistors T1 to T3, three diodes D2 to D4 and three resistors R7 to R9. The two transistors T1 and T2 are, for example, NPN transistors and the transistor T3 is, for example, a PNP transistor. The two transistors T2 and T3 are connected in reception and are controlled by a preamplifier T1; R7, which consists of the transistor T1 and the resistor R7. In other words: the collector of the transistor T1 is fed directly to the base of the transistor T2 and the base of the transistor T3, and the emitters of the two transistors T2 and T3 are connected to each other. An additional DC voltage V "Cc., Whose reference coil is grounded, supplies the collector of the resistor R8 to the collector of the transistor T1 and the collector of the transistor T2 to the resistor R9, while the emitter of the transistor T1 and the collector of the transistor T3 are both grounded. the resistor R7 is connected to the base of the transistor T1, and its output is formed by a pole, namely the anode, of the first diode D2, which in addition, via a parallel connection C3, D4, which consists of the capacitor C3 and the diode D4, lies on earth. , namely the cathode, of the first diode D2 is connected via the capacitor C2 to the emitters of the transistors T2 and T3, dance to the output of the receiving circuit T2: T3, and to the second diode D3 connected to ground, the cathode of the diode D2 being connected to the diode D3 The monostable flip-flop shown in Figure 4 consists of an operational amplifier 13, which is supplied by the direct voltage VCC, an NPN transistor T4, a PNP transistor T5, a diode D5, a co condenser C4 and seven resistors R10 to R15. The input of the monostable flip-flop is connected via the resistor R10 to the base of the transistor T4 and its output via the resistor R16 is connected to the emitter of the transistor T5. The resistor R1z and the capacitor C4 form a first voltage divider, which constitutes an RC link, a pole of the 462 125 capacitor C4 lying on earth. The resistors R13 and R14 form a second voltage divider, one pole of the resistor R14 lying on the ground. Both voltage parts R12; C4 and R13; R14 are supplied by the direct voltage VCC. The common pole of the resistor R12 and the capacitor C4 is connected via the resistor R1 to the collector of the transistor T4 and connected directly to the inverting input of the operational amplifier 13 and connected to the output of the operational amplifier 13 via a diode-resistor series connection D5; The diode-resistor series connection D5: R15 consists of the resistor R15 and the diode D5, the cathode of the diode D5 lying on the output side of the operational amplifier 13. This output is also applied to the base of the transistor T5. The common pole of the resistors RI3 and RI4 is connected to the non-inverting input of the operational amplifier 13. The emitter of the transistor T4 and the collector of the transistor T5 are grounded.

The resistors R10 and R11 and the transistor T4 form an input switch R10; T4: R11. The transistor T5 and the resistor R16 form an output switch T5; R16. The operational amplifier 13 is fed back via the diode-resistor series connection D5: R15.

The connection shown in Figure 1 contains a single, self-monitoring controller, which controls the two relays 8 and 9 and whose setpoint value constitutes the output signal of the oscillator 1. The working relay 8 is controlled by this controller via the capacitor recharging connection 6, and the bistable locking relay 9 is controlled by the same controller via the trigger connection 7.

Self-monitoring means that component faults that have an impact on the unsafe side are automatically identified. To realize this, a dynamic signal, dance, is used. a variable continuous signal at the output of the oscillator 1 as the setpoint for the controller. This ensures that the levels within the control circuit change during normal operation, while they remain constant in the event of a malfunction. Thereby the error can be identified.

With the aid of the temperature sensor 11, which is, for example, a Ni-1000 ohm sensor, the temperature of the liquid, for example the temperature of the boiler in a heating system, is measured. The sensor resistor 462 125 constitutes a component of the voltage divider D1: R3: 11 which forms the regulator's actual value sensor 4 (see figure 1) and which generates a voltage value UF corresponding to the liquid temperature at the output of the actual value sensor 4, UF being a direct voltage signal.

If the permissible limit temperature for the liquid is, for example, 10 ° C, for example, taking into account the tolerance values for the temperature sensor 11 and the electronics, the value of UF is chosen to be at most equal to 5.5 volts at 108 ° C and at least equal to a short-circuit value of 4. 24 volts at -10 ° C. The diode D1 in the actual value sensor 4 serves for temperature compensation and reduction of the effect of voltage fluctuations, so that the setpoint and actual value of the regulator with respect to this run in parallel and are exposed to equal changes. The oscillator 1 generates the dynamic signal which in the setpoint sensor 3 is voltage-divided by the voltage divider R1: R2. If the dynamic signal is rectangular, then, as already mentioned, the oscillator 1 is an unstable flip-flop and its rectangular output voltage US has a maximum value of, for example, 10.5 volts during the pulse duration, which is a limit value corresponding to the limit temperature of the liquid, and below the pulse interval the room has a minimum value of, for example, 8.1 volts, which corresponds to a short-circuit test setpoint. The extreme values of the rectangular voltage UR corresponding to these two values 10.5 volts and 8.1 volts, respectively, at the output of the setpoint sensor 3 are then, for example, 5.5 volts and 4.24 volts, respectively, and thus equal to the maximum and minimum values of the voltage UF at the output of the actual encoder 4. For self-monitoring reasons, dAns. for fault identification, the values of UF and UR are selected in such a way that they are always less than Vcc / 2. If Vcc is the supply voltage of the oscillator 1, the impedance converter 2 and the actual value sensor 4. VCC is, for example, equal to 12 volts.

Under normal operating conditions, the value of the controller's actual value is dance. the value of the voltage UF, between the maximum value 5.5 volts and the minimum value 4.24 volts for the rectangular setpoint, dance. the rectangular voltage UR. The output voltage UV of the threshold switch 5 is then also rectangular and 2 '462 125 has a maximum value which is of the same order of magnitude as the supply voltage value VCC of the threshold switch 5 and can for instance be equal to 10.5 volts, and a minimum value of 0 volts. The rectangular output voltage UV of the threshold switch 5 continuously recharges the capacitors C2 and C3 included in the capacitor recharging circuit 6 (see figure 3).

During the UV pulse gap of the rectangular voltage, the capacitor C2 is charged by the supply voltage V "CC, which for example amounts to 20 volts, via the resistor R9, the transistor T2 and the diode D3. The coil 8a of the working relay 8 then draws its energy from the capacitor C3. - the yellow voltage UV, the capacitor C2 is discharged via the transistor T3, the diode D2 and the capacitor C3, so that the latter is recharged, in which case the coil 8a draws its energy from the two capacitors C2 and C3, thus the operating relay 8 draws continuously and the supply voltage \ fCc (see figure 1) continuously feeds the control device 10 via the now closed closing contact 8b and the opening contact 9b. The locking relay 9 is not operated at all, since the capacitor C4 in the trigger connection 7 (see figure 4) during the pulse duration of the rectangular voltage UV is always discharged via the resistor R11 and the transistor T4 before its voltage reaches a value which brings the subsequent operation amplifier 13 to switch.

If the temperature of the liquid exceeds its limit temperature or if there is an interruption in the temperature sensor ll, the actual value voltage UF is always greater than the rectangular setpoint voltage UR, so that the output voltage of the threshold switch 5 is continuously equal to 0 volts. Thereafter, the capacitor C3 in the capacitor recharging circuit 6 (see figure 3) is no longer recharged by discharging the capacitor C2. The working relay 8 releases and closes with the aid of the now opened closing contact 8b of the control device 10 (see figure 1%. This interrupts the energy supply to the heating system's burner. At the same time the transistor T4 in the trigger connection 7 (see figure 4) is continuously blocked so that the capacitor C4 can no longer be discharged across the resistor R1 and the transistor T4- The capacitor C4 is charged by the supply voltage l 462 125 VCC across the resistor R1- If the capacitor voltage reaches it On the non-inverting input of the operational amplifier 13 adjacent through the voltage divider R137R14 if, the transistor T5 becomes conductive and thus the voltage VCC is applied to the relay coil 9a of the locking relay 9. This pulls and remains in the pulling position, since it is a residual relay.The opening contact 9b opens, so that the control device 10 is now separated by two open relay contacts 8b and 9b from the supply voltage V "CC. The locking relay 9 can e can only be reset by hand by means of the reset key 7 ', so that the control device 10 and thus also the device is not only switched off through the working relay 8 but also locked through the locking relay 9. If the reset key 7' is operated after switching the relay 9, the relay coil is passed 9a of current in the opposite direction and the relay 9 returns to its original position. Thanks to the diode-resistor series connection D5; R15, the operational amplifier 13 returns to its original state as soon as the transistor T4 becomes conductive again and the capacitor C4 is again sufficiently discharged, i.e. it acts in this case as a monostable rocker.

In the event of a short circuit in the temperature sensor 11, the actual value voltage UF drops to a value that is continuously lower than the rectangular setpoint voltage UR, so that the output voltage UV from the threshold switch 5 is continuously equal to the voltage 10.5 volts. The capacitor C2 in the capacitor-recharge connection 6 (see figure 3) is no longer charged, since the transistor T2 is constantly blocked and thus cannot charge the capacitor C3 through its discharge. The working relay 8 thus releases and closes the control device 10 with its now open closing contact 8b (see figure 1). In this case, however, no locking takes place, because, due to UV = 10.5 volts, the transistor T4 in the trigger connection 7 (see figure 4) is constantly conducting and its capacitor C4 is thus completely discharged.

Claims (10)

Yes. CN b.) -À h.) (Fl / 0 Electronic safety temperature limiter with a first relay (8), whose coil (8a) is controlled by a self-monitoring regulator (1; 2; 3 ,; 4; 5; 6), and with a second relay (9), whose coil (9a) is controlled by a trigger coupling (7), the controller (1; 2; 3; 4; 5; 6) containing an actual value sensor (4) containing a temperature sensor (11) and a setpoint sensor (3), the outputs of which are led to each an input of a threshold value switch (5), the output of which in turn is fed to the coil (8a) of the first relay (8), characterized in that the setpoint sensor (3) is supplied by an oscillator (1) with a dynamic signal, that the output of the threshold switch (5) is on the one hand via a capacitor recharging switch (6) to the coil (8a) of the first relay (8) and on the other hand to the input of the trigger switch (7), that both relays (8, 9) contacts (Bb, 9b) are connected in series for voltage supply of a control device (10) of an energy supply source, and that the second relay (9) is a bistable relay that can only be reset manually. Electronic safety temperature limiter according to claim 1, characterized in that the capacitor recharging circuit (6) contains two capacitors (C2, C3), of which the first capacitor (C2) in the presence of a rectangular voltage at the output of the threshold switch (5) is charged and discharged and the second capacitor (C3) is charged by discharging the first capacitor (C2). Electronic safety temperature limiter according to claim 2, characterized in that the capacitor recharging circuit (6) contains two transistors (TZ, 'I'3), which are connected in reception and controlled by a preamplifier (T1: R7), wherein the reception circuit (T1: R7) T2; T3) output via the first capacitor (C2) is connected to a pole of a first diode (D2), which via a second diode (DS) lies on earth, and whose second pole 462 125 over a parallel connection (C3; D4 ) of the second capacitor (C3) and an additional diode (D4) is on earth. Electronic safety temperature limiter according to one of Claims 1 to 3, characterized in that the bistable relay is a residual relay. Electronic safety temperature limiter according to one of Claims 1 to 4, characterized in that the trigger coupling (7) is a monostable rocker. Electronic safety temperature limiter according to claim 5, characterized in that the monostable flip-flop has an input switch (R10; T4; R11), two voltage dividers (R12; C4; and R13; R14), one of which is an RC link, one via a diode-resistor series connection (D5; R15) feedback operational amplifier (13) and an output switch (T5; RI6). Electronic safety temperature limiter according to one of Claims 1 to 6, characterized in that the threshold switch (5) contains a comparator (12). Electronic safety temperature limiter according to one of Claims 1 to 7, characterized in that the oscillator (1) is an unstable flip-flop. Electronic safety temperature limiter according to one of Claims 1 to 8, characterized in that each impedance converter (2) is connected to the oscillator (1) and / or the threshold value switch (5). Electronic safety temperature limiter according to claim 9, characterized in that each impedance converter (2) consists of an amplifier with a gain factor of 1.