DE1130500B - Control circuit with multivibrator - Google Patents

Description

GERMAN

PATENT OFFICE

kl. 21c 46/31

INTERNATIONAL KL.

G05f; g

N15051 VIUb / 21 c

REGISTRATION DAY:

NOTICE THE REGISTRATION ANDOUTPUTE EDITORIAL.

May 6, 1958

May 0, 1962

The invention relates to a control circuit with a multivibrator, which consists of two connected in a multivibrator circuit Transistors and one connected to the collector electrode of one of these transistors Switching transistor exists.

It is known that multivibrators can be used to generate voltage or current pulse sequences be used. By suitable choice of the components of the multivibrator, both the Pulse duration as well as the pulse frequency can be set. A circuit arrangement is already known in which a multivibrator equipped with tubes is used to control a flashing lamp will. It is also part of the state of the art to use transistors as electronic switches in multivibrator circuits, to be used in control and regulating devices etc. For example, with the help of a switching transistor, very small current pulses a large current can be switched, which in turn triggers a relay or counter can be.

The invention is now based on the object of a control circuit consisting of two in a multivibrator circuit switched transistors and one connected to the collector electrode of a transistor Switching transistor exists to be designed in such a way that the generation of pulses is interrupted, if a certain physical parameter, for example temperature or light intensity, a exceeds a certain threshold.

This object is achieved according to the invention in that between the base electrodes of the two Transistors of the multivibrator a control probe is switched, which depends on a physical parameters generates an EMF, which above a given threshold value the transistors biases the multivibrator circuit into a stable state. The control probe can, for example be a photo element or thermocouple.

A control circuit equipped with a photo element according to the present invention can be advantageous can be used to control a battery-powered flasher system that switches off after daybreak and should be switched on at nightfall. By using the invention Circuit arrangement, the energy consumption of a flasher system can be reduced, which is particularly advantageous when on remote Buoys installed flashing systems. It also increases the reliability of the flasher increased, since the system continues to flash even if the photo element fails.

Control circuit with multivibrator

Applicant:

National Research Council,
Ottawa (Canada)

Representative: Dipl.-Ing. M. Licht, patent attorney,
Munich 2, Sendlinger Str. 55

Claimed priority:

V. St. v. America May 6, 1957 (No. 657 365)
and Canada of August 28, 1957 (No. 735 462)

Henry Lyall Ross Smyth, Ottawa (Canada),
has been named as the inventor

The invention will now be described in more detail with a flasher system with reference to the drawings, in which shows

1 shows a circuit diagram of a flashing lamp circuit constructed using the control circuit according to the invention,

2, 3 a and 3 b are graphic representations for explaining the mode of operation of the one shown in FIG Circuit,

4 is a circuit diagram of another embodiment of a flashing lamp circuit,

5 and 6 circuit diagrams of further embodiments of the control circuit according to the invention.

The multivibrator in the circuit arrangement according to FIG. 1 is equipped with two pnp transistors TR 1 and TR 2 . A switching transistor TR3 is controlled with the output signal of the multivibrator occurring at the collector electrode of the transistor TR 2. If the transistor TR 2 is in the blocking state, the switching transistor TR3 conducts. The coil of a relay M, which is used to switch a lamp 12 on and off, is located in the collector circuit of the switching transistor TR3. If the transistor TR 3 is in the on state, the relay coil is excited by the current passing through it and the contact 10, which is normally adjacent to the contact 11, is withdrawn, whereby the lamp circuit is interrupted.

According to the invention, a daylight, but not the light originating from the lamp 12, is now

209- 607/273

I 130 500

set photo element 30 is connected with its negative terminal to the base of the transistor TR 1 and with its positive terminal to the base of the transistor TR2 . As long as the intensity of the light falling on the photo element 30 is below a predetermined level, the photo element does not provide an output signal and therefore does not influence the bias voltage of one of the two base electrodes. Resistance R 14 shown in series with element 30 may be the inherent resistance of the element; however, it can also be an additionally introduced resistor which increases the dark resistance of the multivibrator. In daylight or as long as the light falling on the element has a strength of, for example, over 100 lux, the base electrode of the transistor TR 1 is biased in the forward direction and the base electrode of the transistor TR 2 in the reverse direction, so that the switching transistor Ti? 3 is in the on state and the lamp 12 is de-energized, since the winding of the relay M is energized and the two contacts 10 and 11 are separated from one another.

If the intensity of the daylight falls below a predetermined level, the output voltage drops of the element 30 below the threshold control value of the multivibrator, and the tilting process of the multivibrator starts again. A cell voltage of is sufficient to shut down the multivibrator less than 100 millivolts.

The operation of the control circuit according to the invention can best be imagined if one assumes that the circuit is suddenly put into operation by the application of voltages. The operating voltages for the control circuit can be taken from a battery, for example, between the positive terminal 13 and negative terminal 14 of which the flashing lamp 12 is located. The resistor R 1 in the collector circuit of the transistor TR 1 has essentially the same value as the resistor R6 in the collector circuit of the transistor TR2. The capacitance of the capacitor C1 is several times greater than that of the capacitor C2. When the voltages are applied, a base current therefore flows in each transistor for the first time. The current flow through R2 and Cl takes over the control, while the base current of the transistor TR 2 decays quickly and stops completely until the capacitor Cl is charged to a certain fraction of the battery voltage. At this time, the base current of the transistor TR 1 drops to a lower value. The capacitor C 2 now begins to charge, and as a result of the increase in potential at the collector-side end of the resistor R 1, the base current flowing through this resistor drops very quickly to zero. At this stage, the transistor TR1 is in the blocking state and the transistor TR 2 is in the on state. The potential at the collector end of the resistor R 6 is therefore essentially equal to the positive battery potential, and the transistor TR 3 is switched to the blocking state. As a result, the winding of the relay M is de-energized and the lamp 12 is switched on. Since the capacitor C 2 is smaller, the transistor TR 2 is not as long in the on state as the transistor TR 1. The off state of the transistor TR3 does not last as long as its on state. When the transistor TR 3 is on, the lamp 12 is de-energized. The previously charged capacitor C1 discharges through the resistor chain R 1, R 3 and R 6, while C 2 charges. The charging current of the capacitor C 2 has the same direction as the discharging current of the capacitor Cl through the resistor A1. Therefore, if the potential on each capacitor is the same, the further discharge will turn TR2 into the blocking state, and C1 will begin to charge.

ίο The multivibrator continues to work in the manner described, the transistor TR 1 being in the on state for the longest. The duration of the light flash generated by the lamp 12 can be changed by setting Cl and R3 , while the duration of the currentless state is a function of the values C 2 and R 4 . In series with the resistor R 4 is a somewhat smaller variable resistor R 8, with which the duration of the currentless state of the lamp 12 can be set. The resistors R 2 and RS have a relatively low value and protect the transistors from the voltage surges that occur when the circuit is flipped. The resistor R 7, which has a lower resistance value than the resistor R 2 or R 5 , is used to protect the transistor CR 3. The dead time of the lamp 12 can be increased significantly by increasing the resistance value of Rl . Extreme changes in temperature can be compensated for by using low collector and bias resistances and directing the bias resistors R3, R4, R8 back to the corresponding collector electrode rather than to the busbar. In this way it is possible to keep the pulse sequence and the pulse duration constant over a temperature range of -40 to + 40 ° C and to ensure adequate operation even beyond these limits.
The resistance and the operating current characteristics of the relay M are chosen so that a power of a few milliwatts is sufficient to keep the contacts 10 and 11 closed, and that a current difference of the order of fractions of a milliamp is sufficient to separate the contacts.

FIG. 2 shows in the diagram the relationship between the total resistance offered by the resistors R 4 and R 8 and the number of lightning flashes per minute produced by the circle. The solid line 15 extends over an area in which the setting of the lightning speed is preferably done by resistance control at all outside temperatures that are normally likely to occur. The dashed line 16 extends over that part of the area in which the cooling operation tends to become unstable at large values of the required resistance; therefore it is preferred to achieve the low velocities by changing the size of Cl zn. With these slower flashes the sum of A4 and R8 is kept relatively low and Cl can be increased quite considerably.

In Fig. 3 a and 3 b, the voltage curve is shown as a function of time at the collectors of TR 2 and TR1 . From the blocking state, the potential rises steeply at 19 to approximately the full positive value and remains steadily at 18. Above a certain level indicated at 21, the relay current falls through TR 3 to the contacts 10

Claims (8)

5 6 and 11 to close, causing the battery to consume energy at a rate that the Igniting the lamp is connected. As soon as C2 overcharged in any long period of operation begins to discharge, the collector of Ti falls? 2 prevents, and is not so deep that the cell quickly to the negative feed value and remains damaged. steadily, as indicated by part 17. The 5 While the embodiment of FIG slowly rising potential curve 22 of the collector inclusion of a stage TR 4 has been described, tors from TRl is based on the limited charging time, the output stage can with its base electrodes of Cl via its ohmic series charging circuit by connecting the lower end of and ends at 23 when TR2 starts and C2 is 2? 12 at the collector of the switching transistor Ti? 3 begins to charge. The collector potential of TR 1 io can be coupled, the switching mode im falls steeply from the full positive value along the essential runs as outlined above, particularly Curve 24 and ends at a lower positive where TR 3 with a relatively high collector current tive level at 25 when TRl becomes conductive again. is chosen that has adequate control of the In the embodiment according to FIG. 4, there are no base currents of a group of larger final stage movable contacts. The contacts 10 allowed 15 transistors. and 11 are replaced by a further transistor switching stage. In FIGS. 5 and 6, further embodiment TR 4 have been replaced. This controls the basic currents of the forms shown. In Fig. 5, a pair of elements are parallel transistors 77-5, TR6 ... TRn. 30 with approximately similar characteristics of the off-In this embodiment, the base of the transistor output voltage is connected to the collector of the switching transistor TR3 and TR2 , depending on the incident TR 4 by means of a low-resistance resistor R 9 20 light parallel to the base biasing resistors the negative pole couples, the load of which is R 10. When TR3 of the element connected in parallel with Rl turns to the blocking, TR 4 draws base current through R 9 base of TR 1 and the positive pole of the element with RS and i? 10, and the potential of the emitter end of the element connected in parallel to the base from TR 2 RU is connected by the current flow in TR 4 via RU 25. Depending on the er and R 12 held negative. Current flows through the desired light threshold value, at which one wishes to shut down the multi-small resistor R 12 from the base electrode vibrator, can a single one of the parallel-connected group Ti? S, TR 6 ... TR η element connected to R 5 as described weraus. Since these transistors are strongly biased to keep TR2 blocked under daylight, they establish the closed circuit state for 3 °. In FIG. 6, a single element is shown, the two circles of the lamp filament 12, so that these can see the ends of the base resistors R 2 and R 5 lights up. If TR 4 is at the start of TR 1 and and its negative pole is biased to the base of TR 1 TR3 , the potential that is connected increases. With a commercially available type of base electrode of the group TR 5, TR6 .. .TRn , the voltage-generating selenium element was charged and the base current falls to a low value, 35 observes that the dark resistance was high and so that the flashing circuit is switched off. in full sunlight was relatively low, so that the base current in the final stage of the embodiment- the element has no effect on the timing circuit form according to FIG Steady state can be brought under illumination by using the inter- 40 on the order of 120 lux at each of the switched bias cells 26 with the auxiliary circuits illustrated, state 13. Improved battery life results It is immaterial whether the nature of the lighting is up is from the interposition of such auxiliary light or heat radiation, provided that biasing means with transistors of such character- the responsive element is able to withstand voltage in comparison with a circuit which does not produce 45 which contains biasing means in any relation to the intensity . In the blinking state, when the incident radiation is stopped. For example, current through the base electrodes of the vector group could also be used a thermocouple. TR S, TR 6 ... TR η is pulled, the pre-loading In general, any probe, which is dependent on voltage battery, which preferably generates a voltage from an ambient parameter, an EMF, generating device with low energy 50 in similar Ways to use a pre-absorption capacity is to rely on its full bias voltage effect on the base electrodes of the tranpotential. During the switch-off time, the base current in a multivibrator time control is lowered very considerably below the value practiced. which it would have without the biasing cell 26, and of course the control circuit according to the invention can thanks to the counter voltage, with the result that 55 can also be used to control other payload circuits that a saving in base electricity is achieved. Which are turned. The invention is therefore not based The preload cell is advantageously limited to flashing systems with transistors, uses that are not inherently low enough Have currents in the bias stage where the PATENT CLAIMS: Base is on emitter potential. 60 1st control circuit with multivibrator, consisting of As a further result, the switching transistor group is better approximated to two Trander complete shut-offs connected in multivibrator circuit than sistors and one with the collector electrode in the absence of the cell. As a result, a residual switching current connected to one of these transistors, which would strive to become transistor in the lamp filament circle, is characterized in that between flow and usually a multiple of the base electrodes of the two transistors (TR 1 the residual base current grows) and TR 2) a control probe (30) is connected, which prevents. The shunt resistor R 13 is selected with a value depending on a physical such that it generates the accumulated parameters an EMF, which above thereby (30) a thereby (30) em through this a given threshold value the transistors of the multivibrator circuit in a stable state pretensioned. 2. control circuit according to claim 1,
marked that the control probe
Photo element is. 3. control circuit according to claim 1,
marked that the control probe
Thermocouple is. 4. control circuit according to claim 1,
characterized in that the collector electrode of each multivibrator transistor (TR 1 or TRl) is connected to the base electrode via a resistor (R 3 or R 4 and R 8). 5. Control circuit according to one of the preceding claims, characterized in that the Load resistance of the switching transistor (Ti? 3) from the winding (M) of a lamp circuit (13, 12, 10, 11, 14) controlling relay is formed. 6. Control circuit according to any one of claims 1 to 4, characterized in that the collector electrode of the switching transistor (Ti? 3) via a resistor (R 12) to the Basiselek- troden of a parallel transistor group (TRS ... TRn) is connected, which forms the contactless switch of a lamp circuit (13, 12, 14) 7. Control circuit according to claim 6, characterized in that a further transistor (TR 4) is connected between the switching transistor (TR 3) and the transistor group (TR 5 ... TRn) , the base electrode of which is connected to the via a resistor (R 9) The collector electrode of the switching transistor (TR3) and its emitter electrode are connected to the base electrodes of the transistor group (TR 5 ... TR n) via a resistor (i? 12). 8. Control circuit according to claim 7, characterized in that between the resistor (RVZ) and the base electrodes of the transistor group (TR 5... TRn) a biasing element (26) with a parallel resistor (R 13) is switched on. Considered publications: "Electronics", 1954, No. 5, pp. 35 to 38;
"Valvo Reports", 1956, no. 1, pp. 16 to 26. 1 sheet of drawings