DE3128077C2 - Procedure for phase control - Google Patents

Abstract

The invention relates to a method for phase control and includes in particular an improvement of the circuit known from DE PS 2629831. In addition to the known circuit, a third current source is provided in the method according to the invention, which then charges the capacitor when it is determined via a current detection circuit that the switching path is not carrying any current due to a fault. The third power source charges the capacitor to a reference voltage specified internally in the circuit and, when the reference voltage is reached, triggers a post-ignition pulse, which ensures that the switching path is switched through before the next zero crossing of the mains voltage occurs.

Description

Raise the reference voltage as long as the triac is ignited. This will add unwanted gaps of the load current, especially with inductive loads.

An integrated additional element is designated with O , with the aid of which the circuit can be intervened via the OR gates G 2 and G 3 and the operating voltage of the circuit is monitored.

The block diagram of FIG. 1 differs from that of DE-PS 26 29 831 only by the addition of the gate G 4. With the gate G 4, the output signal at the output (? Of the ÄS-FIip-flop F2 is inverted and sent to the constant current source K 1 what is achieved is that after an ignition pulse, the current source K 1 remains switched off until the mains voltage has its next zero crossing.

When using phase angle control circuits malfunctions can now occur due to, for example, the The switching path controlled by the triac or thyristor remains de-energized or suddenly de-energizes. This is the case, for example, when operating universal motors with collectors when pantograph brushes take off and thereby the current through the triac is interrupted. The triac is then at the known control circuit only again with the next ignition pulse after a zero crossing of the mains voltage switched through. This leads to an irregular running of the engine, which should be avoided as far as possible target. The invention is therefore based on the object of eliminating the power cut-offs caused by disturbances to be eliminated by the control system before the next zero crossing of the mains voltage. This task is according to the invention in a method for phase control of the type described at the beginning solved by the characterizing features of claim 1.

In the method according to the invention, it is always checked whether the controlled switching path is due to the Phase angle control circuit has predetermined operation or whether due to external influences or disturbances a power interruption has occurred within the circuit. If there is a power failure causes a post-ignition logic, which can also be referred to as retrigger logic, the re-connection the switching section before the next zero crossing of the mains voltage.

Advantageous refinements of the invention are specified in the subclaims.

The invention is explained below using an exemplary embodiment explained in more detail:

A half-wave of the mains voltage U is shown in F i 5. 2a. FIG. 2b shows the zero crossing pulses derived from the zero crossing points of the mains voltage, which are emitted by the zero crossing detector U ₀ according to FIG. Such a zero crossing detector is known from DE-OS 25 53 764, for example

The third current source and the control logic for this current source are shown in FIG. In this case, an output signal is derived from the phase control circuit according to FIG. 1 - denoted by Ph in FIG. 3 - at the output of the current detection circuit I _0. This output connection is labeled P. The current detection circuit I ₀ is constructed in the same way as a zero crossing detector. As long as the current through the triac P? flows, so it is switched on. only the small forward voltage drops across the triac. In this case, the current detection detector / ₀ emits a logic “1” at its output, which in the case of a phase control circuit according to FIG. 1 is synonymous with reference potential. If, on the other hand, no current flows through the triac, the mains voltage drops at the triac TR , so that the output of the current detection circuit / “has a logic“ 0 ”, which corresponds, for example, to the DC voltage potential - Us

If there is no current via triac 77? is thus ίο at the connection P according to F i g. 3 an “O” signal, which is converted into a “1” at the inverter circuit G 5, which is applied to one input of the AND gate G6. ? -Flip-flop F2 the switch

is Sl holds, so that the internal reference voltage Ur is applied to the thyristor Γ

If a logical "1" is present at both inputs of the AND gate G 6, which means that the Current flow over the control line is equivalent

is, the output of the AND gate G 6 is set to reference potential and the third current «yelle is switched on.

This third power source is shown in FIG. 3 from a transistor Ti, which when the AND-

Gate G 6 is supplied at the base via the diode path D1, D 2 with a reference voltage through which the transistor Tl is controlled. The transistor Tl has a variable emitter resistor R 1 and a fixed collector resistor R 2 . The collector resistor R 2 is connected to the capacitor C so that it can be charged via the transistor T1.

According to FIG. 2c switches the logic according to FIG. 3 the third current source at the time X to the capacitor C , if it has been determined via the logic that a current is not flowing through the triac TA in the required manner. The voltage on the capacitor C then rises in a ramp shape until the reference voltage value Ur is reached and the ignition process is triggered in the manner already described. The steepness of the voltage rise and thus the pulse repetition time for the post-ignition pulses is set with the variable resistor R 1. The resistor R 2 in the collector of the transistor Tl determines the smallest possible pulse repetition time when the resistor R 1 has the value zero.

In the illustration in FIG. 2c it is assumed that even after the first post-ignition pulse, the logic continues to determine that the triac TR is still de-energized due to a fault. Then the third power source is shown in FIG. 3 after the first re-ignition pulse is again connected to the capacitor C and this is charged again with the set pulse sequence time until the reference voltage Ur is reached , so that a second re-ignition pulse is triggered. Then in the representation in Fig. 2c under

represents that the triac TR properly conducts power again, so that the third power source is switched off and at the next zero crossing of the mains voltage according to FIG. 2b normal operation of the phase control circuit is continued again. In the

bo Fig. 2d, the ignition pulses are shown, the two Middle ignition pulses are post-ignition pulses caused by a faulty power failure between two Zero crossings of the mains voltage have been triggered.

For this purpose i sheet of drawings

Claims (1)

1 2 180 ° phase angle for the tri-claims upstream of the load: continuously changing acs or thyristors. It works with the well-known approaching procedure 1. Method for phase control, in order to keep the circuit complexity for the monolithic in that the time of the ignition pulse delivery thereby 5 integrated circuit low, which is essentially determined that the network-synchronous Rampenspan- chen was achieved that on a condensation on one via a first constant current source tor two different steep ramp voltages fed capacitor a variable, predeterminable, were generated. The steepness of the first ramp span at a comparator threshold voltage determines the time after the NuIldur ^ jigang voltage reached, in which the duration of the ignition 10 of the alternating voltage also elapses until an ignition pulse is triggered by the connection of a second contact constant current source was generated on the capacitor and its same capacitor, determined the Charging to a fixed reference span duration of the ignition pulse itself voltage is determined and in which a Stromer- In DE-PS 26 29 831 is a block diagram of a detection circuit is checked whether the controlled 15 monolithically integrated phase control Switching path conducts current, identified by this, essentially described in the block diagram shows that if there is an interruption in the FIG. 1 is shown p current flow across the switching path between a i | The ignition pulse that triggers the current flow and the output amplifier A is preceded by ignition pulses M. subsequent zero crossing of the mains voltage ei- 20 a triac TR, through which a load Z in a load circuit Ü ne third power source (T ,, Ri, Ri, Di, D ₂ ) is switched on under the desired phase control. 1 capacitor (C) is switched on and this is switched on until the power is supplied to the integrated circuit i reference voltage (Ur) and thus to trigger a through the integrated element V, which is a common smoothing P post-ignition pulse is charged. capacity Cc is assigned The circuit is with si 2. The method according to claim 1, characterized in that a capacitor C is connected pj shows that as long as post-ignition pulses are triggered. First, the phase position of the ignition point in | j until the switching path leads again to the known form of the comparison between a | j 3. The method as claimed in claim 1 or 2, characterized in that the ramp voltage is synchronized with the grid and a predetermined P indicates that the charging time of the capacitor determines the nominal value. The capacitor C is there- jf (C) via the third current source (T \. R ,, Ri, D ,, D2) up to 30 to the zero crossing of the mains voltage via a ] | to the reference voltage (Ur) and thus the pulse-sequence zero-voltage detector U ₀ . an OR gate G 2 and a jl ge-time of the post-ignition pulses changeable is NEN switch S 2 discharged. After the zero crossing j | 4. Circuit arrangement na '' .1 one of the claim impulses, the capacitor C is made of a con- ■ | before 1 to 3, characterized in that an AND stant current source Ki is charged. A control voltage f _i Gate (G ₆ ) is provided, dt-, en an input 35 U _s r determines the threshold value that is determined by the S of the inverted output signal of the Stromerk- charging of the capacitor C generated ramp- ίΙ voltage circuit (Tb) is supplied, while the voltage must be reached in order to reach the ignition point j | A signal is present at the other input when the set. Reaches that delivered by capacitor C. ^: 2 Capacitor voltage at the comparator (T) with the ramp voltage the specified threshold value, trigger :.; Reference voltage (Ur) is compared. 40 det a function of the comparator ;, taking over $ 5. Circuit arrangement according to claim 4, da- thyristor 7 "and in turn sets a subsequent memory ■ "characterized in that the third current source cher flip-flop Fl. The (^ output of the memory flip- ■■ - a transistor (T \) , the base of the flops Fl releases the output amplifier A once. .- ;. Output of the AND gate (Gb) is activated, switches on in addition to the constant current source K 1 \ i its collector through a resistor (Ri) with 45 second Konstantstromquellc K 2 on the capacitor the capacitor (C) and its emitter via a C and connects a switch S 1 to an internally specified voltage potential (- Us) via an RS flip-flop F2 and an or gate variable resistor (R \) with the deich- ter G 1 is, where reference voltage Ur um. between the base and the DC voltage potential The capacitor C is :: (- Us) at least one diode (Dr, Di) provided 57 sources K 1 and K 2 are charged up to its voltage (Uc) is. the reference voltage Ur is reached. The duration of this Charging corresponds to the pulse width (tp) of the ignition ; ,, pulses. If the capacitor voltage reaches the value Ur, '· the thyristor Γ ignites again and sets the memory 55 flip-flop Fl back to its original state. The invention relates to a method for the phase cut, the ignition pulse is terminated and the constant current section control switched off according to the preamble of source K 2 The /? 5-flip-flop F2 holds the award 1. Switches S 1 but still so that the Thyristor T Such a method is known from DE-PS 26 29 831, the internal reference voltage Ur remains. In the patent specification mentioned, a method is described t> o In the next following zero crossing of the mains voltage ^: ren for phase angle control, at which point the zero crossing detector Uo sets the KS'Flip · Monolithically integrated semiconductor components use flop F2 back, discharges the capacitor C again. Such phase control via the OR gate G 2 and the switch S 2 and are used in particular to control triacs and also provide the basic state of the storage thyristors. b5 flip-flops F1 via the OR gate G 3 safely. With the help of the phase control, the current detector / 0 asks about the triac voltage Power consumption of a load on the alternating current network a resistor Λ, and locks the pulse generation by shifting the Zi'indimpulse / wipe 0 "and through the gate G 1 and the switch 51 through