CS209017B1 - Voltage barretter - Google Patents

Description

The subject of the invention is a voltage variator designed to obtain a control voltage controlling other circuits. Its task is to keep the control voltage rising or falling at a constant speed after the switch is closed for the duration of the switch closing.

The prior art acquisition of a control voltage, for example by a potentiometer operated manually, had the disadvantage that the rate of change of the control voltage was dependent on the speed of rotation of the actuator and furthermore, in order to achieve very small changes.

These disadvantages are overcome by the voltage variator according to the invention. It is based on the fact that the operational amplifier is connected by its inverted input to the transistor emitter and to the resistor whose second pole is connected to the neutral pole, the non-inverted input is connected via the positive pole of the supply voltage and through the neutral pole. the output of the operational amplifier is connected to the output terminal and at the same time it is connected by a capacitor to the control electrode of the transistor. On ; [the positive pole of the supply voltage is connected to one switch and the other pole is connected to the neutral pole, the opposite poles of both switches being connected ¹ and connected to the control electrode via a control resistor.

If at least two pairs of negative switches are used in series, the respective control resistors can be connected either in series or connected with one pole and connected to the control electrode and the second poles are connected to the middle poles of the respective dual switches.

It is also possible to connect the control electrode via at least one series of control resistors and switches to the positive pole of the supply voltage and via at least one series of control resistors and zero-pole switches. The control resistors in all variants may be variable as required.

As a result, these new, resp. Higher effects: The rate of change of the control voltage is only dependent on the capacitor and control resistance values and is therefore constant. Different (eg very low) speeds can be achieved by varying the values of said components. When the switches are opened, the control voltage remains constant with great time stability.

The accompanying drawing shows schematically an exemplary embodiment of the invention, including four variations thereof. Giant. 1 is a circuit diagram of a voltage | Fig. 2 is a partial circuit diagram with one pair of switches and one variable control resistor; 3 is partial

209017 _______________________ wiring diagram with two pairs of switches and two control resistors, connected one pole to the transistor control electrode, Fig. 4 is a partial wiring diagram with three pairs of switches and control resistors connected in series and Fig. 5 is a partial wiring diagram with one pair of control resistors and switches connected from the transistor control electrode to the positive terminal of the supply voltage and with one pair of control resistors and switches connected to the neutral.

The inverted input 1 of the operational amplifier 2 is connected to the emitter 3 of the transistor 4, whose emitter 3 is connected via a resistor 5 to the neutral pole 14. The non-inverted input 6 of the operational amplifier 2 is powered by a voltage divider formed by a resistor 7 connected to the positive terminal. and a resistor 8 connected to the neutral pole 14. The output 9 of the operational amplifier 2 is connected to the output terminal 10 and connected via a capacitor 11 to the control electrode 12 of the transistor 4. The control resistor 15 is connected between the switches 16 and 17 and the control electrode 12 of the transistor 4.

By selecting the values of resistors 7 and 8 appropriately, the voltage between points 12 and 14 is set equal to half the voltage between points 13 and 14. After switching the switch 16, current flows to the capacitor 11 and to the output 9 of the operational amplifier 2. It decreases at a constant speed for the duration of closing of switch 16. After opening of switch 16, the current stops flowing

Claims (6)

SUBJECT Voltage variator, characterized in that the operational amplifier (2) is connected by its inverted input (1) to the emitter (3) of the transistor (4) and to the resistor (5) whose second pole is connected to the zero pole (14), wherein the uninverted input (6) is connected via a resistor (7) to the positive pole of the supply voltage (13) and through another resistor (8) to the neutral pole (14), the output (9) of the operational amplifier (2) being connected to the output terminal (10) and at the same time it is connected by a capacitor (II) to the control electrode (12) of the transistor (4). Voltage variator according to claim 1, characterized in that a positive switch (16) is connected to the positive pole of the supply voltage (13) and another switch (17) is connected to the neutral pole (14), the opposite poles of the two switches being connected. and connected via a control resistor (15) to the control electrode (12) of the transistor (4). 3. The voltage variator according to claim 1, wherein at least two pairs are used 5 ex and the output 9 of the operational amplifier 2 remains at the same voltage as when the switch 16 was opened. Upon closing of switch 17, current from capacitor 11 and output 9 of operational amplifier 2 starts to flow through the control resistor 15. The voltage at output 9 increases: at a constant speed while switch 17 is closed. voltage at the same voltage as at the moment of opening of switch 17. The circuit according to FIG. 1 is intended for one constant I rate of change of the control voltage. The wiring shown in FIG. 2 allows setting a suitable rate of change of the control voltage. FIGS. 3 and 4 show two variations of the wiring allowing the rate of change of the control voltage to be scaled. The connections according to FIGS. 1 to 4 are applicable if (e.g. mechanically) the simultaneous switching of switches 16 and 17 is prevented, which would lead to a short circuit of the supply voltage. Where it is not possible to prevent the simultaneous switching of the switches 16 and 17, the circuit according to FIG. 5 is used. The voltage variator can be used in a wide range of technical fields, eg in communication technology for remote tuning of receivers, transmitters, antenna amplifiers, in heavy-current electrical engineering to control the power consumption of electrical appliances, to control the speed [electric motors, etc.]. BACKGROUND OF THE INVENTION In series switches (16 and 17), the control resistors (15) are connected to each other in series. Voltage variator according to Claims 1 and 2, characterized in that, using at least two pairs of series-connected switches (16 and 17), all control resistors (15) are connected with one pole to the control electrode (12) of the transistor (4) and to the other. the poles are connected to the middle pole of the respective pair of switches (16 and 17). Voltage variator according to claim 1, characterized in that the control electrode (12) is connected via at least one pair of control resistors (15) and switches (16) connected in series to the positive pole of the supply voltage (13) and via at least one series connected. a pair of control resistors (15) and switches (17) to the zero pole. Voltage variator according to Claims 1 to 5, characterized in that the control resistor (15) is variable. ___________, ------------- 1