CS267862B1 - Symmetrical stabilized source with dependent current-limiting fuses - Google Patents

Abstract

It is designed symmetrically stabilized source with current current regulation fuses in both power branches. The power supply consists of a screen transformer with two separate secondary ones windings, two-way rectifiers and filter capacitors. In parallel to the filter capacitors is included in each branch the same circumference on which input is a serial combination of the first resistance and a parallel combination of the first capacitor, first diode and serial connection potentiometer, second resistor. Common point the positive pole of the first capacitor, the anode the first diode and the potentiometer is over the third resistor connected to the inverting input op amp op positive and in the negative branch. Potentiometer Runner is associated with its non-inverting entry NIV. NIV OZ is a serial combination of the second and third capacitors, of which the common point is connected to the collector a transistor whose emitter is grounded and the base is grounded through the fourth resistor and over the fifth resistance - linked to Zener diode on the OZ output and the second diode at the output OZ.Kolektor is also connected with the base of the output circuit transistor MAA 723. IV OZ is grounded and OZ is connected to MAA 723 power supply. OZ has input positive supply voltage connected to a doubler connected to this rectifier branches. IV OZ is involved in the fourth resistance positive branches. The source is also a comparator, voltage hinge and smoothing capacitors on its input.

Description

The invention relates to a symmetrical stabilized source with dependent current fuses with simultaneous regulation of the current fuse in both supply branches.

The stabilized adjustable power supplies with current fuse produced so far allow to create a symmetrical power supply by combining two of these adjustable power supplies, which consists of a mains transformer with two separate secondary windings to which two two-way rectifiers with filter capacitors are connected, and a voltage stabilizer to which a comparator is connected. and from the voltage suspension at the output of the voltage stabilizer. The disadvantage of the symmetrical source thus created is that there is no positive and negative supply branch without the current fuses connected. In the event of a short circuit in one branch, the components connected in the other branch are destroyed.

There is also a solution using optocouplers that allows you to limit the current in the other branch when one power branch is overloaded. The disadvantage of this solution, which is also cumbersome, is that with current limitation, the voltage of both branches changes abruptly to zero. You must use the start button to restart.

The above-mentioned disadvantages are eliminated by a symmetrical stabilized source with dependent current fuses according to the invention. This symmetrical stabilized source consists of a mains transformer with two separate secondary windings, on each of which one two-way rectifier with a filter capacitor is connected, a voltage stabilizer to which a comparator is connected and a voltage suspension at the voltage stabilizer output. At the output of a symmetrical stabilized source, one smoothing capacitor is always connected in the positive and negative branch. The essence of this new symmetrical stabilized source is that a circuit formed at the input by a series combination of a first diode and a first resistor is connected in parallel to the filter capacitor of each two-way rectifier, where the anode of the first diode is connected to the positive pole of the respective filter capacitor. In parallel to this first diode, a first capacitor is connected, connected by a positive field to its anode, as well as a series combination of a potentiometer and a second resistor. The second resistor is connected to the cathode of the first diode and the potentiometer to its anode. This anode is connected via a third resistor to the inverting input of the operational amplifier in the respective branch, to the non-inverting input of which a potentiometer runner is connected. A series combination of a second and a third capacitor is connected between the non-inverting input of the operational amplifier in the positive branch and the non-inverting input of the operational amplifier in the negative branch. The emitter of the transistor is grounded and its base is connected through the fourth resistor to ground and through the fifth resistor to the anode of the Zener diode, whose cathode is connected to the op amp output in the positive branch and to the cathode of the second diode, whose anode is connected to the op amp output. negative branch. The inverting input of the operational amplifier in the positive branch is connected to the power supply terminal of the voltage stabilizer. The inverting input of the operational amplifier in the negative branch is grounded, its negative supply voltage input is connected to the common point of the first resistor and negative pole of the filter capacitor in the negative branch and at the same time to the voltage suspension output and its positive supply voltage input is connected to positive branch. The negative supply voltage input of the operational amplifier in the positive branch is grounded and its positive supply voltage input is connected to the output of the voltage doubler, which is connected to the first two-way rectifier in the positive branch.

The advantage of this symmetrical stabilized source according to the invention is that it has simultaneously adjustable current fuses in both supply branches and allows to limit the current in the other branch when one branch is overloaded. Both branches jump in by removing the short circuit. Unlike optocoupler sources, this symmetrical stabilized source can operate in current mode, so it can be used as a voltage and current source, which results in the possibility of wider use - for example, it can be used in determining the Zener voltage of Zener diodes.

An example of the connection of a symmetrical stabilized source with dependent current fuses according to the invention is shown in the accompanying drawing.

One two-way rectifier £ with a filter capacitor £ is connected to one secondary winding per power transformer £ with two separate secondary windings. In the positive and negative branches, the same circuit is always connected in parallel to the filter capacitor £. This circuit is formed at the input by a first diode £, connected by an anode to the positive pole of the filter capacitor £ and a cathode via a first resistor £ connected to its negative pole. In parallel with the first diode 6, a first capacitor 6 is connected by a positive pole to the anode. Furthermore, a series combination of potentiometer £, second resistor £ is connected in parallel to this first diode £, one end of potentiometer £ being connected to the anode of the first diode £, which is simultaneously connected via a third resistor £ to the inverting input of operational amplifier 10 or 11. negative branch. Non-inverting input of operational amplifier χθ_, resp. 11 is connected to the runner of the potentiometer 7 in the respective branch. The non-inverting input of the operational amplifier 10 in the positive branch is connected to the second capacitor 12 ^{which y} is P ^Res third capacitor 13 connected to the noninverting input of operational amplifier 11 in the negative branch. The common point of the second and third capacitors 12 and 13 is connected to the collector of the transistor 14 and at the same time to the base 15 of the output transistor of the voltage stabilizer 16, where this output transistor is not drawn. The emitter of the transistor 14 is grounded and its base is connected via a fourth resistor 17 to ground and via a fifth resistor 18 to the anode of the Zener diode 19, the cathode of which is connected to the output of the operational amplifier 10 in the positive branch and to the cathode of the second diode 22. the anode is connected to the output of the operational amplifier 11 in the negative branch. The negative voltage input of the operational amplifier 11 in the negative branch is connected to the common point of the first resistor 2 ^{and the} negative pole of the filter capacitor 2 ⁱⁿ this negative branch and at the same time to the input of the voltage hinge 23. in the positive branch and its inverting input is grounded. The negative voltage input of the operational amplifier 10 in the positive branch is grounded, its positive voltage input is connected to the output of the voltage doubler 21, which is connected to the two-way rectifier 2 ^{in the} positive branch and its inverting input is connected to the power supply terminal 16. circuit MAA 723. A comparator 22 with an LED diode is connected to the voltage stabilizer 16, which is grounded. A voltage hinge 22 is connected to the output of the voltage stabilizer 16, which is also grounded. 24, ^to which a discharging resistor can be connected in parallel and a second smoothing capacitor 25 is connected in parallel in the negative branch.

The symmetrical stabilized source has a continuously variable voltage from +2 V to + _18 V. The current fuses consist of an operational amplifier 10 in the positive branch and an operational amplifier 11 in the negative branch and their function is indicated by the comparator LED 22. When the set current is exceeded as a power source. The function of current fuses in the positive and negative branch is the same. Operational amplifier 10 and 11 compares the reference voltage with the voltage drop across. third resistor 2 · This voltage is proportional to the output current of the symmetrical stabilized source. The reference voltage is obtained as a voltage drop across the first diode 4 in the forward direction. This voltage can be regulated by potentiometer 2, which according to the application can be realized as tandem. Then each of its paths serves for one branch of the source. If the voltage drop across the third resistor 2 is less than the reference voltage, the inverting input of the operational amplifier 10, resp. 11, more positive voltage than at its non-inverting input. Therefore, there is a negative voltage at the output of the operational amplifier 10 or 11 and the transistor 14 is closed. The symmetrical stabilized source works as a voltage source. As the output current increases, so does the voltage drop across the third resistor 2. which opens the transistor 14. The collector of the transistor 14 switches the base 15 of the output transistor of the voltage stabilizer 16, i.e. the integrated circuit MAA 723, to ground. At the output of the positive and thus also of the negative branch, the voltage decreases, which is proportional to the output current, which creates a voltage drop across the third resistor 2. The operational amplifier 10 or 11 operates so that this voltage drop is equal to the reference voltage. There is zero voltage between the inverting and non-inverting inputs of the operational amplifier 10 or 11. The magnitude of the reference voltage determines the magnitude of the output current. ,

The first diode £ is used to produce the reference voltage, and a first resistor 2 is used to limit the current through this first diode £. In fact, a voltage drop is generated on the second resistor 2, which is no longer required for control by the potentiometer 2. The first capacitor 6, connected in parallel to the first diode 6, serves to filter the reference voltage and thus results in a decrease in output voltage ripple in current limiting mode. The Zener diode 19 at the output of the operational amplifier 10 in the positive branch reduces the output voltage of this operational amplifier 10 if its output switches a positive voltage. If its output switches a negative voltage, this Zener diode 19 separates the output of the operational amplifier 10 in the positive branch and the output of the operational amplifier 11 in the negative branch. Its Zener voltage is 18 V and is equal to the voltage of the doubler 21 · The second diode 20 separates the outputs of both operational amplifiers 10 and 11 in the closing direction. the resistor 18 limits the current flowing from the operational amplifier 10 in the positive branch or from the operational amplifier 11 in the negative branch to the base of the transistor 14. The fourth resistor 17 serves to divert the current carriers and thus to close the transistor 14 faster. The second and third capacitors 12 and 13 are for frequency compensation. The collector of the transistor 14 controls the base 15 of the output transistor of the voltage stabilizer 16, i.e. the cataloged integrated circuit MAA 723. A comparator 22 is used to indicate current overload by means of an LED diode. regulated by a voltage hinge 23, which is solved by an operational amplifier. The outputs of both branches are smoothed by means of the first and second smoothing capacitors 24 and 25. The voltage hinge 23 and the overload comparator 22 are supplied in the same way as the operational amplifier 11 in the negative branch.

The symmetrical stabilized power supply with dependent current fuses according to the invention can be used, for example, to supply and reactivate circuits with operational amplifiers and low-frequency power amplifiers.

Claims (1)

OBJECT OF THE INVENTION Symmetrical stabilized source with dependent current fuses, consisting of a mains transformer with two separate secondary windings to which two two-way rectifiers with filter capacitors are connected, a voltage stabilizer to which the comparator is connected and a voltage hinge connected to the voltage stabilizer output, Smoothing capacitors are connected to the output of a symmetrical stabilized source, characterized in that a circuit formed at the input by a series combination of a first diode (4) and a first resistor (5) is connected in parallel to the filter capacitors (3) of each two-way rectifier (2). diode (4) is connected to the positive pole of the respective filter capacitor (3) and parallel to this first diode (4) is connected a first capacitor (6), connected by a positive pole to its anode and a series combination of potentiometer (7) and second resistor ( 8), where the second resistor (8) is connected to the cathode of the first diode (4) and the potentiometer (7) to its anode and this the anode is connected via a third resistor (9) to the inverting input of the operational amplifier (10 or 11) in the positive or negative branch, to whose non-inverting input a potentiometer runner (7) is connected and between the non-inverting input of the operational amplifier (10) in the positive branch and the non-inverting the input of the operational amplifier (11) in the negative branch is connected to a series combination of the second and third capacitor (12 and 13), the common point of which is connected to the collector of the transistor (14) and at the same time to the base (15) of the output transistor of voltage stabilizer transistor (14) is grounded and its base is connected via a fourth resistor (17) to ground and via a fifth resistor (18) to the anode of a Zener diode (19), the cathode of which is connected to the output of the operational amplifier (10) in the positive branch and with the cathode of the second diode (20), the anode of which is connected to the output of the operational amplifier (11) in the negative branch, the inverting input of the operational amplifier (10) in the positive branch being connected to the supply terminal of the voltage stabilizer (16). the rt input of the operational amplifier (11) in the negative branch is grounded, its negative supply voltage input is connected to the common point of the first resistor (5) and the negative pole of the filter capacitor (3) in the negative branch and is also connected to the voltage hinge output (23) and its positive supply voltage input is connected to the anode of the first circuit diode (4) in the positive branch, the negative supply voltage input of the operational amplifier (10) in the positive branch is grounded and its positive supply voltage input is connected to the voltage doubler output (21), which is connected to a two-way rectifier (2) in the positive branch.