SU506840A1 - Voltage Regulator with Adjustable Temperature Coefficient - Google Patents

Description

one

The invention relates to automatic control devices and can be applied in systems where a change in the output parameter (voltage) is required according to a given law (for example, linear) from the ambient temperature. Stabilizers of this type are used to power computer storage devices.

Adjustable temperature coefficient voltage regulators are known, containing a regulating element connected in series to the stabilizer output bus and connected to the output of the reference unit along the control circuit, which is connected to the output of the stabilizer by one input and the voltage source made from one input. in the form of a current-stabilizing two-pole device on a transistor, the collector of which is connected to the indicated divider, and the emitter is a current-supplying resistor.

The main disadvantage of such a stabilizer is the dependence of the temperature coefficient of voltage (TKN) on the adjustment of the output voltage, which is provided by changing the division factor of the feedback divider. On the other hand, the limits of the regulation of the temperature coefficient itself are limited, since they require a simultaneous change in the linearizing resistances connected in parallel and in series with the thermistor, and the calculation of these resistances is rather complicated.

In order to obtain the temperature coefficient of the voltage of the stabilizer independent of the output voltage, in the proposed stabilizer, the base of the current-stabilizing two-pole transistor is connected to noloconductor diodes in series with which one emitter follower is connected, and another emitter follower is used by one emitter follower, in series with one emitter follower. to the corresponding voltage dividers that thread the current-stabilizing two-terminal networks.

The drawing shows a circuit diagram of the proposed stabilizer.

Claims (1)

The stabilizer consists of a control transistor I, a comparator organ 2, one input of which is connected to the slider of potentiometer 3, which is a divider of the voltage source, and the second is connected to the output of the stabilizer. Potentiometer 3 is connected to a voltage source 4, made in the form of a two-terminal current-stabilizing transistor 5, resistor 6, a group of series-connected diodes 7, emitter followers 8 and 9, the bases of which are connected to potentiometers 10 and 11, respectively, which are voltage dividers supplying a current-stabilized two-terminal device from an auxiliary parametric stabilizer 12. Comparison organ 2 is given a feedback signal Loc from the output of the stabilizer and reference voltage Uoa from potentiometer 3. P and a constant temperature regulator maintains the output voltage at the required stability, and in the embodiment of the circuit of FIG tsa, stabilized voltage to the control transistor 1. Potentiometer 3 allows control of the reference, and accordingly, the output voltage in the range extensive reorganization. The voltage at potentiometer 3 is determined by the current of the two-port 4, which in turn depends on the ambient temperature. Thus, the temperature coefficient of the support voltage will be equal to the temperature coefficient of the current and at the same time will not depend on the position of the slider of potentiometer 3. Variable resistor 6 is used to set the current value of the bipolar /; / R. where f / 6 is the voltage across the resistor 6, the base current can be neglected; Re is the resistance of the resistor 6. We denote the TKN of the voltage Us by 8n, and the temperature coefficient of the current is W. Obviously, it is EnEng .-. 100o / o, (1) where At / 6 is the voltage increment on the resistor 6 when the temperature changes by A / ° C (with a linear dependence of en on temperature, which is provided by using semiconductor devices as thermo-dependent elements). .:. f /, + Oke, - ca. - f / 6.,; (2) W, - W, +, - Af / e ,. - ,, (3) whereLute and is the voltage, and accordingly, the voltage increment on the diodes 7 when the temperature changes at AGS; UKS, and Ike, are the emitter follower voltages, respectively 8 and 9; ibe-, -pump transition base-emitter of transistor 5; DNU is the temperature increment of the voltage on the diodes 7; ,,, and A (/ B5-temperature increments of voltage at the base-emitter transitions of transistors, respectively 8, 9 and 5. TKN for diodes and transitions, the base-emitter has a linear dependence on temperature and is characterized by a value of e (1.6 + 2) - deg. Considering that for this device the value of e is constant under conditions of small changes in the current through it, from the expression (1) it follows that the temperature coefficient SH of the voltage f / 6 can be adjusted by changing the emitter voltage repeaters and short circuit and / kee using potentiometers 10 and 11. From the expression (1) and (2) it is also seen that with the help of an emitter follower 8 it is possible to increase, and with the help of 9 it is possible to reduce the TKN, determined only by diodes 7 and the base-emitter junction of transistor 5, in extremely wide limits. The group is determined from the condition that the minimum voltage f / e is not less than 1 V. (To ensure stable operation of the stabilizer.) One of the advantages of the described stabilizer circuit is the simplicity of the TCH setting for a single temperature test. If we neglect the influence of the organ of comparison, then we can assume that the TKN at the output is equal to the TKN of the reference voltage. Based on the constant value, we can get sf / 6. (4) where e is TKN at voltage I (, (measured at normal temperature), e is TKN at voltage (measured also at normal temperature). In a similar way, The TKN value for an arbitrary voltage Uf ,, can be set to the TK g by setting the voltage defined by (4) with potentiometers 10 and 11 without repeated temperature testing. In order to ensure constant current in the two-pole cells, it is advisable to simultaneously use About resistor 6 to set a constant value of the reference voltage (/ oi. The accuracy of the TKN installation depends on the accuracy of the measuring device. From the above it is clear that all subsequent adjustments of the output voltage with the ncjMCRibio potentiometer 3 do not change the set value of the TKN. Formula of the invention Stabilizer voltage temperature controlled variable temperature regulator, containing a regulating element, connected in accordance with the stabilizer output bar and connected to the outlet of the reference element along the control circuit, which is one the input is connected to the output of the stabilizer, and the other to the divider of the voltage source, performed in the form of a current-stabilizing two-pole device on a transistor whose collector is connected to the specified divider, and the emitter is equipped with a current-dependent resistor, which in order to obtain a temperature coefficient of a voltage regulator independent of the output voltage, the base of the current-stabilizing two-pole transistor is connected to a group of series-connected semiconductor diodes, tion with which one emitter follower is enabled, and in series with the current-supply resisto-5 bipolar. Roll1 included another emitter follower, and the emitter follower bases are connected to the corresponding voltage dividers supplying the current stabilizing