RU2242831C2 - Voltage switching device incorporating load unit overcurrent protective gear - Google Patents

Abstract

FIELD: electronic engineering; switch-mode power supplies incorporating load unit overcurrent protective gear.

SUBSTANCE: proposed voltage switching device has electronic switch that functions to supply load unit with power through load current sensor. Single-pulse generator provides for device reset to make it ready for ON-operation and relay unit connected to current sensor output through OR gate and flip-flop and functions to disconnect load unit from power supply on occurrence of overcurrent both under transient and steady state conditions thereby affording regulation of desired variables of load overcurrent protective gear and reliable reset (setting in OFF-position) before energizing the device.

EFFECT: enlarged functional capabilities and operating reliability.

2 cl, 1 dwg

Description

The invention relates to the field of electronic technology and can be used in switched power supplies with overcurrent protection of both the load unit and the power source and the electronic key itself.

Known voltage stabilizer with protection against overcurrent, containing an electronic switch made on a transistor, a current sensor, a load unit and a second transistor controlling the electronic switch [1].

A disadvantage of the known device is that when the current in the load rises above the permissible one, for example, due to a failure, the second transistor opens and reduces the current flowing through the electronic switch, thereby reducing the allocated power on the electronic switch and, at the same time, the voltage on load. This device does not completely disconnect the load from the voltage source, which in many cases is unacceptable due to the high likelihood of false signals or commands being issued by the failed device.

The closest technical solution to the proposed device is a voltage switch such as a powerful electronic switch BTS149 from INFINEON (formerly SIEMENS; Germany) with the protection of the load unit against overcurrent, described in [2]. Known voltage switch contains connected in series with the load unit electronic switch and current sensor.

A disadvantage of the known device is that the limitation of power in the load unit consumed from the voltage source occurs at a current in the load significantly exceeding the permissible current for the load itself and the rated current through the electronic switch. At the same time, in many cases, during failures, the current consumed in the load block does not reach values at which the known device begins to limit the load current and turn it off, as a result of which overload protection is not carried out. In addition, in the known device, the level of disconnection of the voltage source by the load current remains unchanged and cannot be adjusted to another current value. Given that when the load unit is switched on, the transient current always significantly exceeds the steady state current, it is not possible in the known device to simultaneously protect against overcurrent both in the transient process (at the moment of switching on) and in the steady state.

The objective of the invention is the expansion of functionality by providing protection against overcurrent both in the transient process when the power of the load unit is turned on, and in the steady state, providing the possibility of regulating the protection parameters depending on the load parameters and increasing the functional reliability of the device due to the unconditional installation of elements control in the initial state at the time of turning on the device.

This task is achieved by the fact that in the voltage switch with the protection of the load unit against overcurrent, containing a series-connected load current sensor and an electronic key connected to the load unit, a single pulse generator, an OR logic element, a trigger, a relay element with a direct and inverting inputs, an integrating element, a threshold switch of a relay element connected to an inverting input of a relay element, the output of a logical element OR connected to a reset input trigger, trigger input is connected to voltage switch on input, trigger direct output is connected to electronic key control input, load current sensor output is connected to direct input of relay element, relay element output is connected to first input of OR gate, second input of which is connected to input switch off voltage, the inverse trigger output through an integrating link is connected to the inverting input of the relay element, the output of a single pulse generator is connected to temu input of the OR gate, wherein the single pulse generator may be configured as a differentiator.

The drawing shows a block diagram of a voltage switch with overcurrent protection, while in the drawing and further in the text are indicated:

1 - load current sensor;

2 - electronic key;

3 - load unit;

4 - logical element OR;

5 - trigger;

6 - the first relay element;

7 - the trigger threshold of the relay element;

8 - integrating unit;

9 - input switch voltage;

10 - input switch off the voltage switch;

11 - power supply source;

12 - the second source of supply voltage;

13 - single pulse generator;

U is the switched voltage;

E is the voltage of the second voltage source;

U _in - switch input signals;

U _out - switch off input signals;

u ₁ , u ₂ - threshold voltage at the inverting input of the relay element;

u _i is the voltage from the load current sensor at the direct input of the threshold element 6;

I _Ni - load current;

k is the transmission coefficient (slope) of the sensor 1 load current;

GND is a common bus for power supplies (ground).

The voltage switch with overcurrent protection is as follows.

The load current sensor 1, the electronic switch 2 and the load unit 3 are connected in series and connected to the power supply 11. The threshold threshold of the relay element 7 is connected to the inverting input of the relay element 6, the output of which is connected to the first input of the logic element OR 4, the second input of which connected to input 10 off the voltage switch. The output of the logic element OR 4 is connected to the reset input of the trigger 5, the input of the installation of the trigger 5 is connected to the input 9 of the inclusion of the voltage switch. The direct output of the trigger 5 is connected to the control input of the electronic key 2. The inverse output of the trigger 5 through the integrating link 8 is connected to the inverting input of the relay element 6. The output of the load current sensor 1 is connected to the direct input of the relay element 6. A single pulse generator 13 is connected to a voltage source, and its output is connected to the third input of the OR gate.

The drawing shows the simplest embodiment of the elements of the block diagram of the device. However, the elements of the proposal may not have fundamental differences. So, the load current sensor 1 can be performed using a Hall sensor, the load unit 3 can have, in particular, capacitive components, the threshold switch 7 of the relay element can have a different power source, one (R1) or two (R1, R2) resistors . Instead of an integrating link in the form of the simplest R3C1 chain, two-link ones can be used. RS type trigger 5 can be replaced by a D trigger with reset input R. In the simplest case, the single pulse generator 13 can be made in the form of a differentiating link C2 R4.

The power source of the first supply voltage 11 is an energy source for the load unit 3 (equipment load units), its rated voltage depends on the type of equipment in which the proposed device is used, for example, U = 27 V. The second supply voltage source 12 serves to power the elements of the device and of the trigger threshold of the relay element 7, its voltage is determined by the types of elements used and is, for example, 5 V.

The voltage switch with overcurrent protection operates as follows.

After supplying the supply voltages E and U, the device is restored to its initial (switched off) state: the pulse generated by a single pulse generator 13, through a logical element OR 4, resets trigger 5 (sets it to its original state), resulting in a logical zero from the direct output of this trigger holds the key 2 in the closed state, and the load unit 3 is turned off.

In the initial state of the device, the current from the inverse output of the trigger 5 through the resistor R3 of the integrating element 8 and the current through the resistor R1 of the trigger threshold of the relay element 7 create a blocking voltage u ₁ at the inverting input of the relay element 6 (on the resistor R2), which, using Kirchhoff's laws, can be determined by the formula

Formula (1) is valid in the ideal case when the voltage of the trigger threshold of the relay element 7 and the trigger 5 is supplied from the voltage source E, and the voltage at the inverse output of the trigger 5 is negligibly different from the value of this voltage. Otherwise, the calculation of the voltage u ₁ should be made taking into account the real values of the stresses at the indicated points. In most cases, formula (1) gives accuracy sufficient for practice.

The output voltage from the load current sensor 1, equal to zero, is applied to the direct input of the relay element 6, the output of which is also equal to zero.

By the pulse signal U _in = 1 supplied to the voltage switch input 9, the trigger 5 is set to a single state, and its output signal from the direct output Q puts the electronic switch 2 into the on state, which, in turn, closes the power supply circuit of the load unit 3. If the load current I _N1 at this moment is within the specified limits, then the voltage u _i = kI _N1 at the direct input of the relay element 6 coming from the load current sensor 1 is less than the voltage u ₁ and the relay element 6 remains in the original (off) condition on his Exit logic zero. Load block 3 is on. However, if the load current I _N1 at the time of its switching on is excessively large and the voltage u _i = kI _N1 from the load current sensor 1 exceeds voltage u ₁ , then the relay element also responds with its output pulse (the trailing edge of the pulse is formed after the load current is removed) through OR gate 4 resets trigger 5. This closes the electronic key 2, and the load block 3 is disconnected from the first power supply 11. The device automatically disconnects the load block with a current exceeding the maximum permissible current at the moment the transition starts one process when you turn it on.

If at the moment of switching on the electronic key 2, the load current did not exceed the limit value, then the relay element 6 remained in its original state, the trigger 5 remained on, the signal at its inverse output decreased to zero. In this case, the capacitor C1 of the integrating element 8 begins to discharge through the resistor R3, the voltage at the inverting input of the relay element 6 begins to decrease, and the load current limit capable of automatically turning off the device decreases proportionally. At the end of the transition process, the duration of which is proportional to the capacitance C1 of the integrating element 8, the voltage u ₂ at the inverting input of the relay element 6 can be determined by the formula

This voltage, which can be significantly (several times) less than the voltage u ₁ , will determine the current threshold of the relay element 6 in the steady state of the load block 3. If in this mode the voltage of the load current transmitter 1 at some point exceeds the specified voltage u ₂ (for example, a failure occurred in the load unit when its current exceeded the permissible value), then the relay element 6 will work and with its output pulse through the logic element OR 4 will turn off trigger 5, which, in turn, will close the electronic key 2 and turn off the load block 3. In this case, the device automatically disconnects the load block for current exceeding the permissible current in the steady state load mode.

Here it is necessary to consider the dependence of the ratio of the ratios of the protection currents during switching on and in the nominal mode I _N1 / I _N2 on the ratio of the resistance of the resistors R1-R3. In general, the ratio of currents I _N1 / I _N2 is equal to the ratio of voltages

After simple calculations, we have

As can be seen from expression (3), the ratio of the maximum protection current to the minimum does not depend on the resistance of resistor R2. Thus, by changing the resistance R2, it is possible to simultaneously reconfigure the protection thresholds, both during switching-on and in the steady-state load mode, always preserving the specified margin of protection against overload.

In the nominal operating mode, the load block is turned off by applying a short pulse U _out = 1 to input 10, which, passing through the OR gate 4, resets trigger 5.

Compared with the known voltage switch [2], the present invention extends the functional reliability and functionality of the device by forcing the device to be reset to the initial state upon the supply of a supply voltage to it and protection against overcurrent as in a transient process when the supply voltage is connected to the unit loads (for example, if there is a capacitive component or a DC motor in the load unit 3), and in steady state. The inrush protection time when the load is turned on is proportional to the capacitor C1. The values of currents I _N1 and I _N2 , at which the voltage switch disconnects the load unit from the voltage source, can be widely controlled by resistors R1-R3 and set depending on the parameters of a specific load. When regulating the protection operation currents with one resistor R2, the multiplicity of operation of the protection currents (the ratio of the maximum protection current at the moment the load is turned on to the rated protection current in the steady state) always remains unchanged and depends only on the ratio of the resistors R1 and R3! This additional circumstance improves the consumer properties of the proposed invention, since it simplifies the process of adjusting the levels of current protection, for example, using a potentiometer.

The proposed set of features in the proposal considered by the author was not found to solve the problem and does not follow explicitly from the prior art, which allows us to conclude that the technical solution meets the criteria of "novelty" and "inventive step".

As elements for the implementation of the device, serial microcircuits with the necessary set of functions can be used, for example, 564 series microcircuits, standard relay elements, for example, 521 series, electronic switches of the required power (most promising are field-effect transistors that require minimal control power and are in good agreement with microcircuits )

Literature

1. Sources of power for electronic equipment. Handbook edited by G.S. Naivelt. Moscow, “Radio and Communications”, 1986, p. 189, Fig. 5.19.

2. http://www.infineon.com/cgi/ecrm.dll/ecrm/scripts/prodov. jsp? oid = 13853 & catoid = -8171

http://www.infineon.com/cgi/ecrm.dll/ecrm/scripts/prod ov.jsp? oid = 13853 & cat oid = -8170. Information from the source [2] is given in the application materials.

Claims (2)

1. A voltage switch with protection of the load unit against overcurrent, containing a series-connected load current sensor and an electronic switch connected to the load unit, characterized in that it additionally includes a single pulse generator, OR logic element, trigger, relay element with direct and inverting inputs, an integrating link and a threshold switch of the relay element connected to the inverting input of the relay element, the output of the logical element OR connected to the reset input t the trigger, the trigger installation input is connected to the voltage switch enable input, the direct trigger output is connected to the electronic key control input, the output of the load current sensor is connected to the direct input of the relay element, the output of the relay element is connected to the first input of the OR logic element, the second input of which is connected to the input switch off the voltage switch, the inverse trigger output through the integrating link is connected to the inverting input of the relay element, the output of the single pulse generator is connected to he input of the OR gate. 2. The voltage switch according to claim 1, characterized in that the single pulse generator is made in the form of a differentiating element.