RU211596U1 - Pulse converter protection device against current overloads and short circuits - Google Patents

Abstract

The utility model is used in electrical engineering in the construction of power supplies. The essence of the utility model: a device for protecting a pulse converter from overcurrent and short circuits is proposed, containing a current sensor 1, a control controller 2 with an input of a protection current comparator, an input for setting the conversion frequency, a Common output and a control pulse output, a frequency-setting capacitor 3, an amplitude detector 4 , voltage divider 5, transistor 6 with control and two power outputs, additional capacitor 7; in the device for protecting the pulse converter from overcurrent and short circuits, current sensor 1 is connected between the input of the protection current comparator and the output of the Common control controller 2, and the frequency setting capacitor 3 is connected between the input of the conversion frequency setting and the output of the Common control controller 2, the input of the protection current comparator is connected with the input of the amplitude detector 4, the output of which is connected through the extreme terminals of the voltage divider 5 to the output General of the control controller 2, the middle output of the voltage divider 5 is connected to the control terminal of the transistor 6, one power output of which is connected to the output General, and the other through an additional capacitor 7 - with the input for setting the conversion frequency of the control controller 2. 5 ill.

Description

The utility model relates to electrical engineering and can be used in the construction of pulse voltage and current converters (IP).

Known devices for protecting IP from overcurrent, in which the excess of the current flowing through the current sensor, the threshold value, leads to the shutdown of the IP [1]. However, the restoration of the operating mode in the IP with such protection devices is carried out by switching off and then applying the input voltage, which is not always possible.

Protection devices against current overloads and short circuits, implemented on the basis of control controllers, make it possible to restore the operating mode after the overload is eliminated automatically [2].

The closest in technical essence and the technical problem to be solved is the device for protecting the pulse converter from overcurrent and short circuits at the output, the functional diagram of which is shown in Fig. 13]. The device for protecting the pulse converter from overcurrent and short circuits contains a control controller with a protection current comparator input (CS), an input for setting the conversion frequency (F), a Common output (GND) and a control pulse output (OUT), where the current sensor (DT) , is connected between the input of the protection current comparator CS and the output Common of the control controller, and the frequency setting capacitor C _F is connected between the input of the conversion frequency setting F and the output Common of the control controller.

Consider the operation of a prototype based on a flyback IP. The operating frequency of the control controller is determined by the capacitance of the frequency-setting capacitor C _F . During the action of the pulse at the output OUT of the control controller, a linearly increasing current flows through the current sensor of the IP, the rate of increase of which is proportional to the input voltage. During a pause at the OUT output of the control controller, the current does not flow through the current sensor, and the current through the power inductor decreases linearly at a rate proportional to the output voltage of the MT (shown in dotted lines in the figures). The load current I _N SP is proportional to the average value of the current through the power inductor during a pause at the OUT output of the control controller. The instantaneous value of the voltage on the current sensor is constantly monitored by the protection current comparator. It should be noted that the current in the current sensor does not stop immediately after the end of the pulse at the output OUT of the control controller, but with a delay t _З , the value of which is determined by the delay in closing the power switch of the IP.

The signals on the elements of the prototype in all operating modes of the IP are shown in Fig. 2. The operation of the IP is conditionally divided into 4 modes. During normal operation, the MT operates in the output voltage stabilization mode (interval I), and the pulse duration at the OUT output of the control controller is determined by the feedback signal. The interval I shows the normal mode of operation of the IP at the maximum input voltage and rated load current I _{N N} . In this mode, the instantaneous voltage value on the current sensor is always less than the voltage threshold value of the protection current comparator.

Interval II shows the limiting mode of operation of the IP, when the threshold value of the voltage on the current sensor is reached at the end of the control pulse. The duration of the output pulse of the control controller in this interval is also determined by the feedback signal. In this case, the load resistance R _N MT is less than the nominal value R _{N N.} However, the output voltage of the MT is still stabilized, therefore the slope of the current signal of the power inductor during the pause of the control pulse is the same as in the interval I. The load current reaches the limit value I _{N G} >I _{N N} . Such a margin is always set when adjusting the IP, so that various destabilizing factors, such as ambient temperature, air pressure, or aging of elements, do not lead over time to overloading the IP at a rated load R _N = R _{N N.} Depending on the power of the IP, this margin is 20 ... 50%.

In interval III, the overload increases, R _N <R _{N N} . The duration of the output pulse of the control controller is limited by the protection current comparator when the current in the current sensor reaches the threshold value I _P. Further, during the time t _W , the current in the current sensor continues to increase, due to the delay of the power switch. The load resistance in interval III is even less than in interval II, and the load current of the IP continues to increase: I _N = I _PER > I _{N G} > I _{N N} . The excess of the output current of the MT over the nominal value in this interval can be I _PER = (1.5 ... 2.5) × I _{H N} , depending on the power of the MT. The output voltage of the MT is much less than the nominal value, therefore the slope of the current line in the choke of the MT during the pause is more gentle than at intervals I and II.

And, finally, interval IV - short circuit mode at the output of the IP. Since the output voltage of the MT is equal to 0, the current in the power choke of the MT practically does not decrease during a pause at the OUT output of the control controller. Therefore, during the appearance of the output pulse of the control controller, the current already exceeds the threshold value I _P , and the pulse at the OUT output almost instantly stops. However, the current through the power switch continues to flow for another time t _З. It should be noted that the output current of the IP during a short circuit I _{kz 1} has a maximum value up to the values of 1 _{KZ 1} \u003d (2.5 ... 4) × I _{N N} at which the power inductor of the IP can be saturated. In this case, the rate of current rise sharply increases (shown by a dotted line), which can lead to significant overloads and failure of the power switch of the IP.

The disadvantage of this technical solution is the dependence of the output current of the IP on the degree of overload. Despite the operation of the current limiting circuit, the amplitude value of the current flowing through the current sensor (and, consequently, through the power switch of the IP) continues to increase and reaches its maximum value in the event of a short circuit at the output of the IP, which reduces the reliability of the IP and narrows its scope.

The common features of the proposed technical solution and the prototype are the control controller with the input of the protection current comparator, the input of the conversion frequency setting, the output Common and the output of the control pulse, the current sensor connected between the input of the protection current comparator and the output of the Common control controller, the frequency-setting capacitor connected between the input of the reference conversion frequency and output Common control controller.

The technical task of the proposed utility model is to build a protection device against overcurrent and short circuits, in which, during overload, the amplitude value of the current of the current sensor has a stable value and does not depend on the degree of IP overload, which eliminates emergency operation of the power switch, increases the reliability of the IP and expands its scope.

The technical problem is solved by the fact that a device is proposed to protect the pulse converter from overcurrent and short circuits, containing a control controller with an input of a protection current comparator, an input for setting the conversion frequency, a Common output and a control pulse output, a current sensor connected between the input of the protection current comparator and the output of the Common control controller, a frequency-setting capacitor connected between the input of the conversion frequency setting and the output of the General control controller, characterized in that it contains an amplitude detector, a voltage divider, a transistor and an additional capacitor, and the input of the amplitude detector is connected to the input of the current comparator of the protection of the control controller, and the output through the extreme terminals of the voltage divider - with the output Common, the middle output of the voltage divider is connected to the control output of the transistor, one power output of which is connected to the output Common, and the other through an additional capacitor nsator - to the input for setting the conversion frequency of the control controller.

The introduction of additional elements and new connections into the protection device of a pulse converter against current overloads and short circuits made it possible to stabilize the amplitude value of the current through the current sensor, thereby eliminating overload of the power switch, increase the reliability of the IP and expand its scope.

The applicant has not found technical solutions that have similar features with features that distinguish the claimed solution from the prototype, and, therefore, the proposed technical solution has significant differences.

The proposed device is made of standard elements that are mass-produced by the industry. It is assembled by standard assembly operations using standard equipment, which is especially important in mass production. Therefore, the proposed device satisfies the criterion of industrial applicability.

In FIG. 3 shows a functional diagram of the proposed device for protecting the pulse converter from overcurrent and short circuits. The proposed device for protecting the pulse converter from overcurrent and short circuits contains a current sensor 1, a control controller 2 with an input of a protection current comparator, an input for setting the conversion frequency, a Common output and a control pulse output, a frequency setting capacitor 3, an amplitude detector 4, a voltage divider 5, transistor 6 with a control and two power outputs and an additional capacitor 7.

In the proposed device for protecting the pulse converter from overcurrent and short circuits, current sensor 1 is connected between the input of the protection current comparator and the Common output of the control controller 2, the input of the amplitude detector 4 is connected to the input of the protection current comparator of the control controller 2, and the output through the extreme terminals of the voltage divider 5 - to the output of the General control controller, the frequency-setting capacitor 3 is connected between the input of the conversion frequency setting and the output of the General control controller 2, the middle output of voltage divider 5 is connected to the control output of transistor 6, one power output of which is connected to the output of the General control controller 2, and the other through an additional capacitor 7 - with the input for setting the conversion frequency of the control controller 2.

The signals on the elements of the proposed device for protecting the pulse converter from overcurrent and short circuits are shown in Fig. 4. The proposed device for protecting the pulse converter from overcurrent and short circuits operates as follows. The amplitude detector 4 allocates the amplitude envelope U _AD of the periodic pulse voltage formed on the current sensor 1, and through the voltage divider 5 controls the degree of opening of the transistor 6. identical to the prototype. During an overload (interval III), the signal at the output of the amplitude detector 4 reaches such a level that transistor 6 begins to open, which connects an additional capacitor 7 to the frequency-setting capacitor 3. The frequency of operation of the control controller 2 decreases (the period of operation increases), which is shown in Fig. 4. Since the pause time also increases, the current through the power inductor IP at the same degree of overload drops to a lower value than in the prototype. This means that the load in this mode flows overload current I _PER less than in the prototype. With a further decrease in the load resistance R _H , the transistor 6 opens more and the conversion frequency decreases even more. The next period of operation of the IP will begin with a lower current in the current sensor 1 than in the prototype, and the pause will begin with the same current value in the current sensor 1 as in the previous period of operation of the control controller 2.

In the event of a short circuit (interval IV), the transistor 6 is opened to the maximum, and the reduction in the conversion frequency of the control controller 2 is also maximum. And even taking into account the fact that the rate of decrease in current in the power inductor during a short circuit at the output of the IP during a pause is minimal, by adjusting the transfer ratio of the voltage divider 5, you can adjust the average value of the current in the load I _{short circuit 2} -I _PER . On fig. 4 shows such a setting option that during a pause of the pulse at the OUT output of the control controller, the reduction in the conversion frequency of the IP is so significant that the current in the inductor has time to decrease to zero.

In FIG. 5 shows the comparative output characteristics of the prototype and the proposed device for protecting the pulse converter from overcurrent and short circuits. By setting the transfer ratio of the voltage divider 5 and selecting the capacitance of the additional capacitor 7, it is possible to obtain an almost vertically falling characteristic of the IP when the load resistance R _H decreases from an infinitely large value (sign ∞ on the graph) down to 0 and turn the IP in overload mode into a stable current generator, which expands its scope. At the same time, the amplitude value of the current in the current sensor stabilizes, which increases the reliability of the IP as a whole.

Sources used when writing the application

1. Levinzon S.V. Protection in REA power supplies. - M.: Radio and communication, 1990 - p. 84.

2. Integrated circuits: Microcircuits for switching power supplies and their application. - M. DODEKA, 1997 p. 176.

3. Integrated circuits: Microcircuits for switching power supplies and their application. - M. DODEKA, 1997 p. 93.

Claims (1)

A device for protecting the pulse converter from overcurrent and short circuits, containing a control controller with an input of a protection current comparator, an input for setting the conversion frequency, a Common output and a control pulse output, a current sensor connected between the protection current comparator input and the Common output of the control controller, a frequency-setting capacitor , connected between the input of the conversion frequency setting and the Common output of the control controller, characterized in that it contains an amplitude detector, a voltage divider, a transistor and an additional capacitor, and the input of the amplitude detector is connected to the input of the protection current comparator, and the output through the extreme terminals of the voltage divider - with the Common output of the control controller, the middle output of the voltage divider is connected to the control output of the transistor, one power output of which is connected to the Common output, and the other through an additional capacitor to the input for setting the conversion frequency of the control con troller.

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