CN204442177U - A kind of DC/DC change-over circuit with temperature-compensating - Google Patents

Abstract

The utility model discloses a kind of DC/DC change-over circuit with temperature-compensating, belong to portable set application.The described DC/DC change-over circuit with temperature-compensating comprises a temperature-compensation circuit, an error amplifier, an oscillator, one drive circuit, one slope compensation circuit, a comparator, a power tube, one current sampling resistor, one first feedback resistance, one second feedback resistance, an inductance, one fly-wheel diode, an output filter capacitor; One building-out capacitor and a trigger.In the course of work; if load current is excessive or ambient temperature is too high and when causing Integrated Circuit Temperature to be elevated to set limit value; control output voltage to raise further with temperature and reduce gradually; thus output current also can be raised with temperature further and reduce gradually; Protective IC not damage by high temperature while, the chip avoiding traditional overheat protector mode to cause constantly switch problem repeatedly.

Description

A kind of DC/DC change-over circuit with temperature-compensating

Technical field

The utility model belongs to portable set application, particularly a kind of DC/DC change-over circuit with temperature-compensating.

Background technology

Fig. 1 is the DC/DC change-over circuit with traditional thermal-shutdown circuit, and during work, chip can equal VREF voltage by control FB voltage, and Output Voltage Formula is as follows:

$\mathrm{VOUT}=\frac{R1+R2}{R1}\×\mathrm{VREF}=\mathrm{VREF}+\frac{R2}{R1}\mathrm{VREF};$

During the overheat protector value causing IC interior temperature to reach set when load current is excessive or ambient temperature is too high, thermal-shutdown circuit THSD exports high level and turns off chip output, such chip quits work, temperature starts to decline, when temperature drops to set System recover temperature value, thermal-shutdown circuit THSD exports and becomes low level from high level, chip restarts work, if cause the condition of overheat protector not change, can overheat protector be triggered and chip be quit work again so after a period of operation, go round and begin again like this, load is made not stop change with the state that quits work in working order, have a strong impact on the work of load.

Utility model content

The utility model is for the drawback of prior art, primary and foremost purpose is to provide a kind of DC/DC change-over circuit with temperature-compensating, during the temperature causing IC interior temperature to reach set when load current is excessive or ambient temperature is too high, temperature-compensation circuit can export one to raise further with temperature and the offset current that increases to feedback resistance R1, such output voltage will raise further with temperature and reduces, corresponding load current also can reduce, guarantee that integrated circuit always works in below set limiting temperature by temperature feedback, when Protective IC is not by high temperature failure, it also avoid load in working order and the state that quits work do not stop to change and have a strong impact on the work of load.

The purpose of this utility model is achieved through the following technical solutions: a kind of DC/DC change-over circuit with temperature-compensating, comprising: a temperature-compensation circuit, an error amplifier EA, one oscillator OSC, one drive circuit DRIVER, a slope compensation circuit SLOPE, one comparator PWM, one power tube MN1, a current sampling resistor RS1, one first feedback resistance R1, one second feedback resistance R2, one inductance L 1, sustained diode 1, output filter capacitor C1, one building-out capacitor and a trigger, the output of described temperature-compensation circuit meets the link FB of the first feedback resistance R1 and the second feedback resistance R2, link FB connects the inverting input of error amplifier EA simultaneously, the in-phase input end of described error amplifier EA meets reference voltage VREF, the output COMP of described error amplifier EA connects building-out capacitor to ground, export the inverting input that COMP meets comparator PWM simultaneously, the in-phase input end of comparator PWM is linked into after the inductive current sampled signal that the slope compensation signal that described slope compensation circuit SLOPE sends and current sampling resistor RS1 send is added, the reset terminal of the output contact hair device of described comparator PWM, the set end of the output contact hair device of described oscillator OSC, the output of described trigger connects the input of drive circuit DRIVER, the output of described drive circuit DRIVER connects the grid of power tube MN1, the drain electrode SW of described power tube MN1 connects one end of inductance L 1, the SW that simultaneously drains connects the positive pole of fly-wheel diode D1, the negative pole of described sustained diode 1 connects the positive pole of output filter capacitor C1 and one end of the first feedback resistance R1.

Described temperature-compensation circuit comprises a pnp type triode, an operational amplifier OP, a follower MN2, one the 3rd feedback resistance R3, a diode D2; One first constant-current source I 1, one second constant-current source I2; The collector electrode of described pnp type triode and base earth, the emitter of described pnp type triode meets the first constant-current source I 1, pnp type transistor emitter connects the in-phase input end of operational amplifier OP simultaneously, the output of described operational amplifier OP connects the grid of follower MN2, one end ground connection of described 3rd feedback resistance R3, the source electrode of another termination follower MN2 and the inverting input of operational amplifier OP, the drain electrode of described follower MN2 connects the positive pole of the second constant-current source I2 and diode D2, and the output of described diode D2 is offset current Ic.

Described temperature-compensation circuit can be applied to voltage up converting circuit or decompression converting circuit.

In the course of work, if load current is excessive or ambient temperature is too high and when causing Integrated Circuit Temperature to be elevated to set limit value, temperature-compensation circuit exports an offset current Ic to feedback resistance R1, along with temperature raises further, Ic can increase, output voltage will reduce, thus output current also can be raised with temperature further and reduces gradually, guarantees that integrated circuit always works in below set limiting temperature by temperature feedback.

The utility model compared with prior art; the utility model adopts the mode of temperature-compensating; when detecting that temperature is greater than set limit value; start to export offset current; guarantee that drive integrated circult always works in below set limiting temperature by temperature feedback; Protective IC not damage by high temperature while, avoid the chip that traditional overheat protector causes and constantly repeatedly work and out-of-work problem.

Accompanying drawing explanation

Fig. 1 is the DC/DC change-over circuit figure with conventional temperature protection;

Fig. 2 is the DC/DC change-over circuit figure described in the utility model embodiment 1 with temperature-compensating;

Fig. 3 is the specific embodiment figure of the temperature-compensation circuit described in the utility model embodiment 1.

Embodiment

Fig. 2 is the DC/DC change-over circuit with temperature-compensating described in the utility model, is described in further detail the utility model below in conjunction with Fig. 2 and Fig. 3.

As shown in Figure 2, the utility model provides a kind of DC/DC change-over circuit with temperature-compensating and comprises: a kind of DC/DC change-over circuit with temperature-compensating, comprising: a temperature-compensation circuit, one error amplifier EA, an oscillator OSC, one drive circuit DRIVER, one slope compensation circuit SLOPE, a comparator PWM, a power tube MN1, one current sampling resistor RS1, one first feedback resistance R1, one second feedback resistance R2, an inductance L 1, one sustained diode 1, output filter capacitor C1, one building-out capacitor and a trigger, the output of described temperature-compensation circuit meets the link FB of the first feedback resistance R1 and the second feedback resistance R2, link FB connects the inverting input of error amplifier EA simultaneously, the in-phase input end of described error amplifier EA meets reference voltage VREF, the output COMP of described error amplifier EA connects building-out capacitor to ground, export the inverting input that COMP meets comparator PWM simultaneously, the in-phase input end of comparator PWM is linked into after the inductive current sampled signal that the slope compensation signal that described slope compensation circuit SLOPE sends and current sampling resistor RS1 send is added, the reset terminal of the output contact hair device of described comparator PWM, the set end of the output contact hair device of described oscillator OSC, the output of described trigger connects the input of drive circuit DRIVER, the output of described drive circuit DRIVER connects the grid of power tube MN1, the drain electrode SW of described power tube MN1 connects one end of inductance L 1, the SW that simultaneously drains connects the positive pole of fly-wheel diode D1, the negative pole of described sustained diode 1 connects the positive pole of output filter capacitor C1 and one end of the first feedback resistance R1.

In the course of work, if load current is excessive or ambient temperature is too high and when causing Integrated Circuit Temperature to be elevated to set limit value, temperature-compensation circuit exports an offset current Ic to feedback resistance R1, and the formula of such output voltage is:

$\mathrm{VOUT}=\mathrm{VREF}+(\frac{\mathrm{VREF}}{R1}-\mathrm{Ic})\×R2=\mathrm{VREF}+\frac{R2}{R1}\mathrm{VREF}-\mathrm{Ic}\×R2$

Like this along with temperature raises further, Ic can increase, output voltage VO UT will reduce, thus output current also can be raised with temperature further and reduces gradually, guarantees that drive integrated circult always works in below set limiting temperature by temperature feedback.

Be illustrated in figure 3 the specific embodiment of temperature-compensation circuit described in the utility model, described temperature-compensation circuit comprises a pnp type triode, an operational amplifier OP, a follower MN2, one the 3rd feedback resistance R3, a diode D2; One first constant-current source I 1, one second constant-current source I2; The collector electrode of described pnp type triode and base earth, the emitter of described pnp type triode meets the first constant-current source I 1, pnp type transistor emitter connects the in-phase input end of operational amplifier OP simultaneously, the output of described operational amplifier OP connects the grid of follower MN2, one end ground connection of described 3rd feedback resistance R3, the source electrode of another termination follower MN2 and the inverting input of operational amplifier OP, the drain electrode of described follower MN2 connects the positive pole of the second constant-current source I2 and diode D2, and the output of diode D2 is offset current Ic.

Under the effect of OP, the anti-phase input terminal voltage of OP equals VEB, so offset current Ic meets formula below:

$\mathrm{Ic}=I2-\frac{\mathrm{VEB}}{R3}$

When temperature does not exceed set temperature value, I2 is less than VEB/R3, and diode D2 is in cut-off state, and offset current Ic is 0.When I 1 is certain, the EB junction voltage VEB of Q1 reduces along with the rising of temperature, when temperature be elevated to make I2 be greater than VEB/R3 time, temperature-compensating pattern starts, export offset current Ic and be greater than 0, and Ic increases along with the further rising of temperature, output voltage VO UT will reduce, thus output current also can be raised with temperature further and reduce gradually, guarantee that drive integrated circult always works in below set limiting temperature by temperature feedback.

Described temperature-compensation circuit can be applied to voltage up converting circuit or decompression converting circuit.

Above embodiment is only a specific execution mode of the present utility model, but not to restriction of the present utility model, all those skilled in the art make some adjustment according to design of the present utility model and change, and are still main idea place of the present utility model, all because of within scope of the present utility model.

Claims (2)

1. there is a DC/DC change-over circuit for temperature-compensating, it is characterized in that: comprising: a temperature-compensation circuit, an error amplifier EA, one oscillator OSC, one drive circuit DRIVER, a slope compensation circuit SLOPE, one comparator PWM, one power tube MN1, a current sampling resistor RS1, one first feedback resistance R1, one second feedback resistance R2, one inductance L 1, sustained diode 1, output filter capacitor C1, one building-out capacitor and a trigger, the output of described temperature-compensation circuit meets the link FB of the first feedback resistance R1 and the second feedback resistance R2, link FB connects the inverting input of error amplifier EA simultaneously, the in-phase input end of described error amplifier EA meets reference voltage VREF, the output COMP of described error amplifier EA connects building-out capacitor to ground, export the inverting input that COMP meets comparator PWM simultaneously, the in-phase input end of comparator PWM is linked into after the inductive current sampled signal that the slope compensation signal that described slope compensation circuit SLOPE sends and current sampling resistor RS1 send is added, the reset terminal of the output contact hair device of described comparator PWM, the set end of the output contact hair device of described oscillator OSC, the output of described trigger connects the input of drive circuit DRIVER, the output of described drive circuit DRIVER connects the grid of power tube MN1, the drain electrode SW of described power tube MN1 connects one end of inductance L 1, the SW that simultaneously drains connects the positive pole of fly-wheel diode D1, the negative pole of described sustained diode 1 connects the positive pole of output filter capacitor C1 and one end of the first feedback resistance R1.

2. there is the DC/DC change-over circuit of temperature-compensating as claimed in claim 1, it is characterized in that: described temperature-compensation circuit comprises a pnp type triode, an operational amplifier OP, a follower MN2, one the 3rd feedback resistance R3, a diode D2; One first constant-current source I1, one second constant-current source I2; The collector electrode of described pnp type triode and base earth, the emitter of described pnp type triode meets the first constant-current source I1, pnp type transistor emitter connects the in-phase input end of operational amplifier OP simultaneously, the output of described operational amplifier OP connects the grid of follower MN2, one end ground connection of described 3rd feedback resistance R3, the source electrode of another termination follower MN2 and the inverting input of operational amplifier OP, the drain electrode of described follower MN2 connects the positive pole of the second constant-current source I2 and diode D2, and the output of described diode D2 is offset current Ic.