CN212033995U

CN212033995U - Intelligent integrated controller and power circuit with same

Info

Publication number: CN212033995U
Application number: CN202020553143.6U
Authority: CN
Inventors: 赖良海; 余智鹏
Original assignee: Shenzhen E-Tek Electronics Manufactory Ltd
Current assignee: Shenzhen E-Tek Electronics Manufactory Ltd
Priority date: 2020-04-14
Filing date: 2020-04-14
Publication date: 2020-11-27
Anticipated expiration: 2030-04-14

Abstract

The utility model discloses an intelligent integrated controller and a power circuit with the same, wherein the intelligent integrated controller comprises a load current detection module, a continuous/discontinuous mode identification module, a logic control module and a power transistor, and the load current detection module is used for detecting the feedback current amount when the load of the power circuit is loaded; the continuous/discontinuous mode identification module automatically detects whether the working state of the transformer of the power supply is a continuous mode or a discontinuous mode by detecting the current magnitude; when a transformer of a power supply is in a continuous or discontinuous working state, the logic control module adjusts and outputs PWM pulse width and drives a power tube; to adjust the transformer primary current PWM pulses. When the power supply circuit is in a discontinuous mode, the PWM pulse width can be adjusted through the logic control module so as to ensure that the slope of the output power supply voltage meets the charging requirement. Or when the circuit is in the continuous mode, the PWM pulse width can be adjusted through the logic control module so as to improve the power conversion efficiency of the circuit.

Description

Intelligent integrated controller and power circuit with same

Technical Field

The utility model relates to a power technical field especially relates to an intelligent integrated controller and have its power supply circuit.

Background

The existing charger for charging battery mainly includes two architectures, namely primary side feedback PSR architecture and secondary side feedback SSR architecture. However, no matter the primary side feedback PSR architecture or the secondary side feedback SSR architecture, the adopted power controllers all work with fixed working frequencies, and when the power circuit is in no-load, the power circuit loss is large. In the working process, the power supply controller cannot detect the working state of the power supply circuit in real time and cannot regulate and output the PWM pulse regulation and control signal according to the working state of the power supply circuit, so that the slope of the power supply voltage output by the power supply circuit meets the charging requirement and high-efficiency power supply conversion.

In addition, the battery chargers with two existing architectures have the defects of low constant voltage and constant current precision. Wherein, the SSR of the secondary feedback framework can only reach the constant current precision of about +/-5 percent and the constant voltage precision of about +/-3-5 percent. The primary side feedback framework PSR can only reach the constant current precision of about +/-10 percent and the constant voltage precision of about +/-5 percent, has no constant power function, cannot work in the working state that the constant voltage CV is 0V, has a small constant voltage CV range, cannot output small current, and cannot meet the driving requirements of a battery and a motor.

SUMMERY OF THE UTILITY MODEL

The present invention aims at solving at least one of the technical problems in the related art to a certain extent. Therefore, an object of the present invention is to provide an intelligent integrated controller and a charger having the same.

On the one hand, for realizing above-mentioned purpose, according to the utility model discloses an intelligence integrated control ware, intelligence integrated control ware includes:

the load current detection module is connected with the current detection end and used for detecting the feedback current amount when the power circuit load is loaded;

the continuous/discontinuous mode identification module is connected with the detection output end of the on-load current detection module so as to automatically detect whether the working state of the transformer of the power supply is in a continuous mode or a discontinuous mode by detecting the current amount;

the logic control module is connected with the continuous/discontinuous mode identification module so as to adjust the pulse width of the output PWM when a transformer of the power supply is in a continuous or discontinuous working state;

and the control end of the power tube is connected with the logic control module, and the collector end of the power transistor is used for being connected with the primary side of a transformer of the power circuit so as to adjust the PWM pulse of the primary current of the transformer.

Further, according to the utility model discloses an embodiment, intelligent integrated control ware still includes:

and the green energy-saving working mode identification module is respectively connected with the current detection end and the logic control end so as to reduce the PWM pulse frequency when detecting that the power supply circuit is in an idle state.

the current error detection module is connected with the on-load current detection module so as to compare and output the detected current magnitude with a current reference value;

and the current precision calibration module is connected with the current error detection module and the logic control module in decibels so as to adjust the output precision constant current PWM pulse width through a current error output value.

the voltage error detection module is connected with the voltage feedback end so as to compare and output the feedback voltage quantity with a voltage reference value;

and the voltage precision calibration module is respectively connected with the voltage error detection module and the logic control module so as to adjust the output precision constant voltage PWM pulse width through a voltage error output value.

Further, according to the utility model discloses an embodiment, intelligent integrated control ware still includes: and the line compensation module is respectively connected with the voltage feedback end and the logic control module so as to collect compensation output of the difference of the input line voltage and the inductance of the transformer.

the constant current control module is connected with the logic control module so as to output a constant current PWM pulse control signal through the logic control module;

the constant voltage control module is connected with the logic control module and outputs a constant voltage PWM pulse control signal through the logic control module;

the constant power control module is connected with the logic control module so as to output a constant power PWM pulse control signal through the logic control module;

and the working mode detection module is respectively connected with the constant current control module, the constant voltage control module, the constant power control module and the working mode control end so as to collect the setting of the working mode control end and select one of the constant current control module, the constant voltage control module and the constant power control module to control the output of the PWM pulse signal.

Further, according to the utility model discloses an embodiment, intelligent integrated control ware still includes: and the driving module is respectively connected with the logic control module and the power transistor so as to drive the power transistor after amplifying the PWM pulse power.

the high-voltage starting module is connected with a power supply end of a power supply so as to convert a high-voltage input power supply into a power supply of the controller;

and the chip power supply generation module is connected with the high-voltage starting module so as to convert a wide-range input power supply into a power supply of the controller.

Further, according to the utility model discloses an embodiment, intelligent integrated control ware still includes: the fault protection module is connected with the logic control module to output a fault signal to the logic control module;

the fault protection module comprises one or more of an overcurrent protection module, a short-circuit protection module, an over-temperature protection module and an overvoltage and undervoltage protection module.

On the other hand, the embodiment of the utility model provides a still provide an intelligent integrated power supply circuit, include:

and the alternating current-direct current conversion circuit is connected with one end of the primary coil of the transformer so as to convert the commercial power alternating current into the first direct current power supply.

One end of a primary coil of the transformer is connected with the output end of the first direct current power supply;

in the above intelligent integrated controller, the collector terminal of the power tube of the intelligent integrated controller is connected to the other end of the primary coil of the transformer;

the output filter circuit is connected with the secondary coil of the transformer so as to stabilize the voltage of the power supply output by the secondary coil of the transformer and output a second direct-current power supply;

the primary voltage feedback circuit is respectively connected with the auxiliary power supply end of the transformer and the voltage feedback end of the intelligent integrated controller, the auxiliary power supply voltage of the transformer is fed back to the intelligent integrated controller, and the width of pulse modulation is controlled through the intelligent integrated controller, so that the second direct current power supply is output in a constant voltage mode;

and the primary current feedback circuit is connected with a current feedback end of the intelligent integrated controller and feeds current back to the current feedback end of the intelligent integrated controller so as to control the width of pulse modulation through the intelligent integrated controller, and the second direct current power supply outputs constant current.

The utility model is used for detecting the feedback current amount when the load of the power circuit is loaded through the on-load current detection module; the continuous/discontinuous mode identification module automatically detects whether the working state of the transformer of the power supply is a continuous mode or a discontinuous mode by detecting the current magnitude; when a transformer of a power supply is in a continuous or discontinuous working state, the logic control module adjusts and outputs PWM pulse width and drives a power tube; to adjust the transformer primary current PWM pulses. Therefore, when the continuous/discontinuous mode identification module identifies that the power supply circuit is in the discontinuous mode, the PWM pulse width can be adjusted through the logic control module so as to ensure that the slope of the output power supply voltage meets the charging requirement. Or when the power supply circuit is identified to be in a continuous mode, the PWM pulse width can be adjusted through the logic control module, and the power supply conversion efficiency of the circuit is improved.

Drawings

Fig. 1 is a schematic diagram of an intelligent integrated power circuit provided by the present invention;

fig. 2 is a structural block diagram of the intelligent integrated controller provided by the present invention.

Reference numerals:

an AC-DC conversion circuit 10;

a transformer 20;

an output filter circuit 30;

an intelligent integrated controller 40;

a built-in high-voltage starting module 401;

a chip power generation module 402;

an operating mode detection module 403;

a constant current control module 404;

a constant voltage control module 405;

a constant power control module 406;

a voltage error detection module 407;

a voltage precision calibration module 408;

a line compensation module 409;

a green energy saving work identification module 410;

a CS on-load current detection module 411;

a DCM/CCM pattern recognition module 412;

a current precision calibration module 413;

a logic control module 414;

a drive module 415;

a fault protection module 416;

a power transistor 417;

a primary voltage feedback circuit 50;

a primary current feedback circuit 60.

The purpose of the present invention is to provide a novel and improved method and apparatus for operating a computer.

Detailed Description

In order to make the technical field person understand the scheme of the present invention better, the following will combine the drawings in the embodiments of the present invention to clearly and completely describe the technical scheme in the embodiments of the present invention. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the invention. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. It is explicitly and implicitly understood by one skilled in the art that the embodiments described herein can be combined with other embodiments.

In one aspect, referring to fig. 1 and 2, an embodiment of the present invention provides an intelligent integrated controller 40, including: the load current detection module is connected with the current detection end and is used for detecting the feedback current amount when the load of the power circuit is loaded; as shown in fig. 1 and 2, the on-load current detection module is connected to the current detection terminal to detect the feedback current amount information of the circuit, as shown in fig. 1, a resistor R2 is disposed between the power transistor 417 and the reference ground to feed the current amount of the primary coil back to the on-load current detection module, and the on-load current detection module can obtain the current amount of the output terminal when the power circuit is loaded by the current function proportional relationship between the primary coil and the secondary coil of the transformer 20.

The continuous/discontinuous mode identification module is connected with the detection output end of the on-load current detection module so as to automatically detect that the working state of the transformer 20 of the power supply is a continuous mode or a discontinuous mode through detecting the current amount; as shown in fig. 2, the continuous/discontinuous mode identification module may identify that the power circuit is in a continuous operation mode or is operating in a discontinuous operation module by the current amount detection value of the on-load current detection module.

The logic control module 414 is connected to the continuous/discontinuous mode identification module to adjust the output PWM pulse width when the transformer 20 of the power supply is in a continuous or discontinuous operating state; when the continuous/discontinuous mode identification module identifies that the power circuit is in the discontinuous mode, the PWM pulse width may be adjusted by the logic control module 414 to ensure that the slope of the output power voltage meets the charging requirement. Alternatively, when the power circuit is identified to be in the continuous mode, the PWM pulse width may be adjusted by the logic control module 414 to improve the power conversion efficiency of the circuit.

The control terminal of the power transistor is connected to the logic control module 414, and the collector terminal of the power transistor 417 is used for connecting to the primary side of the transformer 20 of the power circuit, so as to PWM pulse width of the primary current of the transformer 20. The power tube is connected between the primary coil of the transformer 20 and the reference ground, and the on-off control of the current of the primary coil of the transformer 20 is performed under the control of the PWM pulse signal. Thus, the current regulation output of the power supply circuit is realized.

The utility model is used for detecting the feedback current amount when the load of the power circuit is loaded through the on-load current detection module; the continuous/discontinuous mode identification module automatically detects whether the working state of the transformer 20 of the power supply is a continuous mode or a discontinuous mode by detecting the current amount; when the transformer 20 of the power supply is in a continuous or discontinuous working state, the logic control module 414 adjusts the output PWM pulse width and drives the power tube; to PWM the pulse width of the primary current of the transformer 20. Thus, when the continuous/discontinuous mode identification module identifies that the power circuit is in the discontinuous mode, the PWM pulse width may be adjusted by the logic control module 414 to ensure that the slope of the output power voltage meets the charging requirement. Or, when the power supply circuit is identified to be in the continuous mode, the PWM pulse width may be adjusted by the logic control module 414, so as to improve the power conversion efficiency of the circuit.

Referring to fig. 2, the intelligent integrated controller 40 further includes: and the green energy-saving working mode identification module is respectively connected with the current detection end and the logic control end so as to reduce the PWM pulse frequency when detecting that the power supply circuit is in an idle state. As shown in fig. 2, the amount of current at the current detection terminal is detected by the green energy saving operation mode identification module. Therefore, the working state of the load of the power supply circuit can be obtained, and when the load is in no load or light load, the output frequency of the PWM pulse can be adjusted to provide the overall working efficiency of the circuit. For example, in an idle state, the power supply controller reduces the number of switching cycles in a hiccup mode to improve the average working efficiency of the system; or under the light load of 10% -25%, the average working efficiency of the whole system of the power circuit is improved in a mode that the switching frequency of the power controller IC is reduced to 25-30 KHZ.

Referring to fig. 2, the intelligent integrated controller 40 further includes: a current error detection module and a current precision calibration module 413, wherein the current error detection module is connected with the on-load current detection module to compare and output the detected current quantity with a current reference value; the current precision calibration module 413 is respectively connected to the current error detection module and the logic control module 414, so as to adjust the output precision constant current PWM pulse width according to the current error output value. The feedback current amount is compared with a reference value and output through the current error detection module, so that the feedback current amount error is output to the current precision calibration module 413, and after the current output by the constant current is calibrated through the current precision calibration module 413, the constant current PWM pulse width of the output precision is adjusted. The output current of the power supply circuit is high-precision constant current output, and the output constant current precision is higher than +/-3%.

Referring to fig. 2, the intelligent integrated controller 40 further includes: the voltage error detection module 407 is connected with the voltage feedback end to compare and output the feedback voltage quantity with a voltage reference value; the voltage precision calibration module 408 is respectively connected to the voltage error detection module 407 and the logic control module 414 to adjust the output precision constant voltage PWM pulse width according to the voltage error output value. The feedback voltage amount is compared with the reference value by the voltage error detection module 407 and outputted to output the feedback voltage amount error to the voltage precision calibration module 408, and after the voltage calibration of the constant voltage output is performed by the voltage precision calibration module 408, the output precision constant voltage PWM pulse width is adjusted. The output voltage of the power supply circuit is high-precision constant-voltage output, and the precision of the output constant voltage is more than or equal to 1 percent.

Referring to fig. 2, the intelligent integrated controller 40 further includes: and the line compensation module 409, wherein the line compensation module 409 is respectively connected with the voltage feedback end and the logic control module 414 so as to collect the compensation output of the input line voltage and the inductance difference of the transformer 20. As shown in fig. 2, the line compensation module 409 compensates for the difference between the input line voltage and the inductance of the transformer 20, thus ensuring the stability of the power supply voltage.

Referring to fig. 1 and 2, the intelligent integrated control further includes: the constant current control module 404 is connected with the logic control module 414 so as to output a constant current PWM pulse control signal through the logic control module 414; the constant voltage control module 405 is connected to the logic control module 414 to output a constant voltage PWM pulse control signal through the logic control module 414; the constant power control module 406 is connected to the logic control module 414 to output a constant power PWM pulse control signal through the logic control module 414; the working mode detection module 403 is respectively connected to the constant current control module 404, the constant voltage control module 405, the constant power control module 406, and the working mode control end, so as to collect the setting of the working mode control end, and select one of the constant current control module 404, the constant voltage control module 405, and the constant power control module 406 to control the output of the PWM pulse signal. As shown in fig. 1, the operation mode control module determines the operation mode by detecting the impedance of the configuration capacitor C1 by connecting the configuration capacitor C1 between the operation mode control terminal and the reference ground. For example, the constant current control module 404, the constant voltage control module 405, or the constant power control module 406 are configured to operate so that the power circuit is in a constant current, constant voltage, or constant power mode of operation. Therefore, the power supply controller can work in a working state that the constant voltage CV is 0V, a large constant voltage CV range and a low current output state in a constant current or constant power mode, so that the driving requirements of a battery and a motor are met. That is, if the battery voltage reaches 0V, a constant voltage CV to 0V power supply can be output to charge the battery. The constant voltage CV range is wide, namely the charging voltage is 1.0V/node, namely the constant current mode loading range is wide, and the low current output <200mA can be supported. For example 70mA, 120mA or 150 mA.

Referring to fig. 2, the intelligent integrated controller 40 further includes a driving module 415, and the driving module 415 is respectively connected to the logic control module 414 and the power transistor 417 to amplify the PWM pulse power and then drive the power transistor 417. The transistors may be better driven by the driving module 415. The power tube can be driven well even if the power tube is operated in a large current state.

Referring to fig. 2, the intelligent integrated controller 40 further includes: the high-voltage starting module is connected with a power supply end of a power supply so as to convert a high-voltage input power supply into a power supply of the controller; the high-voltage starting module can convert the input high-voltage direct current into a power supply VCC of the power supply controller when the power supply controller starts to work and supply power to the power supply controller. After the power controller is started, the high-voltage starting module is closed, and the auxiliary coil of the transformer 20 supplies power. In addition, a starting power supply voltage can be introduced through a collector terminal of the power tube and is respectively pressed through the internal resistors to serve as the starting power supply voltage, so that the external resistor of the starting circuit is reduced.

The chip power supply generation module is connected with the high-voltage starting module so as to convert the wide-range input power into the power supply of the controller. The power supply controller is supplied with power voltage through the chip power supply generation module, and when the secondary output voltage is 0V, the power supply controller IC supplies power to the built-in high-voltage starting module 401 in a switching mode. The power supply controller IC is designed to have VCC power supply range of 5-50V, so as to ensure that the output constant-current voltage CV of the power supply is in a wide range.

Referring to fig. 2, the intelligent integrated controller 40 further includes: a fault protection module 416, the fault protection module 416 being connected to the logic control module 414 to output a fault signal to the logic control module 414; that is, when a fault is detected, a fault signal may be output to the logic control module 414, so as to stop outputting the PWM pulse modulation signal through the logic control module 414, so that the circuit is in a shutdown state, thereby protecting the power supply controller and the whole circuit. The fault protection module 416 includes one or more of an overcurrent protection module, a short-circuit protection module, an over-temperature protection module, and an overvoltage and undervoltage protection module. Various faults generated by the power circuit may be detected by the fault protection module 416, and when a fault occurs, the PWM signal may be controlled by the logic control module 414 by outputting a fault detection signal to the logic control module 414. For example, the power supply controller IC has an over-temperature protection function integrated therein. When the internal temperature of the power supply controller reaches 150 ℃, the thermal protection circuit acts, and the chip of the power supply controller stops working; the power controller chip modules can only resume operation when the junction temperature is below 135 degrees.

Referring to fig. 1, in another aspect, an embodiment of the present invention further provides an intelligent integrated power circuit, including: the intelligent integrated controller comprises an alternating current-direct current conversion circuit 10, a transformer 20, the intelligent integrated controller 40, an output filter circuit 30, a primary voltage feedback circuit 50 and a primary current feedback circuit 60, wherein the alternating current-direct current conversion circuit 10 is connected with one end of a primary coil of the transformer 20 so as to convert commercial power alternating current into first direct current power.

One end of the primary coil of the transformer 20 is connected with the output end of the first direct current power supply; the transformer 20 performs pulse regulation on the first direct current power supply and then transforms the voltage to be output.

The collector terminal of the power tube of the intelligent integrated controller 40 is connected with the other end of the primary coil of the transformer 20; the power tube pulse width modulates the current on the transformer 20.

The output filter circuit 30 is connected to the secondary coil of the transformer 20 to stabilize the voltage of the power supply output from the secondary coil of the transformer 20 and output a second direct current power supply; the output filter circuit 30 filters the pulse voltage output from the transformer 20 and outputs the filtered pulse voltage to output a stable second direct current.

The primary voltage feedback 50 circuit is respectively connected with the auxiliary power supply end of the transformer 20 and the voltage feedback end of the intelligent integrated controller, and feeds the auxiliary power supply voltage of the transformer 20 back to the intelligent integrated controller 40, so that the intelligent integrated controller 40 controls the width of pulse modulation, and the second direct current power supply is output in a constant voltage mode; the primary current feedback circuit is connected with a current feedback end of the intelligent integrated controller 40, and feeds current back to the current feedback end of the intelligent integrated controller, so that the width of pulse modulation is controlled through the intelligent integrated controller 40, and the second direct current power supply is output in a constant current mode. As shown in fig. 1, the primary current and voltage of the transformer 20 can be fed back to the power supply controller through the primary voltage feedback circuit 50 and the primary current feedback circuit 60, so as to perform constant current and constant voltage output through the power supply controller.

The utility model discloses implement the intelligent integrated power supply circuit who provides, when continuous/discontinuous mode identification module discernment power supply circuit is in discontinuous mode, accessible logic control module 414 adjusts PWM pulse width to guarantee that output power supply voltage slope satisfies the requirement of charging. Or, when the power supply circuit is identified to be in the continuous mode, the PWM pulse width may be adjusted by the logic control module 414, so as to improve the power conversion efficiency of the circuit.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The above only be the preferred embodiment of the utility model discloses a not consequently restriction the utility model discloses a patent range, all are in the utility model discloses a conceive, utilize the equivalent structure transform of what the content was done in the description and the attached drawing, or direct/indirect application all is included in other relevant technical field the utility model discloses a patent protection within range.

Claims

1. An intelligent integrated controller, comprising:

2. The intelligent integrated controller of claim 1, further comprising:

3. The intelligent integrated controller of claim 1, further comprising:

4. The intelligent integrated controller of claim 3, further comprising:

5. The intelligent integrated controller of claim 4, further comprising: and the line compensation module is respectively connected with the voltage feedback end and the logic control module so as to compensate and output the difference between the input line voltage and the inductance of the transformer.

6. The intelligent integrated controller of claim 4, further comprising:

7. The intelligent integrated controller of claim 1, further comprising: and the driving module is respectively connected with the logic control module and the power transistor so as to drive the power transistor after amplifying the PWM pulse power.

8. The intelligent integrated controller of claim 1, further comprising:

9. The intelligent integrated controller of claim 1, further comprising: the fault protection module is connected with the logic control module to output a fault signal to the logic control module;

10. An intelligent integrated power supply circuit, comprising:

one end of a primary coil of the transformer is connected with the output end of the first direct-current power supply;

an ac-dc conversion circuit connected to the one end of the primary coil of the transformer to convert the commercial power ac into the first dc power supply;

the intelligent integrated controller of any one of claims 1 to 9, wherein a collector terminal of a power tube of the intelligent integrated controller is connected with the other end of the primary coil of the transformer;