CN214376077U - Device with freely adjustable power of micro heating chip - Google Patents

Abstract

The invention discloses a device with freely adjustable power of a micro heating chip. The method for freely adjusting the power of the micro heating chip comprises the following steps: the device comprises an auxiliary power supply circuit, a main control chip circuit, an electrical isolation circuit, a buffer protection circuit, a power supply chip circuit and a micro heating chip. And a sampling resistor is arranged at the position of the micro heating chip for overcurrent protection. The invention utilizes the low-voltage control circuit and the high-voltage regulating circuit to form a parallel structure to replace the power supply mode of the traditional series structure, thereby not only realizing safer and more stable power supply to the micro heating chip end, but also improving the overall efficiency of the power supply of the device; the main control chip circuit and the power supply chip circuit are electrically isolated through the electrical isolation circuit, low-voltage control high voltage is achieved, the voltage of the micro heating chip end can be adjusted between 0V and 220V, and therefore the micro heating chip can achieve controllable change of heating temperature under different powers.

Description

Device with freely adjustable power of micro heating chip

Technical Field

The invention provides a device with freely adjustable power of a micro heating chip.

Background

The power supply of the control panel of each electronic circuit is basically direct current power supply, such as low voltage direct current power supply output by rectifying an alternating current power supply, or battery power supply. At present, an adjustable direct current voltage source on the market is generally in a low-voltage range of 0-12V or 0-30V, a DC-DC conversion circuit or a low dropout linear regulator (LDO) is adopted to realize the voltage reduction or the voltage boosting of a direct current input power supply, and then the micro heating chip is supplied with power. In addition, as in the power topology shown in fig. 1, when the current series low-voltage range adjustable dc power supply in the market works at a low voltage, the overall efficiency of the system power supply is not high.

Micro-heating chips often play a crucial role for the field of gas sensors. Since activation energy is often required for various gas sensitive materials to react with a target gas, the degree of response of each gas sensor node is very dependent on the operating temperature. When the working temperature is too low, the gas response is also low, and when the working temperature is too high, the sintering effect of the gas-sensitive material can be caused, and the gas-sensitive characteristic is influenced. In general, in a gas sensor experiment, the working temperature of each sensor node is controlled by setting the distance between each sensor node and a micro heating chip, but the method is complicated in operation and poor in precision. The invention can provide a method for freely adjusting the power of a micro heating chip, and the micro heating chip can work in different powers to generate different temperature environments by regulating and controlling the power supply voltage of a power supply; in addition, for the method for freely adjusting the power of the micro heating chip, under the condition of wide-range adjustable voltage, the power efficiency can be ensured no matter low voltage or high voltage is used.

Disclosure of Invention

The invention provides a method for freely adjusting the power of a micro heating chip. The method and the device enable the control circuit to work in a low-voltage state and control the high-voltage circuit through electrical isolation, enable the driving circuit to work normally through the buffer protection circuit, and automatically close the circuit once the current of the micro heating chip end exceeds 3A.

The technical scheme adopted by the invention is as follows:

a method for freely adjusting the power of a micro heating chip is characterized by comprising the following steps: the device comprises an auxiliary power supply circuit, a main control chip circuit, an electrical isolation circuit, a buffer protection circuit, a power supply chip circuit and a micro heating chip. The auxiliary power supply circuit and the main control chip circuit form a low-voltage control circuit, and the buffer protection circuit and the power supply chip circuit form a high-voltage regulating circuit. The external alternating current power supply is connected with the auxiliary power supply circuit and the input end of the buffer protection circuit to provide power; the output end of the auxiliary power supply circuit is connected with the input end of the main control chip circuit, the output end of the main control chip circuit is connected with the enabling end of the power supply chip circuit through an electrical isolation circuit, and the electrical isolation circuit can ensure the safety and reliability of the main control chip circuit for regulating and controlling the power supply chip circuit; the output end of the buffer protection circuit is connected with the input end of the power chip circuit, and the output end of the power chip circuit is connected with the micro heating chip. And the micro heating chip is provided with a sampling resistor for performing overcurrent protection on a power chip circuit.

Furthermore, in the method for freely adjusting the power of the micro heating chip, the circuit where the main control chip circuit is located is a low-voltage control circuit, the circuit where the power chip circuit is located is a high-voltage adjustable circuit, and the main control chip circuit and the power chip circuit are electrically isolated by an isolation circuit; the main components in the electric isolation circuit are a precision isolation amplifier and an optical coupling isolation module, so that the safety and reliability of the low-voltage control circuit for regulating and controlling the high-voltage adjustable circuit can be ensured.

Further, in the method for freely adjusting the power of the micro heating chip, the auxiliary power circuit includes a full-bridge rectification filter circuit and a Buck chopper circuit, wherein the Buck chopper circuit is a Buck circuit and is used for obtaining appropriate voltage and current supply.

Further, in the method for freely adjusting the power of the micro heating chip, the main control chip circuit includes a main control chip, a key circuit, a display circuit, a digital-to-analog converter and a dual operational amplifier. The main control chip circuit can realize the numerical control function of the high-voltage regulating circuit through the electrical isolation circuit in a stable low-voltage environment.

Further, in the above method for freely adjusting the power of the micro heating chip, the buffer protection circuit includes a power control chip including a full-bridge rectification filter circuit and a high-power capacitor buffer circuit. Wherein, a fuse is arranged at the rectifier bridge of the full-bridge rectifier filter circuit for current protection; the high-power capacitor and the operational amplifier circuit are used in the high-power capacitor buffer circuit to avoid direct impact of larger voltage and current.

Further, in the above method for freely adjusting the power of the micro heating chip, the power chip circuit includes a power chip circuit including a switching power supply pulse width modulation control chip and an electronic switching circuit. The electronic switch circuit comprises an IGBT driving chip and an IGBT module. When the current at the end of the micro heating chip exceeds 3A, the power chip circuit is turned off and output through overcurrent protection.

Further, in the method for freely adjusting the power of the micro heater chip, the method further includes: the external alternating current power supply is commercial power 220V alternating current.

According to the technical scheme of the embodiment of the invention, the driving circuit is connected in parallel, so that the overall efficiency of the system power supply can be ensured when the micro heating chip end works in a low-voltage state. In addition, the electric isolation between the control circuit and the driving circuit can effectively improve the reliability and the safety of the power circuit, and the cooperation between the control circuit and the driving circuit can effectively realize that the system circuit can work in the voltage range of 0-220V.

Drawings

Fig. 1 shows a schematic structure of a conventional power supply circuit;

FIG. 2 is a schematic structural diagram illustrating a method for freely adjusting power of a micro heater chip according to an embodiment of the present invention;

Detailed Description

The method 100 for freely adjusting the power of the micro heating chip, which is combined with the embodiment shown in fig. 2, includes an auxiliary power circuit 10, a main control chip circuit 20, an electrical isolation circuit 30, a buffer protection circuit 40, a power chip circuit 50, and a micro heating chip 60. The auxiliary power circuit 10 and the main control chip circuit 20 form a low-voltage control circuit, and the buffer protection circuit 40 and the power chip circuit 50 form a high-voltage regulation circuit.

The main control chip circuit 20 is electrically isolated from the power chip circuit 50 through the electrical isolation circuit 30; the main components in the electrical isolation circuit 30 are a precision isolation amplifier and an optical coupling isolation module, which can ensure the safety and reliability of the main control chip circuit 20 for regulating and controlling the power chip circuit 50.

The external alternating current power supply is connected with the auxiliary power supply circuit 10 and the input end of the buffer protection circuit 40 to provide power; the output end of the auxiliary power supply circuit 10 is connected with the input end of the main control chip circuit 20, the output end of the main control chip circuit 20 is connected with the enabling end of the power supply chip circuit 50 through the electrical isolation circuit 30, and the electrical isolation circuit 30 can ensure the safety and reliability of the main control chip circuit 20 in regulating and controlling the power supply chip circuit 50; the output end of the buffer protection circuit 40 is connected to the input end of the power chip circuit 50, and the output end of the power chip circuit 50 is used for connecting the micro heating chip 60.

The low-voltage control circuit comprises an auxiliary power supply circuit 10 and a main control chip circuit 20.

The auxiliary power circuit 10 comprises a full-bridge rectification filter circuit and a step-down chopper circuit, wherein the full-bridge rectification filter circuit is used for converting alternating current into relatively stable direct current; the voltage-reducing chopping circuit is a Buck circuit and is used for obtaining proper voltage and current supply. The auxiliary power circuit 10 not only supplies power to the main control chip circuit 20, but also ensures that the input terminal of the main control chip circuit 20 does not directly contact the high-voltage circuit, thereby ensuring the normal operation of the main control chip circuit 20. In addition, in order to avoid the possible influence of the fluctuation of the input power grid voltage on the circuit, a voltage stabilizing module can be added to further ensure the safety and reliability of voltage and current supply.

The main control chip circuit 20 includes a main control chip, a key circuit, a display circuit, a digital-to-analog converter and a dual operational amplifier. The invention realizes the numerical control function, namely after an operator inputs a specified voltage value, the input end of the micro heating chip can reach corresponding voltage, and the matrix type keyboard is adopted to design a corresponding key circuit because the numerical values are different and the span is larger. The required voltage value is input through the key circuit, the voltage value can be checked and confirmed in a display screen of the display circuit, and after the main control chip receives a signal, an instruction is transmitted to the digital-to-analog converter and the double operational amplifier and is input to the enabling end of the power chip circuit 50 through the electric isolation circuit 30.

The high voltage regulator circuit includes a buffer protection circuit 40 and a power chip circuit 50.

The buffer protection circuit 40 includes a full bridge rectifier filter circuit and a high power capacitor buffer circuit. The high-power capacitor buffer circuit is protected by the high-power capacitor, and the power chip circuit 50 is prevented from being burnt due to overlarge current at the moment of starting. Because the external alternating current power supply is the commercial power 220V alternating current, the voltage peak value in the buffer protection circuit 40 can reach 310V, and even a high-power capacitor is difficult to bear larger voltage and current for direct impact. Therefore, the buffer protection circuit 40 is added with an operational amplifier circuit, so that the high-power capacitor is prevented from being damaged due to direct impact of larger voltage and current. When the charging of the large capacitor in the buffer protection circuit 40 is completed, that is, the voltage in the buffer protection circuit 40 reaches about 310V, the operational amplifier circuit is turned on, and the buffer protection circuit 40 starts to supply power to the power chip circuit 50. In addition, in order to realize the overcurrent protection of the circuit, a fuse is arranged at the rectifier bridge in the full-bridge rectifier filter circuit, and if the voltage and the current are too high, the fuse can be burnt out and disconnected, so that the buffer protection circuit 40 stops working.

The power chip circuit 50 comprises a switching power supply pulse width modulation control chip and an electronic switching circuit. The electronic switch circuit comprises an IGBT driving chip and an IGBT module.

Because the switching power supply pulse width modulation control chip is used for fixedly outputting a certain voltage value in general use, but the voltage value is required to be adjustable in the invention, in the specific use of the switching power supply pulse width modulation control chip, some specific pin functions are changed to adapt to the requirements of the design.

The switching power supply pulse width modulation control chip is connected with the main control chip circuit 20 through the electric isolation circuit 30, and the main control chip circuit 20 controls output, so that the problem of fixed output of the switching power supply pulse width modulation control chip is solved. The switching power supply pulse width modulation control chip is connected with the electronic switching circuit through the protective resistor to carry out signal transmission. And the reference voltage is used as a reference value to be compared with the voltage value fed back by the micro heating chip 60 end through the sampling resistor, so that the effect of reasonably protecting the normal work of the power supply chip is achieved.

The electronic switch circuit comprises an IGBT driving chip and an IGBT module. Although the IGBT has the characteristics of high frequency, small on-resistance and the like as an electronic switch, because the IGBT has poor overcurrent resistance, in the invention, in order to realize overcurrent protection of the power chip circuit 50, a low-resistance resistor is connected from the end of the micro heating chip 60 as a sampling resistor, and the sampling resistor transmits a current signal to the switching power supply pulse width modulation control chip. When the current of the sampling resistor reaches 3A, an error amplifier in the pulse width modulation control chip of the switching power supply starts to work, and at the moment, if the current on the sampling resistor is increased, the pulse width modulation control chip of the switching power supply reduces the duty ratio through PWM until the output is completely closed, so that overcurrent protection is realized.

The above examples are merely illustrative of one embodiment of the present invention, and the description is more specific and detailed, but should not be construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention.

Claims (6)

1. A device with freely adjustable power of a micro heating chip is characterized by comprising: the device comprises an auxiliary power supply circuit, a main control chip circuit, an electrical isolation circuit, a buffer protection circuit, a power supply chip circuit and a micro heating chip; the auxiliary power supply circuit and the main control chip circuit form a low-voltage control circuit, and the buffer protection circuit and the power supply chip circuit form a high-voltage regulating circuit; the external alternating current power supply is connected with the auxiliary power supply circuit and the input end of the buffer protection circuit to provide power; the output end of the auxiliary power supply circuit is connected with the input end of the main control chip circuit, the output end of the main control chip circuit is connected with the enabling end of the power supply chip circuit through an electrical isolation circuit, and the electrical isolation circuit can ensure the safety and reliability of the main control chip circuit for regulating and controlling the power supply chip circuit; the output end of the buffer protection circuit is connected with the input end of the power chip circuit, and the output end of the power chip circuit is connected with the micro heating chip; and the micro heating chip is provided with a sampling resistor for performing overcurrent protection on a power chip circuit.

2. The device of claim 1, wherein the circuit of the main control chip is a low voltage control circuit, the circuit of the power chip is a high voltage adjustable circuit, and the main control chip circuit and the power chip circuit are electrically isolated by an electrical isolation circuit; the main components in the electric isolation circuit are a precision isolation amplifier and an optical coupling isolation module, so that the safety and reliability of the main control chip circuit for regulating and controlling the power chip circuit can be ensured.

3. The device of claim 1, wherein the auxiliary power circuit comprises a full-bridge rectification filter circuit and a Buck chopper circuit, and the Buck chopper circuit is a Buck circuit for obtaining a suitable voltage and current supply.

4. The device for freely adjusting the power of a micro heating chip according to claim 1, wherein the main control chip circuit comprises a main control chip, a key circuit, a display circuit, a digital-to-analog converter and a dual operational amplifier; the main control chip circuit can realize the numerical control function of the high-voltage regulating circuit through the electrical isolation circuit in a stable low-voltage environment.

5. The device for freely adjusting the power of the micro heating chip according to claim 1, wherein the buffer protection circuit comprises a power control chip, a full-bridge rectification filter circuit and a high-power capacitor buffer circuit; wherein, a fuse is arranged at the rectifier bridge of the full-bridge rectifier filter circuit for overcurrent protection; the high-power capacitor and the operational amplifier circuit are used in the high-power capacitor buffer circuit to avoid direct impact of larger voltage and current.

6. The micro heating chip power freely adjustable device according to claim 1, wherein the power chip circuit comprises a switching power supply pulse width modulation control chip, an electronic switching circuit; the electronic switch circuit comprises an IGBT driving chip and an IGBT module; when the current at the end of the micro heating chip exceeds 3A, the power chip circuit is turned off and output through overcurrent protection.

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