KR101435631B1 - Parallel interconnection circuit device of switching mode power supply equipment, and control method - Google Patents

Abstract

The present invention relates to a parallel interconnection circuit device of switching mode power supply equipment, and a control method thereof. A parallel interconnection circuit device of switching mode power supply equipment according to one embodiment of the present invention includes an SMPS connection part (100) which comprises a first SMPS board (110) and a second SMPS board (120); a potential difference generation part (200) which is connected in parallel to the output terminals of the first SMPS board (110) and the second SMPS board (120); a relay (300); and a microcomputer (400).

Description

TECHNICAL FIELD [0001] The present invention relates to a parallel connection circuit device of a switching mode power supply device, and a control method thereof. BACKGROUND OF THE INVENTION [0002]

More particularly, the present invention relates to a parallel connection circuit device of a switching mode power supply device and more particularly to a method and a device for connecting two single SMPS (Switching Mode Power Supply) To a parallel-connected circuit device of a switching-mode power supply device and a control method thereof.

Generally, a switching mode power supply unit (SMPS) switches a switching device according to a signal having a pulse width modulated to generate a good quality power source in which a ripple component is removed, thereby supplying power Power supply.

1 is a schematic functional block diagram of a conventional switching mode power supply device (SMPS). 1, the conventional switching mode power supply apparatus 10 includes a rectifying circuit section 11 that rectifies an input AC to convert it to a DC voltage and outputs the rectified DC voltage, A transformer 13 for transforming the power supplied from the power source switch circuit portion 12 in proportion to the turns ratio of the primary and secondary coils, And a rectified output unit 14 for outputting a constant voltage through rectification and smoothing of the induced AC power.

When the conventional SMPS is not designed with sufficient power, there are cases where two identical SMPS boards are connected in parallel. However, when the SMPS boards are used in parallel, Because it is very low and uses the output voltage as feedback, if the output voltage of two SMPS boards is not set very precisely, the output voltage will flow from high to low. In order to solve this problem, in the conventional method, two diodes or resistors are used to solve the problem. However, in such a method, a large amount of current flows into the diode or the resistor, which causes a problem that large heat is generated in the device. In order to solve such a heat generation problem, there is a problem that a heat sink must be installed, resulting in an additional cost and a size of the system.

The present invention has been proposed in order to solve the above-mentioned problems of the previously proposed methods, in which two single SMPS boards are connected in parallel and the output of both ends of the potential difference generating unit connected in parallel to the output terminals of two SMPS boards The output voltage of the two single SMPS boards is controlled to be the same output voltage without generating a potential difference at both ends by judging which one of the detected output voltages is higher, A parallel connection circuit device of a switching mode power supply device and a control method thereof for enabling the output voltage of the SMPS boards to be output in the same manner as well as solving the thermal problem occurring in a conventional SMPS parallel connection circuit structure And the like.

In addition, according to the present invention, the output voltages of two SMPS boards are controlled to be the same through the microcomputer, and the parallel connection of the output terminals of the two SMPS boards is connected via the relay only when there is no potential difference, Another object of the present invention is to provide a parallel connection circuit device of a switching mode power supply device and a control method thereof, which can solve the problem that the heat sink required in the circuit structure is removed and the size of the system is increased.

According to an aspect of the present invention, there is provided a parallel-connected circuit device of a switching-

A parallel-connected circuit arrangement of a switching mode power supply,

An SMPS connection unit having a first SMPS board and a second SMPS board, respectively, and configuring an output terminal of the first SMPS board and an output terminal of the second SMPS board in parallel connection;

The first output voltage of the first SMPS board and the second output voltage of the second SMPS board are connected in parallel to the output terminals of the first SMPS board and the second SMPS board, A potential difference generating unit for generating a potential difference;

A relay connected in parallel to the output terminals of the first SMPS board and the second SMPS board and turned on / off so that the output terminals of the first SMPS board and the second SMPS board are connected in parallel; And

And a first output voltage of the first SMPS board and a second output voltage of the second SMPS board are respectively measured and detected, and the first SMPS board and the second SMPS board are connected to both ends of the potential difference generating unit, And a microcomputer for outputting an output voltage control signal to one of the first SMPS board and the second SMPS board such that the first and second output voltages of the board are equal to each other.

Preferably, the SMPS connection comprises:

(+) Output terminal of the first SMPS board and the (+) output terminal of the output terminal of the second SMPS board are connected in parallel to be connected to the load (LOAD_ +), (-) output terminal of the second SMPS board and the (-) output terminal of the second SMPS board may be connected in parallel to be connected to the load LOAD_-.

Preferably, the potential difference generating unit includes:

And a resistor R connected in parallel between a (+) output terminal of the first SMPS board and a (+) output terminal of the second SMPS board.

Preferably, the relay includes:

And may be connected in parallel with the potential difference generating unit at a rear end of the potential difference generating unit.

More preferably, the relay includes:

The first SMPS board and the second SMPS board are turned off so that the output terminals of the first SMPS board and the second SMPS board are interrupted when there is a potential difference between the first output voltage of the first SMPS board and the second output voltage of the second SMPS board can do.

More preferably, the relay includes:

The output terminal of the first SMPS board and the output terminal of the second SMPS board are connected in parallel if the first output voltage of the first SMPS board and the second output voltage of the second SMPS board have the same voltage without a potential difference, . ≪ / RTI >

Preferably, the microcomputer includes:

A first ADC connected to an output terminal side of the first SMPS board of the potential difference generating unit to measure and detect a voltage of an output terminal of the first SMPS board and convert the detected voltage into a digital value; And

And a second ADC connected to the output terminal side of the second SMPS board of the potential difference generating unit to measure and detect the voltage of the output terminal of the second SMPS board and convert the detected voltage into a digital value.

More preferably, the microcomputer includes:

And determines whether the output voltage of the first output voltage of the first SMPS board and the output voltage of the second SMPS board of the second SMPS board are higher by comparing the converted digital values detected by the first ADC and the second ADC And output voltage control signals for lowering the output voltage of the output voltage to a corresponding one of the first SMPS board and the second SMPS board.

More preferably, the microcomputer further comprises:

And control is performed so that a potential difference between the first output voltage of the first SMPS board and the second output voltage of the second SMPS board is not generated.

Still more preferably, the microcomputer further comprises:

When the first output voltage of the first SMPS board and the second output voltage of the second SMPS board are determined to be the same value, the relay is controlled to be turned on so that the output terminal of the first SMPS board, 2 It is possible to control the output terminal of SMPS board to be connected in parallel.

According to an aspect of the present invention, there is provided a method of controlling a parallel-connected circuit device of a switching-

A method of controlling a parallel-connected circuit device of a switching mode power supply device,

(1) a first output voltage and a second output voltage at both ends of a potential difference generating section connected in parallel between an output terminal of the first SMPS board and a second SMPS board, which are configured by the microcomputer in parallel connection, step;

(2) determining whether the output voltage of the microcomputer is higher than a first output voltage of the first SMPS board and a second output voltage of the second SMPS board;

(3) outputting an output voltage control signal for lowering the output voltage of the microcomputer to a higher output voltage to a corresponding SMPS board of the first SMPS board and the second SMPS board; And

(4) The microcomputer controls the relay to be turned on when the first output voltage and the second output voltage detected at both ends of the potential difference generating unit are equal to each other without generating a potential difference, And connecting the output terminals of the second SMPS board in parallel and connecting them.

Preferably, the potential difference generating unit includes:

And a resistor R connected in parallel between an output terminal of the first SMPS board and an output terminal of the second SMPS board.

Preferably, in the step (2)

Converting the first output voltage and the second output voltage measured and detected in step (1) into a digital value using a first ADC and a second ADC, each of which comprises an internal functional block of the microcomputer, have.

Preferably, in the step (3)

Wherein the microcomputer controls output of an output voltage control signal to the SMPS board so that the output voltage of the microcomputer is lowered to a higher output voltage, wherein the first output voltage of the first SMPS board and the second output voltage of the second SMPS board And controlling the output voltage to be maintained until a potential difference is not generated.

Preferably, in the step (4)

Wherein when the microcomputer has a potential difference between a first output voltage and a second output voltage detected at both ends of the potential difference generating unit, the relay is controlled to maintain an off state so that an output terminal of the first SMPS board, 2 The parallel connection of the output terminals of the SMPS board can be interrupted.

Preferably, the first SMPS board and the second SMPS board are connected in parallel,

(+) Output terminal of the first SMPS board and the (+) output terminal of the output terminal of the second SMPS board are connected in parallel to be connected to the load (LOAD_ +), (-) output terminal of the second SMPS board and the (-) output terminal of the output terminal of the second SMPS board are connected in parallel to be connected to the load (LOAD_-).

More preferably, the connection of the parallel connection of the resistor (R)

One end of the resistor R of the potential difference generating unit is connected to the positive output terminal of the first SMPS board and the other end of the resistor R is connected between the positive output terminals of the second SMPS board, .

Even more preferably,

And a parallel connection is made to the potential difference generating unit at a rear end of the potential difference generating unit.

Preferably, the microcomputer includes:

The first output voltage of the first SMPS board and the second output voltage of the second SMPS board are detected and compared, and the first output voltage and the second output voltage are detected using the corresponding first and second ADCs And converting and comparing the digital values.

More preferably, the microcomputer includes:

A method of comparing the first output voltage and the second output voltage with the digital conversion values of the first ADC and the second ADC to determine which one of the output voltages is higher and lowering the output voltage of the higher output voltage And outputting an output voltage control signal to a corresponding one of the first SMPS board and the second SMPS board.

According to the parallel connection circuit device and the control method thereof of the switching mode power supply device proposed in the present invention, two single SMPS boards are connected in parallel and connected to the output terminals of two SMPS boards, The output voltage of the two single SMPS boards is controlled by measuring the output voltage through the microcomputer and judging which output voltage of the detected output voltage is high so that the potential difference between the two ends is not generated and the same output voltage is obtained, In addition to allowing the output voltages of two SMPS boards to be matched and output, it is possible to solve the thermal problems that arise in the conventional SMPS parallel circuit structure.

In addition, according to the present invention, the output voltages of two SMPS boards are controlled to be the same through the microcomputer, and the parallel connection of the output terminals of the two SMPS boards is connected via the relay only when there is no potential difference, It is possible to solve the problem that the required heat sink is removed from the connection circuit structure and the size of the system is increased.

1 is a schematic functional block diagram of a conventional switching mode power supply device (SMPS);
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a switching power supply apparatus,
3 is a circuit diagram of a parallel connection circuit device of a switching mode power supply device according to an embodiment of the present invention.
4 is a diagram illustrating an internal configuration of a microcomputer in a parallel connection circuit device of a switching mode power supply apparatus according to an embodiment of the present invention.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a switching power supply apparatus,

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, in order that those skilled in the art can easily carry out the present invention. In the following detailed description of the preferred embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In the drawings, like reference numerals are used throughout the drawings.

In addition, in the entire specification, when a part is referred to as being 'connected' to another part, it may be referred to as 'indirectly connected' not only with 'directly connected' . Also, to "include" an element means that it may include other elements, rather than excluding other elements, unless specifically stated otherwise.

FIG. 2 is a functional block diagram illustrating a configuration of a parallel connection circuit device of a switching mode power supply device according to an embodiment of the present invention. FIG. 3 is a circuit diagram of a parallel connection circuit of a switching mode power supply device according to an embodiment of the present invention. FIG. 4 is a diagram illustrating an internal configuration of a microcomputer in a parallel connection circuit device of a switching mode power supply apparatus according to an embodiment of the present invention. Referring to FIG. 2 and 3, a parallel connection circuit device of a switching mode power supply device according to an embodiment of the present invention includes an SMPS connection unit 100, a potential difference generation unit 200, a relay 300, (400).

The SMPS connection unit 100 includes a first SMPS board 110 and a second SMPS board 120. The output terminals of the first SMPS board 110 and the output terminals of the second SMPS board 120 are connected in parallel Connection. More specifically, the (+) output terminal 111 of the output terminal of the first SMPS board 110 and the (+) output terminal 121 of the output terminal of the second SMPS board 120 (-) output terminal 112 of the output terminal of the first SMPS board 110 and the output terminal (-) of the output terminal of the second SMPS board 120 are connected to the load LOAD_ + Terminals 122 are connected in parallel to be connected to the load LOAD_-.

The potential difference generating unit 200 is connected in parallel to the output terminals of the first SMPS board 110 and the second SMPS board 120. The first output voltage of the first SMPS board 110 and the first output voltage of the second SMPS board 120 The second output voltage of the second comparator can be measured. 3, the potential difference generating unit 200 is connected between the (+) output terminal 111 of the first SMPS board 110 and the (+) output terminal 121 of the second SMPS board 120 And a resistor R connected in parallel to each other.

The relay 300 is connected in parallel to the output terminals of the first SMPS board 110 and the second SMPS board 120 and the output terminals of the first SMPS board 110 and the second SMPS board 120 are connected in parallel (On / Off). The relay 300 is connected in parallel with the potential difference generating unit 200 at the rear end of the potential difference generating unit 200 and connected to the first output voltage of the first SMPS board 110 and the second output voltage of the second SMPS board 120 If there is a potential difference between the voltages, the first SMPS board 110 and the second SMPS board 120 are turned off so as to be interrupted. The relay 300 is connected between the first SMPS board 110 and the second SMPS board 120 when the first output voltage of the first SMPS board 110 and the second output voltage of the second SMPS board 120 are the same voltage, And the output terminal of the board 120 is turned on so as to be connected in parallel.

The microcomputer 400 is connected to both ends of the potential difference generating unit 200 and measures a first output voltage of the first SMPS board 110 and a second output voltage of the second SMPS board 120 And outputs an output voltage control signal to the first SMPS board 110 and the second SMPS board 120 so that the first and second output voltages of the first and second SMPS boards 110 and 120 are equal to each other, Or the like. 4, the microcomputer 400 is connected to the output terminal side of the first SMPS board 110 of the potential difference generation unit 200 to measure the voltage of the output terminal of the first SMPS board 110 A first ADC 401 for converting the output of the first SMPS board 120 into a digital value after detecting the first SMPS board 120 and then converting the digital value into a digital value; And a second ADC 402 for measuring and detecting a voltage and converting the voltage to a digital value.

The microcomputer 400 compares the converted digital values detected by the first ADC 401 and the second ADC 402 and outputs the first output voltage of the first SMPS board 110 and the second output voltage of the second SMPS board 120, Of the second output voltage of the second transistor Q1 is high. Then, an output voltage control signal for lowering the output voltage of the output voltage is output to the corresponding SMPS board of the first SMPS board 110 and the second SMPS board 120. Here, the microcomputer 400 controls the first and second SMPS boards 110 and 120 so that a potential difference between the first output voltage of the first SMPS board 110 and the second output voltage of the second SMPS board 120 is not generated. When the first output voltage of the first SMPS board 110 is equal to the second output voltage of the second SMPS board 120, the microcomputer 400 turns on the relay 300 So that the output terminal of the first SMPS board 110 and the output terminal of the second SMPS board 120 are connected in parallel and controlled.

5 is a flowchart illustrating a method of controlling a parallel connection circuit device of a switching mode power supply apparatus according to an embodiment of the present invention. As shown in FIG. 5, a method of controlling a parallel-connected circuit device of a switching-mode power supply according to an embodiment of the present invention includes the steps of measuring and detecting a first output voltage and a second output voltage at both ends of a potential- In operation S110, it is determined whether the output voltage of the first output voltage or the second output voltage is high (S120). The output voltage control signal is output-controlled to the corresponding SMPS board having a high output voltage If the first output voltage and the second output voltage are equal to each other without generating a potential difference, control is performed such that the relay is turned on so that the first output voltage and the second output voltage are connected in parallel and connected (S140). Here, as a control method in the parallel connection circuit device of the switching mode power supply device according to the present invention, reference is made to the parallel connection circuit device shown in FIG. 2 to FIG.

In step S110, the microcomputer 400 is connected in parallel between the output terminal of the first SMPS board 110 and the output terminal of the second SMPS board 120, And the output voltage and the second output voltage are respectively measured and detected. The potential difference generating unit 200 may include a resistor R connected in parallel between an output terminal of the first SMPS board 110 and an output terminal of the second SMPS board 120.

In step S120, the microcomputer 400 determines whether the output voltage of the first output voltage of the first SMPS board 110 and the output voltage of the second output voltage of the second SMPS board 120 are high. In this step S120, the first output voltage and the second output voltage measured and detected in step S110 are converted into digital values using the first ADC 401 and the second ADC 402, which are internal function blocks of the microcomputer 400, Into a predetermined format.

In step S130, the microcomputer 400 outputs an output voltage control signal for lowering the output voltage of the output voltage of the microcomputer 400 to a corresponding one of the first SMPS board 110 and the second SMPS board 120 Output can be controlled. In this step S130, the microcomputer 400 outputs and controls an output voltage control signal for lowering the output voltage of the higher output voltage to the corresponding SMPS board. In this case, the first output voltage of the first SMPS board 110 And controlling the second output voltage of the second SMPS board 120 to be maintained until a potential difference is not generated.

In step S140, if the first output voltage and the second output voltage detected at both ends of the potential difference generating section 200 are equal to each other without generating a potential difference, the microcomputer 400 controls the relay 300 to be turned on, The output terminal of the SMPS board 110 and the output terminal of the second SMPS board 120 are connected in parallel. Here, in step S140, when the microcomputer 400 has a potential difference between the first output voltage and the second output voltage detected at both ends of the potential difference generation unit 200, the relay 300 is controlled to maintain the off state So that the parallel connection of the output terminal of the first SMPS board 110 and the output terminal of the second SMPS board 120 is interrupted.

The present invention may be embodied in many other specific forms without departing from the spirit or essential characteristics of the invention.

100: SMPS connection part 110: 1st SMPS board
120: second SMPS board 200: potential difference generator
300: Relay 400: Microcomputer
401: first ADC 402: second ADC
S110: a step of measuring and detecting the first output voltage and the second output voltage at both ends of the potential difference generating unit, respectively
S120: a step of determining which of the output voltages of the measured values of the first output voltage and the second output voltage is high
S130: controlling the output voltage control signal to the corresponding SMPS board having a high output voltage
Step S140: If the first output voltage and the second output voltage are equal to each other without generating a potential difference, control is performed so that the relays are turned on so as to be connected in parallel

Claims (20)

A parallel-connected circuit arrangement of a switching mode power supply,
The SMPS 100 having the first SMPS board 110 and the second SMPS board 120 and configuring the output terminal of the first SMPS board 110 and the output terminal of the second SMPS board 120 in parallel connection, A connection part 100;
The first SMPS board 110 and the second SMPS board 120 are connected in parallel to the output terminals of the first SMPS board 110 and the second SMPS board 120. The first output voltage of the first SMPS board 110, A potential difference generating unit 200 for measuring a potential difference due to a voltage difference;
The first SMPS board 110 and the second SMPS board 120 are connected in parallel to the output terminals of the first SMPS board 110 and the second SMPS board 120. The output terminals of the first SMPS board 110 and the second SMPS board 120 are connected in parallel (Relay) 300 (On / Off); And
The first output voltage of the first SMPS board 110 and the second output voltage of the second SMPS board 120 are connected to both ends of the potential difference generating unit 200 to measure and detect the first output voltage of the first SMPS board 110 and the second output voltage of the second SMPS board 120, An output voltage control signal is applied to the first SMPS board 110 and the second SMPS board 120 so that the first and second output voltages of the first SMPS board 110 and the second SMPS board 120 become equal to each other, , And a microcomputer (400) for outputting the output of the microcomputer (400).
The apparatus of claim 1, wherein the SMPS connector (100)
(+) Output terminal 111 of the output terminal of the first SMPS board 110 and the (+) output terminal 121 of the output terminal of the second SMPS board 120 are connected in parallel to the load LOAD + (-) output terminal 112 of the output terminal of the first SMPS board 110 and the (-) output terminal 122 of the output terminal of the second SMPS board 120 are connected in parallel Connected to the load (LOAD_-).
The apparatus of claim 1, wherein the potential difference generator (200)
And a resistor R connected in parallel between a (+) output terminal 111 of the first SMPS board 110 and a (+) output terminal 121 of the second SMPS board 120 Circuit device of a switching mode power supply.
The apparatus of claim 1, wherein the relay (300)
And the parallel connection circuit unit is connected in parallel with the potential difference generation unit (200) at a rear end of the potential difference generation unit (200).
5. The apparatus of claim 4, wherein the relay (300)
If there is a potential difference between the first output voltage of the first SMPS board 110 and the second output voltage of the second SMPS board 120, the output of the first SMPS board 110 and the output of the second SMPS board 120 Terminal of the switched-mode power supply operates in an off-state such that the terminal is interrupted.
5. The apparatus of claim 4, wherein the relay (300)
If the first output voltage of the first SMPS board 110 and the second output voltage of the second SMPS board 120 are the same voltage without a difference in potential, the first SMPS board 110 and the second SMPS board 120 And the output terminal of the switching circuit is operated to be connected in parallel.
7. The microcomputer according to any one of claims 1 to 6, wherein the microcomputer (400)
The first ADC (110) is connected to the output terminal side of the first SMPS board (110) of the potential difference generation unit (200) and measures the voltage of the output terminal of the first SMPS board (110) (401); And
A second ADC connected to the output terminal side of the second SMPS board 120 of the potential difference generation unit 200 for measuring and detecting the voltage of the output terminal of the second SMPS board 120 and converting the detected voltage into a digital value, (402). ≪ / RTI >< RTI ID = 0.0 > 40. < / RTI >
The method of claim 7, wherein the microcomputer (400)
The first ADC 401 and the second ADC 402 compare the digital values detected and converted so that the first output voltage of the first SMPS board 110 and the second output voltage of the second SMPS board 120 Output voltage control signal for determining which one of the output voltages of the first SMPS board 110 and the second SMPS board 120 is high and for lowering the output voltage of the second SMPS board 120 To the corresponding SMPS board of the parallel-connected circuit device of the switching mode power supply.
9. The method of claim 8, wherein the microcomputer (400)
And controls so that a potential difference between a first output voltage of the first SMPS board (110) and a second output voltage of the second SMPS board (120) is not generated, Connecting circuit device.
The method of claim 9, wherein the microcomputer (400)
If the first output voltage of the first SMPS board 110 is equal to the second output voltage of the second SMPS board 120, the relay 300 is controlled to be turned on, And the output terminal of the first SMPS board (110) and the output terminal of the second SMPS board (120) are connected in parallel so as to be connected to each other.
A method of controlling a parallel-connected circuit device of a switching mode power supply device,
(1) A potential difference generating unit 200 connected in parallel between the output terminal of the first SMPS board 110 and the output terminal of the second SMPS board 120, in which the microcomputer 400 is connected in parallel, Measuring and detecting a voltage and a second output voltage, respectively;
(2) determining whether the output voltage of the microcomputer 400 is higher than a first output voltage of the first SMPS board 110 and a second output voltage of the second SMPS board 120 ;
(3) The microcomputer 400 outputs an output voltage control signal for lowering the output voltage of the microcomputer 400 to a higher output voltage from the first SMPS board 110 and a corresponding one of the second SMPS boards 120 Controlling output to the board; And
(4) When the microcomputer 400 controls the relay 300 to turn on when the first output voltage and the second output voltage detected at both ends of the potential difference generation unit 200 are equal to each other without generating a potential difference, And a step of connecting the output terminal of the first SMPS board 110 and the output terminal of the second SMPS board 120 in parallel to each other so as to connect the output terminal of the first SMPS board 110 and the output terminal of the second SMPS board 120 .
12. The apparatus of claim 11, wherein the potential difference generator (200)
And a resistor (R) connected in parallel between an output terminal of the first SMPS board (110) and an output terminal of the second SMPS board (120). Control method.
12. The method according to claim 11, wherein in the step (2)
The first output voltage and the second output voltage measured and detected in the step (1) are converted into digital values using a first ADC 401 and a second ADC 402 constituted of internal functional blocks of the microcomputer 400 To the power supply voltage of the switching power supply.
12. The method according to claim 11, wherein in the step (3)
The microcomputer 400 controls output of an output voltage control signal to the corresponding SMPS board so that the output voltage of the microcomputer 400 can be lowered to an output voltage higher than the first output voltage of the first SMPS board 110, 2 SMPS board (120) until a potential difference of the second output voltage of the second SMPS board (120) is not generated.
12. The method according to claim 11, wherein in the step (4)
When the microcomputer 400 has a potential difference between the first output voltage and the second output voltage detected at both ends of the potential difference generation unit 200, the relay 300 is controlled to be kept off, Wherein the parallel connection of the output terminal of the first SMPS board (110) and the output terminal of the second SMPS board (120) is interrupted.
12. The method of claim 11, wherein the parallel connection of the first SMPS board (110) and the second SMPS board (120)
(+) Output terminal 111 of the output terminal of the first SMPS board 110 and the (+) output terminal 121 of the output terminal of the second SMPS board 120 are connected in parallel to the load LOAD + (-) output terminal 112 of the output terminal of the first SMPS board 110 and the (-) output terminal 122 of the output terminal of the second SMPS board 120 are connected in parallel And a parallel connection is made to be connected to the load (LOAD_-).
17. The method according to claim 16, wherein the connection of the parallel connection of the resistance (R) of the potential difference generation part (200)
One end of the resistor R of the potential difference generating unit 200 is connected to the positive output terminal 111 of the first SMPS board 110 and the other end of the resistor R is connected to the second SMPS board 120 (+) Output terminal (121) of the switching power supply, and the connection is made.
18. The apparatus of claim 17, wherein the relay (300)
And a parallel connection is made to the potential difference generating part (200) at a rear end of the potential difference generating part (200).
The method of claim 11, wherein the microcomputer (400)
The first output voltage of the first SMPS board 110 and the second output voltage of the second SMPS board 120 are detected and compared, and the first output voltage and the second output voltage are detected by the corresponding first ADC 401) and the second ADC (402), and comparing the digital values and comparing the converted digital values.
The method of claim 19, wherein the microcomputer (400)
The first and second ADCs 401 and 402 compare the first output voltage and the second output voltage to determine which one of the output voltages is higher and output the higher output voltage And outputting an output voltage control signal for lowering the voltage to a corresponding SMPS board of the first SMPS board 110 and the second SMPS board 120, Control method of connecting circuit device.

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