KR100869724B1 - Process Integration System for Automated Power Conversion and Characterization - Google Patents

Abstract

A process integration system for automating the power conversion and the characteristic test reduces an amount of electric power by performing the recycling by converting DC output power into AC output power. A switching unit connects an output terminal of the power supply(105) to an external variable power supply in an over voltage protection process of characteristic test items. A load change part(232) changes an output terminal load of the power supply for performing the over current protection, over voltage protection, and load regulation tests. An output sensing unit(234) receives the voltage and current outputs of the power supply under the characteristic test in a cycle and a step which a user sets up. An ADC(Analog To Digital Conversion)(228) performs sampling to a preset cycle for transmitting the current and voltage output received from the output sensing unit to a CPU. The CPU(231) independently controls a current control unit or controls a boosting range and a dropping range of a boosting unit. A communications unit(229) manages the communication of the control unit and the CPU. A current controller(227) controls the output of the power supply according to the command of the CPU. The boosting unit(233) boosts or drops the voltage for converting the direct current output power source of the power supply into the AC input power. An output integration unit(235) integrates outputs of the power supply which are converted to the same magnitude. An external variable power feeder(236) is used for performing the over voltage protection function of the power supply.

Description

Process Integration System for Automation of Power Conversion and Characterization

1: Power supply durability tester currently in use

FIG. 2A is an e diagram of a power converter capable of significantly reducing the electrical energy of the present invention. FIG.

2B is a diagram of a power converter input unit.

2C is a diagram of an input unit to which a switching unit is added to simplify the configuration of the input unit.

2D is a diagram illustrating an input unit including a load variation unit, an output sensing unit, a booster unit, an output integration unit, an external variable power supply unit, and a switching unit.

3 is a schematic flowchart of operation of a power converter.

4A is a schematic flowchart of an input unit.

4B is a schematic flowchart of an input unit to which a switching unit is added to simplify the configuration of the input unit.

Power converters, such as power supplies (including inverters), which are the core components of the current electronics or component manufacturing market, perform durability tests for a certain period of time before leaving the factory, and a characteristic test of whether the finished products have passed the durability tests The process will be carried out.

Due to the manufacturing characteristics of mass production, the endurance test of the power supply is simultaneously testing as many as several thousand to as few as hundreds of power supplies. Depending on the product, the product is tested for approximately four hours of durability, and the endurance test equipment is continuously operated for 24 hours.

1 is a schematic block diagram of the power supply endurance tester currently being used in a large enterprise manufacturing process producing power supply related products.

As shown in FIG. 1, AC power (hereinafter referred to as Vac) of 110 to 220 Vac is supplied to each power supply to be tested for durability to test whether DC power output (hereinafter referred to as Vdc) occurs continuously for a predetermined time (usually 4 hours or more). In the durability test, a load is applied to each power supply output terminal in order to induce a DC power output from the power supply under test.

The problem of the power supply endurance test is that electrical energy is consumed and discarded in the form of thermal energy by a load applied to the DC output end of the power supply to induce the DC output power of the power supply. The durability test of the power supply is a step of verifying that it is possible to continuously maintain a stable DC output to the AC input power of the power supply, and inevitably needs to be a load that consumes the DC output power converted by the power supply. Currently, a high-watt wattage resistor is connected to the load, so that the DC output power converted by the power supply is consumed in the form of thermal energy. By using the high power watt resistor as described above, the DC output power of the power supply is consumed in the form of thermal energy, so that the temperature inside the test room is considerably high, and secondary energy waste that requires operating its own air conditioner and air conditioner to lower the temperature occurs. There is this.

Due to the above reason, the electricity consumption ratio used in the durability test of the power supply occupies most of the electricity consumption used in the entire manufacturing process, resulting in large energy waste, and the manufacturing cost of the power supply as a whole is greatly increased. .

Another problem of the power supply endurance test is that during the endurance test process, information on the parts of the power supply under test cannot be obtained. Therefore, after the endurance test is completed, the power supply for which the endurance test is completed is separately tested. It is necessary to go through an unnecessary process of judging the status. The present invention obtains the DC output power output from each power supply during the endurance test at a predetermined time interval (settable by the user) through a current sensor to set the power supply at the same time as the end of the endurance test. You can immediately determine.

An object of the present invention is to convert the DC output power of the power supply that is consumed in the form of thermal energy by the load applied for the durability test of the power supply to an AC power of 110 ~ 220Vac to alternating current required for the durability test By recycling it as an input power source, it is to develop a method and apparatus for greatly reducing the amount of electric energy used in the entire manufacturing process.

It is also an object of the present invention to develop a high efficiency DC-AC converter for reusing the DC output power of the power supply back to the AC input power of the durability test.

In addition, an object of the present invention is to provide a current sensor for outputting the DC output power output from each power supply during the durability test in order to eliminate the process of acquiring the characteristics for the determination of the power supply in which the durability test is completed in the manufacturing process of the power supply. By acquiring at regular time intervals (which can be set by the user) through the method, a method and an apparatus for immediately determining the power supply part of the power supply at the same time as the end of the durability test or the completion thereof are provided.

The present invention provides a DC-AC converter 215 for converting the power supply DC output power (hereinafter referred to as Vdc) into an AC input power source (hereinafter referred to as AC) of 110 to 220 Vac used in the durability test of the power supply. The current sensor 226 for acquiring the AC power of 110 to 220 Vac converted by the AC converter 215 and the 110 to 220 Vac converted by the DC-AC converter 215 acquired from the current sensor A 220. The control unit 210 to supply the AC power supply and the external AC input power supply unit 225 is less than the predetermined total AC input power required for the durability test, and a plurality of power supply 105 during the durability test Output of the power supply 105 based on the obtained current value and the current sensor 226 for acquiring the output of each of the power supply 105 under the durability test to stabilize the output of each power supply according to the parallel connection. To control Including the input unit 205 so that all the power supply 105 used in the endurance test can always output a constant DC output power is characterized in that formed.

According to the present invention, the load 110 is subjected to high power resistance in a power supply durability test (output stability confirmation test after applying a load to the power supply, usually about 4 hours continuous test), which is essentially performed in the power supply manufacturing market. The high power resistor 110 is replaced with a DC-AC converter 215 to be produced by the power supply 105 during the durability test to prevent waste of electrical energy generated by the release of heat into the atmosphere using thermal energy. The present invention relates to a method and apparatus for dramatically reducing the amount of electrical energy required for the durability test by converting the DC output power to AC power again and using the AC input power of the power supply 105 for performing the durability test. .

Hereinafter, with reference to the accompanying drawings and description will be described in detail the operating principle of the preferred embodiment of the present invention. However, the drawings and the following description shown below are for the preferred method among various methods for effectively explaining the features of the present invention, the present invention is not limited only to the drawings and description below.

1 is a schematic block diagram of a conventional power supply durability tester 100.

In almost all electronic manufacturing processes, manufacturers test the power supply endurance test at the same time, with as little as 500 or as many as 3000 units at a time, in order to shorten production time and reduce manufacturing costs. A large amount of electrical energy is required to perform the durability test of hundreds or more of the power supply at a time, so that most of the electrical energy consumed in the entire manufacturing process of the power supply 105 is consumed in the durability test process. As a result, the manufacturing cost of the power supply 105 is greatly increased.

Referring to the power supply durability test process, after mounting the assembled power supply 105 to the endurance test equipment to drive the power supply 105 mounted on the endurance test equipment 110 ~ 110 which is a general AC power source A 220 Vac power supply 115 is applied to the power supply 105. The power supply 105, which receives the 110-220 Vac AC power supply 115, continuously discharges the DC output power corresponding to the rating to the load 110 for at least 4 hours, and outputs the DC output from the power supply 105. The powered load 110 was configured to consume the direct current output power as heat so that the power supply 105 continued to discharge its rated output. As described above, since the DC output power corresponding to the rating of the power supply 105 is discarded in the form of thermal energy through the load 110 during the durability test period, a lot of electric energy is wasted. .

FIG. 2A is a schematic diagram of a power supply endurance tester in which a power converter 200 is added to recycle electric energy that is discharged and wasted in the form of thermal energy by the load 110 during the endurance test period in the power supply endurance test apparatus. Block diagram.

As described in FIG. 1, in the power supply durability test step, the AC power supply 105 is applied to the power supply 105 to drive the power supply 105, and the 110-220Vac 115 is operated. The power supply 105 receiving the AC input power discharges the DC output power corresponding to the rating to the load 110, and the load receiving the rated DC output power (power) from the power supply 105 ( 110 continuously discharges the rated DC output power applied from the power supply 105 to the air in the form of thermal energy during the durability test period so that the power supply 105 continuously outputs the rated DC output power. have.

The present invention in the power supply endurance test by recycling the rated DC output power (power) of the power supply 105 that is discarded into the atmosphere in the form of thermal energy by the load 110, greatly reducing the waste of electrical energy, the overall durability A method and apparatus for lowering the manufacturing cost of the power supply 105 by greatly reducing the electrical energy used in the test.

The power supply 105 is manufactured in a variety of forms, from the form of supplying a single DC output power to the supply of a variety of DC output power in accordance with the purpose.

The present invention is applied to a single DC output power supply as well as to a multi DC output power supply (five types of outputs are common in two types of outputs), and FIG. 2A illustrates two simple types to aid in understanding of the present invention. The power supply 105 for supplying the DC output power of the illustrated in the following, in order to clearly explain the key technical features of the present invention to those skilled in the art to clearly understand the terminology The present invention will be suitably modified, but the present invention is not limited thereto, and it can be said that the present invention is generally applicable to all power converters (such as a power supply and an inverter) that perform power conversion functions.

Each of the DC output power of the power supply 105 for the durability test is connected to the input unit 205 of the power converter 200 which is the core of the present invention. In the case of the power supply 105 for supplying two types of DC output power as shown in FIG. 2A, the input unit 205 of the power converter 200 is composed of two types, and a power supply for performing the durability test ( The number of input units 205 (input unit A, input unit B....) Of the power converter 200 is determined according to the type of the DC output power of 105. The same kind of outputs (outputs A1, A2, ..., An or outputs B1, B2 ..., Bn) of the power supply 105 are connected to the same input section 205 (input section A or input section B). After that, when the AC input power corresponding to the rating is supplied to the power supply 105, the durability test is started.

The input unit 205 obtains the DC output power output from each power supply 105 during the durability test at a predetermined time interval (settable by the user) through the current sensor 226 to the control unit 210. The control unit 210 that transmits and receives each power supply 105 DC output power value from the input unit 205 compares the preset DC output power value of the power supply 105 with the power that is currently being tested for durability. Supply 105 When the DC output power value is higher than the predetermined DC output power value, and lower if the high so that the current control unit 227 of the input unit to continuously output the same DC output power from a plurality of power supplies connected in parallel To control.

The control unit 210 transmits the DC output power of each power supply which is constantly controlled by the input unit 205 to the DC-AC converter 215, and receives the DC output power from the input unit 205. The AC converter 215 converts the DC output power into an AC power source of 110 to 220 Vac. In addition, the controller 210 acquires the value of the 110 to 220 Vac AC power converted by the DC-AC converter 215 to the current sensor A 220 and is to be provided to the power supply 105 under the durability test. The difference from the AC input power is calculated, and the external AC input power supply unit 225 is controlled to supply as many 110-220 Vac AC input power as necessary to re-input the input AC power required for each of the power supplies under test. Supply it. In addition, in order to shorten the characteristic test (stable government determination test of the DC output power supply) process of the power supply for which the durability test is completed, the control unit 210 receives a plurality of power supplies 105 connected in parallel received from the input unit 205. The DC output power value is stored and the DC output power value is transmitted to the outside in a form desired by the user such as online or offline.

The power supply endurance tester illustrated in FIG. 2A includes at least one server (or device) including at least one or more functional components (eg, power converters, etc.) or a predetermined server (or It may be implemented by at least one or more programs recorded on a recording medium provided in the device), by which the present invention is not limited.

2B is a schematic block diagram of the input unit 205 of the power converter 200.

Even with the same type of power supply, there is a slight difference in each DC output power supply. When several parallel connections are made, the output is generated in a power supply having a relatively high DC output voltage and a relatively low power supply. In order to solve the problem that a power supply having a DC output voltage cannot operate, each output of each power supply 105 to perform the endurance test is outputted to the current control unit 227 and the current sensor 226 of the input unit. Is connected to the input unit 205 through. The current sensor 226 acquires the DC output power of each power supply 105 at a predetermined period for a predetermined period and transmits it to the ADC (Analog To Digital Convertor, 228), the DC output power value of the power supply 105 The ADC (Analog To Digital Convertor) 228 receives the DC output power value at predetermined intervals and transmits the same to the communication unit 229. The communication unit 229 that receives the respective DC output power values of the power supply 105 from the ADC (Analog To Digital Convertor) 228 transmits the received DC output power values to the controller 210. The control unit 210 which receives the DC output power value of each of the power supplies 105 from the communication unit 229 compares the preset DC output power value of the power supply 105 with the communication unit 229 through the communication unit 229. By controlling the current control unit 226, the power supply 105, which is currently being tested for durability, has a lower DC output power value higher than the preset DC output power value, and a low value makes the DC output power constant. DC power supply 105 stabilized through the current sensor 226, the analog to digital converter (ADC) 228, the communication unit 229, the control unit 210, the communication unit 229, the current control unit 226. The output power is transmitted to the DC-AC converter 215 by the DC output 230.

2C is an example of a method for reducing the quantity of the current sensor 226 by further including a switching unit 231 as an example to simplify the device configuration in the input unit 205 of the power converter. Each output (output 1, output 2, output n) of the power supply 105 is connected to the switching unit 231 through the current control unit 227, and each of the power supply units connected to the switching unit 231 is provided. 105) outputs (output 1, output 2, output n) are connected to the usual DC output 230 to continuously supply the DC output power of each of the power supply 105 to the DC-AC converter 215, In addition, the DC output power of each of the power supply is configured to be connected to the DC output 230 through the current sensor 226 once in a predetermined period sequentially switched one by one at a predetermined period, the power supply once every predetermined period Each of the DC output power values is sequentially transmitted to the control unit 210 through the ADC (Analog To Digital Convertor, 228) and the communication unit 229 one by one.

The input shown in FIG. 2C is implemented to include at least one server (or device) including at least one or more functional components (e.g., switching unit, etc.), or a record provided in a predetermined server (or device). At least one program recorded on the medium may be implemented, and the present invention is not limited thereto.

2d is a load variation part, an output sensing part, a booster part, an output integration part, an external variable power supply part, and a switching part in order to integrate the durability test process and the characteristic test process of the power supply being performed in the existing product production process step. Fig. 1 is a schematic block diagram of an example of an additional input unit.

In the durability test process of the power supply 105, the output sensing unit senses the output of the power supply (values necessary for determining whether the product is successful, current, voltage, ripple value, etc.) as shown in FIGS. 2A and 2B. (Analog To Digital Convertor) is transmitted to the CPU, and the CPU receiving the output value (current, voltage, ripple value, etc.) of the power supply is output value (current, voltage, ripple value received from the output sensing unit 234). Etc.) to control the current controller 227 so that the outputs of a plurality of power supplies connected in parallel are constant. In addition, the CPU controls the booster 233 to simultaneously convert the various DC output power values of the power supply to the AC power values of 110 to 220 Vac at the same time and efficiently. Step up to DC output power. Various DC output power values of the power supply boosted to the same size DC output power value as described above are integrated into one DC output power from the output integrator 235 and transmitted to the DC-AC converter 215. do. The control unit transmits the DC output value of the power supply under durability test to the CPU 231 through the communication unit so that the DC output power value of the power supply in the endurance test process can be varied and tested. The controller 227 is controlled to vary the DC output power value of the power supply under test for durability, and verify the variable result again through the output sensing unit 234, and if the variable is completed, the result of the variable completion. The communication unit 229 transmits the data to the control unit.

In addition, the parameters (values obtained for the determination of the quality of the product) acquired in the existing characteristic inspection process of the power supply are integrated into the following functions without transferring the product to the existing characteristic inspection process. Although there are some differences depending on the manufacturer's power supply, there is a common measurement of output voltage / current stability due to AC input fluctuations, and Over Current Protection (current measurement where the power supply loses its function for output above the rated current) Over Voltage Protection ( Measurement of the voltage that the power supply loses its function for the output over the rated voltage) , ripple voltage (AC voltage component included in the DC output voltage of the DC power supply.The smaller the component, the better the voltage supply. It is one of the important parameters that determine the quality of the power supply.) Perform the inspection process. The output voltage / current stability measurement is a step of measuring whether the power supply generates a stable output for an unstable AC input power according to the site environment, which is supplied from the DC-AC converter 215 to the power supply to be tested. Supply AC input power while changing to a preset value (eg, check whether the power supply generates a rated output by supplying AC 200Vac or 250Vac to a power supply operating at AC 220Vac), and change the DC-AC converter. The output value of the power supply supplied with the AC input power is sensed by the output sensing unit 234 and passed through an analog to digital convertor (ADC) 228, a central processing unit (CPU) 231, and a communication unit 229. Transmitted to the control unit and used as a positive / negative determination parameter of the power supply to Judges FIG. Over current protection (current measurement that the power supply loses its function for an output above the rated current) The measurement test causes the control unit to output the output current of the power supply step by step at the load variation unit 232 step by step. The CPU 231 receives the sequential output current fluctuation value preset by the user for each power supply type through the communication unit and the sequential output current fluctuation value preset by the user for each power supply type is determined by the load fluctuation part ( 232) to induce the power supply to output more than the rated current to measure the overcurrent value that the power supply loses its function and transmits it to the controller. The control unit receiving the overcurrent value determines whether the overcurrent value of the received power supply has lost its function within a preset maximum overcurrent allowance range, and determines whether the overcurrent value of the power supply is correct. In the Over Voltage Protection test, a voltage measurement in which the power supply loses its function for an output above a rated voltage is performed. The CPU, which is commanded by the controller, switches the power supply output stage from the switching unit 237 to the external variable power supply unit 236. Connect with. When the power supply output stage and the external variable power supply unit 236 are connected, the control unit controls the external variable power supply unit 236 to gradually increase and apply DC power to the power supply output stage step by step, so that the power supply unit An overvoltage value that loses the function is acquired through the output sensing unit 234. The control unit receiving the overvoltage value acquired by the output sensing unit 234 determines whether the overvoltage value of the received power supply has lost its function within a preset maximum overvoltage allowable range, and determines whether the power supply is correct. In addition, in order to implement the invention more simply, the Over Voltage Protection test further includes a function of gradually removing DC variable power supply unit 236 and gradually increasing DC power from the load variable unit 232 to the power supply output stage. By implementing it, the user can select and use the convenience. In the ripple voltage measurement test, the ripple voltage itself has a high frequency characteristic, and therefore, there is a problem in that sampling at high speed is required. The ripple voltage value of the power supply acquired by the output sensing unit 234 is acquired by the ADC 228 at a sampling rate (number of data acquired per second) preset by the control unit and transmitted to the control unit. In this case, the Samplin Rate, which is a speed of acquiring the ripple voltage value in the ADC 228, may be arbitrarily changed by the controller.

In addition, the control unit controls the load variation unit 232 through the CPU to 100% the output condition of the power supply under the durability test conditions. 80%. Like 70%, it can be adjusted by the user as needed.

The load variable also regulates the power supply output environment during the endurance test. (Designated by the user as 100% durability test, 70% durability test)

The input unit illustrated in FIG. 2D includes at least one server (or a load variable unit and an output sensing unit, a booster unit, an output integration unit, an external variable power supply unit, a switching unit, etc.) (or Device) or at least one program recorded on a recording medium provided in a predetermined server (or device), and the present invention is not limited thereto.

3 is a schematic flowchart of a power supply durability test using the power converter 200.

After checking the quantity and the number of outputs of the power supply 105 to be tested for durability (305), the number of inputs of the power converter is determined. (310) The output of the power supply is connected to the input (315). 110-220Vac rated AC input power is supplied to the supply unit 105 to transmit the output DC output power to the DC-AC converter 215 (325). In this case, the controller controls the output of each of the power supplies connected in parallel so that the DC output power of each of the power supplies under test for durability is matched with a preset value without error. In addition, the DC-AC converter 215 converts the DC output power received to the AC input power (335), and the control unit 210 through the current processor A 220, the DC-AC converter 215 Calculate the total amount of the AC input power converted in step 340, calculates the difference from the total AC input power to be supplied to each power supply 105 under the durability test, and the difference as much as the external AC input By supplying the power supply unit 225 (345), generates the AC input power required for the durability test, and continuously supplying the AC input power to each of the power supply 105 in the durability test (320). In addition, the controller 210 checks the durability test time set during the power supply durability test, if the test time is less than the predetermined time (350), and continuously performs the durability test (320), If the test time exceeds the preset time (355), the test is terminated (360).

4A is a schematic flowchart of a power converter input 205.

In the durability test, when the DC output power of each power supply 105 is output (405), the DC output power value is obtained from the current sensor 226 (410) to the ADC (Analog To Digital Convertor, 228). Transmit (410). The ADC 228, which receives the DC output power value of the power supply 105 from the current sensor 226, samples the obtained DC output power value at a predetermined period (415) to the control unit through the communication unit 229. Transmit (420). The control unit 210 receiving the DC output power value of each of the power supply 105 from the communication unit 229 compares (425) with a predetermined DC output power value of the power supply 105 (430) and matches (430). The DC output power value is acquired again (410), and the above process is repeated for each preset period. If the comparison value does not match (435), the current controller 227 is controlled through the communication unit 229 to present current durability. When the DC power supply value of the power supply 105 under test is higher than the preset DC output power value, and lower when the value of the power supply 105 is higher, the DC output power of each power supply 105 under the durability test is always kept constant. (440)

FIG. 4B is a simple flowchart of an input unit further including a switching unit 231 to simplify the configuration of the input unit 205 of the power converter.

In the durability test, when the DC output power of each power supply 105 is output (405), the DC output power of the power supply is integrated through the DC output 230 and transmitted to the DC-AC converter (410). In this case, the switching unit 231 switches the DC output power terminals of each of the power supplies 105 to output one DC output power terminal of the power supply 105 that is sequentially selected according to a predetermined rank and period. The connection to 230 is disconnected and automatically connected to the current sensor 226 (415). The current sensor 226 connected to the DC output power terminal of the power supply acquires a DC output power value and transmits the DC output power value to an analog to digital convertor (ADC) 420. The ADC (Analog To Digital Convertor) 228, which receives the DC output power value of the power supply 105 from the current sensor 226, samples the obtained DC output power value at predetermined intervals (425) and the communication unit 229 In operation 430, the control unit 210 transmits the control to the control unit 210 through the control unit 210. Receiving the DC output power value of each of the power supply 105 from the communication unit 229, the control unit 210 compares with the predetermined DC output power value of the power supply 105 (425) if the two values match The above process is repeated by switching the power supply DC output terminal of the next lower surface 440, and if the two values do not coincide (445), the current controller 227 is controlled through the communication unit 229. The DC power supply 105 under durability test is lowered if the value of the DC output power is higher than the preset DC output power value, and lowered if it is low, so that the DC output power of each power supply under durability test is always kept constant. (450)

The present invention in the durability test, which is an essential process of the power supply manufacturing process, converts the DC power output of the power supply consumed in the form of thermal energy by the load applied for the durability test to an AC power source of 110 to 220 Vac and then again. By recycling the AC input power required for the durability test, it is possible to greatly reduce the amount of electrical energy used in the entire manufacturing process.

In another aspect, the present invention by performing the characteristic test of the power supply at the same time during the power supply endurance test, by omitting the characteristic test step for the power supply that has been previously performed, the advantage that can shorten the entire manufacturing process There is this.

Claims (16)

Integrating the durability test process and the characteristic test process to automatically and automatically test all power supplies simultaneously with the power supply in the durability test facility without additional wiring and instrument connection after the end of the durability test process. The power conversion and process integration system, A switching unit which maintains the output terminal of the power supply connected to the load variation unit and the output sensing unit during the endurance test process, and connects the output terminal of the power supply to an external variable power supply in a step of performing an Over Voltage Protection item among characteristic test items; And A load variation unit configured to vary an output load of the power supply under control of a controller to perform over current protection, over voltage protection, and load variation test; And An output sensing unit which receives the voltage and current output of the power supply being tested for characteristics as well as the durability test process at a predetermined cycle and step; And An analog-to-digital conversion (ADC) for sampling the current and voltage outputs received from the output sensing unit at predetermined intervals to transfer them to the CPU; And The current and voltage output values sampled by the ADC are input to control the current controller independently, or transmit to the control unit through the communication unit to wait for the next command transmission, and control the boosting range and the decompression range of the boosting unit under the control of the control unit. CPU; And A communication unit in charge of communication between the CPU and the controller; And A current control unit controlling an output of the power supply according to a command of the CPU; And A booster for performing a boosting or reducing step to convert a direct current (AC) output power of the power supply into an AC input power to be used for the durability test of the power supply; And An output integrating unit that boosts or depresses different output powers of the power supply in a boosting unit and converts the output power of the power supply into power of the same size, and integrates the outputs of the power supply converted into the same size in the boosting unit; And An external variable power supply for performing the over voltage protection function of the power supply; and a power conversion and process integration system comprising: The method of claim 1, wherein the power conversion and process integration system, Function to control the load changer, the output sensing unit, the current control unit and the booster in the CPU by the command of the control unit, and the load changer, the output sensing unit, the current control unit and the booster in the GUI (Graphic User Interface) Power conversion and process integration system characterized in that it comprises a The method of claim 1, wherein the characteristic inspection process, In addition to the basic characteristic test items such as output voltage / current stability test, over current protection test, over voltage protection test, load fluctuation test, and ripple voltage measurement, test items added according to the characteristics of the power supply to be tested (Turn On Time) Measurement (the time it takes for the output voltage of the power supply to reach the rated voltage after applying the input power to the power supply) , Turn Off Time measurement ( The output voltage of the power supply may be 0V after removing the power supply to the power supply. Time period ), and additional contact points of the switching unit to further implement the output signal check for a specific input signal (control signal) .The oscilloscope, digital multimeter, function generator, and specific input signal (or control signal) Power conversion and process integration system, characterized in that configured to use the output signal inspection module. The method of claim 1, wherein the input unit (205-2) Input and output points, which are processed and outputted as signals and data, are processed and output to the load changer, the output sensing unit, the ADC, the current control unit, the CPU, the communication unit, the booster, and the output integration unit constituting the input unit as separate Test Point terminals. In addition, power conversion, characterized in that it provides a convenience to periodically calibrate the integrity of the load change unit, output sensing unit, ADC, current control unit, CPU, communication unit, boosting unit, output integration unit at the Test Point terminal And process integration systems The power conversion and process integration system of claim 1, For the characteristic test, the load variable part, the output sensing part, the current control part, the CPU, and the communication part are controlled through the GUI (Graphic User Interface) of the control part. A power conversion and process integration system, characterized in that implemented to change the operation order and initial value of the current control unit, the CPU, the communication unit. The method of claim 1, wherein the ADC, During the endurance test process, the output voltage / current of the power supply is sampled from the output sensing unit at predetermined intervals and is transmitted to the control unit via the CPU and the communication unit. And setting a different sampling period of the ADC for each process so as to set the current / voltage sampling period different from the set period and obtain the voltage / current by sampling and transmitting the CPU / communication unit to the control unit. Power conversion and process integration system, characterized in that. The method for recycling different direct current (AC) output powers of a plurality of power supplies to AC input power to be used for durability test of the power supply Stepping up or down to convert the different direct current (AC) output power sources into an AC input power source to be used for the durability test of the power supply; and Integrating the boosted or decompressed different direct current (AC) outputs into one output; and And converting the integrated DC (AC) output into an AC input power and recycling the AC input power for the durability test of the power supply. The method and method of claim 7, wherein the plurality of power supplies connected in parallel to generate a predetermined output simultaneously, Sensing a direct current (AC) output power value of each power supply connected in parallel and transmitting the same to an CPU through an analog-to-digital converting (ADC) process; And Transmitting a direct current (AC) output power value of the power supply received from the CPU to a controller through a communication unit; And Controlling the current control unit to control the current control unit so as to lower the DC (AC) output power value of the transmitted power supply to a higher value than a preset value; . The method and method for converting a direct current (AC) output power of the power supply into an AC input power to be used for durability test of the power supply, Separating output voltages of different magnitudes of the power supplies under test for durability into a low voltage group of 0 to 50 V, a medium voltage group of 51 to 120 V, and a high voltage group of 121 V or more; And Receiving outputs of the power supply separated into a low voltage group of 0 to 50 V, a medium voltage group of 51 to 120 V, and a high voltage group of 121 V or more to a separate independent input unit; And And converting the power supply outputs of different sizes into outputs of the same size by boosting or depressurizing them into AC power. The method and method for converting an output of a power supply that supplies an output of AC 500 Vac or 1000 Vac or more into an AC input power to be used for durability test of the power supply. The power supply output power of AC 500Vac or less converts AC 220Vac (or AC 110Vac) to the primary pressure reduction, and the power supply output power of AC 1000Vac or more is first reduced to 1000Vac AC and then decompressed to AC 500Vac again and then again. Reducing the pressure to AC 220Vac (or AC 110Vac); power conversion method comprising a. The boosting step and method for converting an output of a power supply supplying an output of 50 V or less into an AC input power to be used for durability test of the power supply, When the output of the power supply is 50 Vdc or less, directly boosting to a medium voltage group of 51 to 120 V, and then converting to AC input power after boosting to 380 V for the second time; and When the output of the power supply is 50Vac or less AC step of step up to the medium voltage group of 51 ~ 120Vac first and then step up to AC 220Vac or 380Vac or 440Vac; power conversion method comprising a. The method and method according to claim 7, wherein the direct current (AC) output of the power supply under durability test is converted into an AC input power to be used for the durability test of the power supply, and the method is resupplyed to the power supply under durability test. Converting a DC (AC) output of the power supply into an AC input power to be reused for the durability test of the power supply, and then matching the phase and magnitude of the converted AC input power with an AC power supplied from an external power network; and And feeding (or connecting) AC input power to the external power grid to be reused for durability test of the power supply whose phase and magnitude match the AC power supplied from the external power grid. Power conversion method. 10. The method and method according to claim 7, wherein the step and method for allowing a variable test of the direct current (AC) output power value of the power supply during the endurance test process are performed. Transmitting, by a control unit, a direct current (AC) output power value of the power supply under test to the CPU through a communication unit; And A CPU receiving an output value to be output by the power supply from the control unit, controlling a current control unit and testing the variable DC power output value of the power supply; And Sensing, by the current sensing unit, a variable direct current (AC) output power value of the power supply being tested for durability and transmitting it to a CPU to determine whether the direct current (AC) power output value of the power supply is correctly changed; And And transmitting a result of a direct current (AC) output power value of the variable power supply unit to a control unit through a communication unit. In order to integrate the durability test process and the characteristic test process, all the above-mentioned power supplies are simultaneously loaded with the power supply in the durability test facility without the additional wiring and instrument connection after the end of the durability test process. How to do it Measuring an output voltage / current stability that checks whether an AC power input for driving the power supply is within a preset range while checking whether the output of the power supply maintains a predetermined constant value without change; And Inspecting whether the power supply is within the preset overcurrent range by measuring an overcurrent value in which the power supply loses its function by inducing the power supply output while varying the output of the power supply so that the power supply increases the current above the rated output current. Over Current Protection step; And In the load variation section, the power supply increases the voltage of the power supply to increase the voltage above the rated output voltage while inducing the output of the power supply. Voltage Protection step 1; And The CPU controls the switching unit by receiving a command from the controller so that the plus terminal of the power supply output terminal is connected to the minus terminal of the external variable power supply and the minus terminal of the power supply output terminal is connected to the plus terminal of the external variable power supply in reverse. An over voltage protection step 2 of checking whether the power supply loses its function by applying power of an opposite polarity to an output terminal of the power supply from an external variable power supply; And A load variation test step of checking whether the power supply maintains a predetermined constant output while varying an output condition (load condition) of the power supply in the load variation part; And And measuring a ripple voltage mixed in the power supply output power. The method according to claim 14, characterized in that The oscilloscope or digital multimeter may be added by adding a connection contact of the switching unit to perform the inspection of additional characteristic inspection items that may be generated according to the characteristics of the power supply, in addition to the common characteristic inspection items of the power supply described in claim 14. Configuring a function generator and an output signal inspection module for a specific input signal (or control signal); And Signals and data are input, processed, and output to each of the load changer, output sensing unit, ADC, current control unit, CPU, communication unit, booster unit, output integrating unit, control unit, and DC-AC converter unit constituting the power conversion system. Characteristic test and process integration method comprising the; further comprising the step of configuring the input and output points to a separate Test Point terminal. 15. The method of claim 14, wherein the method of performing a simultaneous characteristic test for a plurality of power supplies, Combining and connecting the number of input units to be controlled by one control unit; And Characterizing and process integration method characterized in that it comprises a; connecting each of the control unit connected to a plurality of input unit combination to perform the control again to a plurality of combinations and the upper control unit (distribution control);

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