RU142950U1 - UNINTERRUPTIBLE POWER SUPPLY LAYOUT TEST DEVICE - Google Patents

Abstract

A device for testing the model of an uninterruptible power supply containing a test uninterruptible power supply, a first power quality analyzer, a computer with software, a second power quality analyzer, a load, and the input of the tested uninterruptible power supply combined with the input control parameters of the input circuits of the uninterruptible power supply of the first power quality analyzer , the output of the tested uninterruptible power supply is connected to the control input parameter the output circuits of the uninterruptible power supply of the second energy quality analyzer and with a load input, the output of the first energy quality analyzer is connected to the first input of the computer, the second input of which is connected to the output of the second energy quality analyzer, the third computer input is controllable, characterized in that a laboratory autotransformer is introduced the first input of which is connected to the power source, and the second input is controllable, the output of the laboratory autotransformer is connected to The combined input of the tested uninterruptible power supply and the first analyzer of the quality of electricity, the output of the tested uninterruptible power supply is connected to the fourth input of the computer.

Description

UNIT UNINTERRUPTIBLE POWER SUPPLY TEST DEVICE.

The utility model relates to the field of radio engineering, in particular to a method for testing and verification of models of uninterruptible power supplies.

Testing of uninterruptible power supplies (UPS) is a necessary condition for its further functioning. Bench testing of the UPS involves checking for operating time from the mains or battery with various loads.

Currently, there are many instruments for analyzing power supply. In particular, these are power analyzers of the Fluke Norma 4000 series. (). The compact Fluke Norma Power Analyzers offer the latest in measurement technology. These devices provide high accuracy in measuring currents and voltages in single-phase and three-phase systems, harmonic analysis, fast Fourier transform (FFT), as well as calculating power and other derived parameters.

But they all do not represent a complete solution for the analysis of secondary power sources, but can only be part of the instrumentation of test benches.

The UPS self-diagnosis system is known (US Pat. No. 5,458,991 A, “UPS with auto self test”, October 17, 1995), which performs the functions of checking the connected load and the condition of the battery. It also provides the user with this information. But this proposal is not intended for research of various uninterruptible power supplies, but only for integration into

finished products.

US 8,324,865B1, “UPS with test discharge load to determine battery capacity”, December, 2012, describes a UPS device with an integrated load for determining the capacity of a connected battery. But this solution does not allow measurements at various loads.

The closest technical solution (prototype) to the claimed utility model is the technical solution described in the Fluke () documentation for a Fluke 435 3-phase network power quality analyzer with the assumption that the Fluke 435 analyzer (for monitoring 3-phase networks) should be replaced with a Fluke 43V power quality analyzer (for monitoring 1-phase networks). The described solution is applicable for the case when it is required to test various power networks, secondary voltage sources.

Figure 1 presents the structural diagram of the device prototype.

The device contains a test UPS 1, a first power quality analyzer 2, a computer with software 3, a second power quality analyzer 5, a load 4, a PC operator 6. The input of the tested UPS 1 is combined with the input control parameters of the input circuits of the first UPS power quality analyzer 2 and connected with a power source. The output of the tested UPS 1 is connected to the input of the control of the output circuits of the UPS of the second power quality analyzer 5 and to the input of the load 4. The output of the first power quality analyzer 2 is connected to the first input of the computer 3, the second input of which is connected to the output of the second power quality analyzer 5. Third input computer 3 is connected to the output of the operator 6.

The power quality analyzer 2 monitors the parameters of the UPS input circuits, such as: input current and voltage, active and apparent power consumption, harmonic distortion of the current and voltage at the UPS input.

The power quality analyzer 5 monitors the parameters of the UPS output circuits, such as: output current and voltage, active and apparent power supplied to the load, harmonic distortions of the current and voltage at the UPS output.

The values of the parameters measured by the analyzers are transferred to computer 3 according to the RS-232 standard, where they are stored and analyzed by the Fluke View program.

Load 4 allows you to test the UPS at various degrees of UPS load.

The PC 3 operator processes the data received by Fluke View.

Unfortunately, the described method does not allow monitoring the state of the battery of the UPS under test, as well as checking the operation of the UPS for various voltage deviations of the power supply network.

The main problem solved by the proposed utility model is to study the behavior of uninterruptible power supplies for various deviations of the power supply network, to collect and process statistical information about the processes occurring in the uninterruptible power supply, as well as the state of the battery, its parameters and characteristics.

To solve this problem, a test model of an uninterruptible power supply unit containing a tested uninterruptible power supply source, a first power quality analyzer, a computer with software, a second electric power quality analyzer, load, operator, the input of the tested uninterruptible power supply connected to the output control parameter of the output circuits uninterruptible power supply of the second power quality analyzer and with load input, the output of the first quality analyzer The electric power supply is connected to the first input of the computer, the second input of which is connected to the output of the second energy quality analyzer, the third input of the computer is controllable, according to a utility model, a laboratory autotransformer is introduced, the first input of which is connected to a power source, and the second input is controllable, the output of the laboratory autotransformer is connected with the combined input of the tested uninterruptible power supply and the first analyzer of power quality, the output of the tested source b spereboynogo power is connected to the fourth input of the computer.

A comparative analysis of the claimed device with the prototype shows that the proposed solution is significantly different from the prototype, as it allows the study of uninterruptible power supplies at various deviations in the power supply network, various loads and at the same time monitor the state of the battery.

A comparative analysis of the claimed device with other technical solutions in this technical field did not allow to reveal the features stated in the distinctive part of the utility model formula.

Graphic materials presented in the description:

Figure 1 - presents a structural diagram of a prototype device.

Figure 2 - presents a structural diagram of the proposed device.

The proposed device is used to test various secondary power sources, such as UPS layouts.

The structural diagram of the proposed device is presented in figure 2.

The device contains a laboratory autotransformer 7, the UPS under test 1, the first electric power quality analyzer 2, a computer with software 3, the second electric power quality analyzer 5, load 4, the PC operator 6. The first input of the laboratory autotransformer 7 is connected to a power source, the second input of the laboratory autotransformer 7 connected to the second control output of the operator 6, the output of the laboratory autotransformer 7 is connected to the combined input of the tested UPS 1 and the first energy quality analyzer 2. The input of the tested UPS 1 is combined with the input of the control parameters of the input circuits of the UPS of the first power quality analyzer 2. The output of the tested UPS 1 is connected with the input of the control of parameters of the output circuits of the UPS of the second power quality analyzer 5 and with the load input 4. The output of the first power quality analyzer 2 is connected with the first input of computer 3, the second input of which is connected to the output of the second energy quality analyzer 5. The third input of computer 3 is connected to the output of operator 6.

Laboratory autotransformer 7 allows you to simulate various deviations of the voltage of the power supply.

The power quality analyzer 2 monitors the parameters of the UPS input circuits, such as: input current and voltage, consumed active and full power, harmonic distortion of the current and voltage at the input of the UPS.

The power quality analyzer 5 monitors the parameters of the UPS output circuits, such as: output current and voltage, active and apparent power supplied to the load, harmonic distortions of the current and voltage at the UPS output.

The values of the parameters measured by the analyzers, as well as information about the state and degree of charge of the UPS batteries, are transmitted to computer 3 according to the P3-232 standard, where they are saved and analyzed by software.

Load 4 - allows you to test the UPS at various degrees of UPS load.

The operator 6 adjusts the laboratory autotransformer 7 to ensure that the UPS parameters are measured for various deviations of the parameters of the supply network.

Computer 3 allows you to save data, as well as monitor the state and degree of charge of the UPS battery and monitor the battery life of the UPS at various degrees of load,

In contrast to the existing universal solutions, the proposed utility model allows research that is designed to study the characteristics of the UPS. Automated performance collection enhances research performance. Storage of the collected information allows for the qualitative analysis and comparison of the UPS.

Claims (1)

A device for testing the model of an uninterruptible power supply containing a test uninterruptible power supply, a first power quality analyzer, a computer with software, a second power quality analyzer, a load, and the input of the tested uninterruptible power supply combined with the input control parameters of the input circuits of the uninterruptible power supply of the first power quality analyzer , the output of the tested uninterruptible power supply is connected to the control input parameter the output circuits of the uninterruptible power supply of the second energy quality analyzer and with a load input, the output of the first energy quality analyzer is connected to the first input of the computer, the second input of which is connected to the output of the second energy quality analyzer, the third computer input is controllable, characterized in that a laboratory autotransformer is introduced the first input of which is connected to the power source, and the second input is controllable, the output of the laboratory autotransformer is connected to The combined input of the tested uninterruptible power supply and the first analyzer of the quality of electricity, the output of the tested uninterruptible power supply is connected to the fourth input of the computer.