KR101849054B1 - System for power saving of intelligent - Google Patents

Abstract

Disclosed is an intelligent electricity saving system which is connected to a three-phase AC power supplying line receiving a three-phase AC power, measures voltages and currents of the three-phase AC power, improves waveforms of currents according to the measured voltage and currents, corrects a power factor generated from a phase difference of the voltages and currents, and is able to reduce power consumption. The intelligent electricity saving system comprises: a measuring module which measures the voltages and currents of a three-phase AC power received from the outside; a power saving module which filters noises to inhibit the noises of the three-phase AC power from occurring, and reduces a phase difference between the voltages and currents of the three-phase AC power to decrease an amount of usage of the three-phase AC power; and a control module which individually determines operations of each of noise filters and power factor correction circuits, depending on the current waveform of the three-phase AC power measured by the measuring module and the phase difference between the voltage and currents of the three-phase AC power. Accordingly, even if the system is connected to a supply line of a three-phase AC power whose voltage is higher than a single-phase AC power, the system effectively improves waveforms of currents and reduces a phase difference between a voltage and currents, thereby reducing power consumption.

Description

[0001] System for power saving of intelligent [0002]

More particularly, the present invention relates to a three-phase AC power supply line connected to a three-phase AC power supply line to which three-phase AC power is supplied, measures voltage and current of a three-phase AC power supply, The present invention relates to an intelligent electricity saving system capable of improving the waveform of current and compensating the power factor according to the phase difference between voltage and current, thereby reducing the amount of electricity used.

The three-phase AC power supply has more stable and strong current than the single-phase 220V used in general households, and has the advantage that the number of wires entering the outlet is larger than single phase and the stability of the power supply can be secured. It is applied to products that use a lot of electricity. It is widely used in offices and factories.

Such a three-phase AC power source, like a single-phase AC power source, generates unnecessary power consumption due to noise generated in the process of being supplied to various electronic and electric products, shortens the service life of electronic and electric products, There is a problem that the efficiency of the AC power source is lowered.

Since conventional power saving systems or AC power source noise reduction devices related to this technology are applied to single-phase AC power sources, there is a difficulty in applying them to a three-phase AC power source having a higher voltage than a single-phase AC power source.

Therefore, even if a high-voltage three-phase AC power supply is connected to a supply line of a higher voltage than a single-phase AC power supply, it is required to seek a way to improve the current waveform effectively and improve the efficiency of the three-phase AC power supply.

Korean Patent Laid-Open No. 10-2010-0137273 (entitled "AC outlet-connected AC power line noise reduction device") Korean Patent No. 10-1572627 entitled " Power Saving System "

It is an object of the present invention to provide a noise filter for improving a current waveform of a three-phase AC power source and a power factor correction A plurality of circuits are provided. Whether or not the plurality of noise filters and the power factor compensating circuit are operated individually is determined according to the measured current and voltage of the three-phase AC power source to improve the waveform of the current, Saving electric power saving system.

According to an aspect of the present invention, there is provided an intelligent electricity saving system including: a measurement module for measuring a voltage and a current of a three-phase AC power source supplied from the outside; A power saving module for filtering the noise and reducing a phase difference between a voltage and a current of the three-phase AC power source so that the amount of use of the three-phase AC power source is reduced so that generation of noise of the three-phase AC power source is suppressed; And a control module for individually determining whether the noise filter and the power factor correction circuit operate according to the phase difference between the current waveform of the three-phase AC power source measured by the measurement module and the voltage and current of the three-phase AC power source .

The measurement module includes an R-phase AC power supply line, an S-phase AC power supply line, and a T-phase AC power supply line so that the voltage and current of the R phase AC power, the S phase AC power and the T phase AC power are separately measured for each AC power source. Phase alternating current power supply lines. And a voltage measuring module connected to the R-phase AC power supply line, the S-phase AC power supply line, the T-phase AC power supply line, and the N-phase AC power supply line, Lt; / RTI >

Also, the power saving module may be separately connected to the R-phase AC power supply line, the S-phase AC power supply line, and the T-phase AC power supply line, and the R-phase AC power, the S- The current waveforms of the power source can be individually improved and the phase difference between the voltage and current of the R-phase AC power, the S-phase AC power, and the T-phase AC power can be individually reduced.

The control module controls the R-phase AC power source, the S-phase AC power source, and the T-phase AC power source so that information on the current waveform before and after filtering is output, And information on the phase difference between the voltage and the current of the T-phase AC power source before and after the decrease can be distinguished and output.

The power saving module includes a noise filter for improving the current waveform of the current and a plurality of power factor correcting circuits for reducing the phase difference between the voltage and the current. The R phase AC power supply line, the S phase AC power supply Line and T-phase AC power supply lines, the plurality of noise filters and the plurality of power factor correction circuits are connected in parallel for each of the connected AC power supply lines, and the control module includes: The operation of a plurality of noise filters and a plurality of power factor correction circuits connected in parallel for each AC power supply line is determined by comparing the current waveforms of the R-phase AC power, the S-phase AC power, and the T- Can be determined individually.

When the plurality of noise filters connected in parallel are not operating, the control module controls the current waveform of the AC power source of the three-phase AC power source through the measurement module, Comparing the stored current wave model with the current waveform model so that if the noise of the measured current waveform is judged to exceed the predetermined noise tolerance range, the noise filter of any one of the plurality of noise filters connected in parallel is operated, The current waveform of any of the AC power supplies is re-measured in a state in which the noise filter of the re-measured current waveform is in operation and the re-measured current waveform is compared with the previously stored current waveform model, If it is determined that the noise tolerance is exceeded, another noise filter And comparing the re-measured current waveform with the pre-stored current waveform model to determine whether the noise of the measured current waveform is within the noise tolerance range, It is possible to increase the number of operations.

When the noise filter and the power factor correction circuit are operated by one switch, it is determined that the noise of the measured current waveform is within the predetermined noise tolerance range, Phase AC voltage of the AC power supply is measured in a state in which the operation number of the operating noise filter is maintained through the measurement module and the phase difference between the measured voltage and the current is set in advance Determining whether or not the phase difference between the voltage and the current is within a permissible range of the phase difference, and if it is determined that the measured phase difference between the voltage and the current exceeds the predetermined phase difference allowable range, Further comprising: a state in which any one of the power factor correction circuits is further operated; The phase difference between the original voltage and the current is re-measured. When it is determined that the phase difference between the re-measured voltage and the current exceeds the predetermined phase difference allowable range, the other power factor correction circuit is further operated And the number of operation of the plurality of power factor correction circuits connected in parallel may be increased until it is determined that the phase difference between the remeasured voltage and current is within the predetermined phase difference allowable range.

The control module controls the current waveform and the phase of voltage and current measured when the plurality of noise filters or the plurality of power factor correction circuits connected in parallel are not operated for each AC power source for the three- Information on the difference and information on the number of operation of the noise filter and the number of operation of the power factor correction circuit for each of the AC power sources may be matched and stored.

In addition, the control module may further include: a plurality of noise filters or a plurality of power factor correction circuits connected in parallel among information stored in the voltage and current of the three-phase AC power source measured through the measurement module, If it is determined that there is the same information as the current waveform and information on the phase difference between the voltage and the current, information on the number of operations of the noise filter and the number of operations of the power factor correction circuit, The number of operations and the number of operations of the power factor correction circuit can be determined.

When the measurement modules are individually connected to the R-phase AC power supply line, the S-phase AC power supply line, and the T-phase AC power supply line, an overcurrent occurs in each AC power supply line, The control module detects that the AC power supply line is disconnected or the AC power supply line is disconnected from the AC power supply line through the power saving module , An overcurrent is generated or a warning signal is issued that the supply of AC power is interrupted and the overcurrent occurs in the AC power supply line where the overcurrent occurs or the supply of the AC power is interrupted, Information on the measured current and voltage immediately before the supply of the AC power is cut off and the above-mentioned overcurrent And information about the noise filter and power factor correction circuit which is matched to, or are connected to the block AC power supply line of the AC power supply operation can be stored.

Thus, even when the power supply is connected to the supply line of the three-phase AC power source having a voltage higher than that of the single-phase AC power source, the current waveform can be effectively improved and the phase difference between the voltage and the current can be reduced.

1 is a view showing a terminal box equipped with an intelligent electricity saving system according to an embodiment of the present invention.
2 is a diagram illustrating a configuration of an intelligent electricity saving system according to an embodiment of the present invention.
3 is a diagram illustrating a configuration of a power saving module of an intelligent electricity saving system according to an embodiment of the present invention.
FIG. 4 is a diagram schematically showing a part of the configuration circuit of the power saving module according to an embodiment of the present invention.
5 is a diagram illustrating a configuration of an output module of an intelligent electricity saving system according to an embodiment of the present invention in more detail.
FIG. 6 is a diagram for explaining a process of improving a current waveform and compensating a power factor according to a phase difference between a voltage and a current, using an intelligent electricity saving system according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings. The embodiments described below are provided by way of example so that those skilled in the art will be able to fully understand the spirit of the present invention. The present invention is not limited to the embodiments described below and may be embodied in other forms.

FIG. 1 is a view showing a terminal box equipped with an intelligent electricity saving system according to an embodiment of the present invention, and FIG. 2 is a diagram illustrating a configuration of an intelligent electricity saving system according to an embodiment of the present invention. Hereinafter, the intelligent electricity saving system according to the present invention will be described with reference to FIGS.

This intelligent power saving system is designed to improve the waveform of the current and to reduce the phase difference between voltage and current.

Specifically, the intelligent electricity saving system 10 is connected to a three-phase AC power supply line supplied with three-phase AC power, measures the voltage and current of the three-phase AC power supply, It is possible to improve the waveform and compensate the power factor which is the phase difference between the voltage and the current, so that the phase difference between the voltage and the current can be reduced.

Herein, the three-phase AC power supply line to which the intelligent electricity saving system 10 is connected may be connected to the earth leakage breaker 20 together with the intelligent electricity saving system 10 and the earth leakage breaker 10, And may be installed to be accommodated in one terminal box 30 as shown in FIG.

2, the intelligent electricity saving system 10 includes a measuring module 100, a power saving module 100, a power saving module 100, a power saving module 100, The input module 300, the control module 400, the output module 500, the storage module 600, and the power supply module 700, as shown in FIG.

The measurement module 100 is provided for measuring three-phase AC power and current. Specifically, the measurement module 100 is individually connected to the R-phase AC power supply line, the S-phase AC power supply line, and the T-phase AC power supply line, so that the R-phase AC power, the S- Current measuring module 110 for separately measuring currents, and R-phase AC power supply lines, S-phase AC power supply lines, T-phase AC power supply lines, and N-phase AC power supply lines, And a voltage measurement module 120.

Here, the current measurement module 110 can measure not only the current value and the voltage value but also the current waveform, and the voltage measurement module 120 can measure the voltage waveform, The phase difference between voltage and current can be measured through the waveform of the current and the waveform of the voltage.

When the current measurement module 110 is individually connected to the R-phase AC power supply line, the S-phase AC power supply line, and the T-phase AC power supply line, an overcurrent occurs in each AC power supply line, Can be detected.

The power saving module 200 is provided for filtering the noise of the three-phase AC power source according to the measured current and voltage, reducing the phase difference between the voltage and the current, and reducing the amount of the three-phase AC power source. here,

The input module 300 is provided for the user to generate input signals that can control the control module 400. Specifically, the user controls the power saving module 200 through the input module 300 so that the power saving module 200 filters the noise of the three-phase AC power according to the measured current and voltage, It is possible to select an automatic mode in which the process of reducing the phase difference between voltage and current is automatically performed or a manual mode in which it is performed manually according to the user's input.

The control module 400 may control the power saving module 200 according to the input signals generated through the input module 300. Specifically, when the automatic mode is selected according to the input signal generated through the input module 300, the control module 400 filters the noise of the three-phase AC power according to the measured current and voltage , The process of reducing the phase difference between the voltage and the current can be performed without any additional user operation. Further, when the manual mode is selected, the control module 400 can control the power saving module 200 to operate as the user operates, and a more detailed description related thereto will be described later with reference to FIG.

If it is determined that an over-current occurs in any of the AC power supply lines of the AC power supply lines or the supply of the AC power is interrupted, the control module 400 generates an overcurrent, or supplies the AC power And an alarm for the interruption is outputted through the output module 500. When an overcurrent occurs or an overcurrent occurs in the alternating-current power supply line in which the supply of the alternating-current power is interrupted, or the supply of the alternating-current power is interrupted The information on the current and voltage measured immediately before and the information on the noise filter 210 and the power factor correction circuit 220 which are operated by being connected to the AC power supply line in which the overcurrent is generated or the supply of the AC power is cut off, And may be stored in the storage module 600.

The output module 500 outputs information on the measured current and voltage through the measurement module 100 or information on the waveform of the current measured before and after the improvement and the voltage and current measured before and after the power factor compensation Can be output. Then, the output module 500 may output an alarm indicating that an over-current occurs or a supply of the AC power is interrupted.

The storage module 600 may store information generated as the intelligent electricity saving system 10 measures or operates. Specifically, the storage module 600 stores information on the current and voltage measured through the measurement module 100, information on the waveform of the current measured after the improvement and after the improvement, and information on the voltage and current measured before and after the power- Information and the like can be stored.

The power supply module 700 may be implemented as an SMPS to supply AC power to the components of the intelligent electricity saving system 10, including the control module 400.

FIG. 3 is a diagram illustrating a configuration of a power saving module 200 of an intelligent electricity saving system according to an exemplary embodiment of the present invention, and FIG. 4 is a diagram illustrating a power saving module 200 according to an embodiment of the present invention. Fig. 2 is a schematic view showing a part of the constituent circuits of Fig. Hereinafter, the configuration of the intelligent electricity saving system will be described in more detail with reference to FIGS. 3 to 4. In particular, the configuration of the power saving module 200 will be mainly described.

The power saving module 200 filters the noise of the three-phase AC power according to the measured current and voltage, reduces the phase difference between the voltage and the current, and reduces the amount of use of the three-phase AC power. A filter 210, a power factor correction circuit 220 for compensating the power factor of the voltage and the current, a noise filter 210 and a switch circuit 230 for determining whether the power factor correction circuit 220 operates, And a zero-cross switch circuit 230 for determining the on / off operation of the three-phase AC power source when the power factor correction circuit 220 does not operate.

Specifically, the noise filter 210 is individually connected to the R-phase AC power supply line, the S-phase AC power supply line, and the T-phase AC power supply line so that the current waveform of the current flowing through each AC power supply line becomes sinusoidal So that the waveform can be improved.

In addition, the noise filter 210 is provided with a capacitor 211, which is a capacitive load, so as to filter the noise of the AC power source. Here, since the capacitor 211 is a device whose phase is higher than the phase of the current, not only the noise of the AC power source is filtered but also the phase difference between the voltage and the current is higher than the phase of the voltage due to the inductive load It is possible to reduce the phase difference between the voltage and the current of the AC power source.

The power factor correction circuit 220 is connected to the R phase AC power supply line, the S phase AC power supply line, and the T phase AC power supply line separately to control the power factor of the R phase AC power, the S phase AC power, and the T phase AC power So that the phase difference between the voltage and the current can be individually reduced.

Specifically, the inductor 221 is provided in the power factor compensating circuit 220, thereby suppressing generation of harmonics and preventing an overcurrent from being generated at the time when the supply of the alternating-current power is started.

Since the inductor 221 is an inductive load and the current phase is higher than the phase of the voltage, the phase difference between the voltage and current of the three-phase AC power source is higher than the phase of the current by the capacitive load It is possible to reduce the phase difference between the voltage and the current of the AC power source.

The noise filter 210 and the power factor correction circuit 220 are provided with a plurality of noise filters 210 and a plurality of power factor correction circuits 220 for respective AC power supply lines, Each of the noise filter 210 and the respective power factor correction circuits 220 may be connected in parallel and each of the noise filter 210 and the power factor correction circuit 220 connected in parallel may be connected to each of the switch circuits 230 The operation of each of the noise filter 210 and the respective power factor correction circuits 220 connected to the specific AC power supply line can be individually determined according to the opening and closing of the respective switch circuits 230. [

The zero-cross switch circuit 240 is connected to an AC power supply line of a specific AC power supply among AC power supply lines of three-phase AC power supply. When the noise filter 210 and the power factor correction circuit 220 do not operate, Power supply is enabled, but the on / off state of the switch is determined when the instantaneous value of the AC voltage is around 0, so that the inrush current and the transient voltage can be suppressed.

On the other hand, when the automatic mode is selected, the control module 400 determines whether each of the noise filters 210 and the power factor of each of the switches, which are connected to the specific AC power supply line, It is also possible to determine whether the compensation circuit 220 is operating.

When the automatic mode is selected and the plurality of noise filters 210 connected in parallel are not operated, the control module 400 causes the switch of the zero switch circuit 230 to be turned on, When the current waveform of the AC power source is measured by the module 100 and the current waveform is measured, the measured current waveform is compared with the pre-stored current waveform model, and the noise of the measured current waveform is It is possible to determine whether the noise filter 210 is in operation or not by judging whether or not the noise filter 210 has exceeded a predetermined noise allowable range.

Specifically, when it is determined that the noise of the measured current waveform exceeds the preset noise tolerance range, the control module 400 controls the noise filter 210 of any one of the plurality of noise filters 210 connected in parallel, The current waveform of any AC power source is re-measured in a state in which any one of the noise filters 210 is operated, and the re-measured current waveform is compared with the pre-stored current waveform model, If it is determined that the noise exceeds the predetermined noise allowable range, the process of causing the other noise filter 210 to operate further is repeated, and the re-measured current waveform is compared with the pre-stored current waveform model, The number of operation of the plurality of noise filters 210 connected in parallel is increased until it is determined that the noise of the current waveform is within the predetermined noise tolerance range .

The control module 400 also allows the switch of the zero switch circuit 230 to be turned on when the plurality of power factor correction circuits 220 connected in parallel are not operating, The phase difference between the measured voltage and the current is within a predetermined phase difference allowable range, and determines whether or not the operation of the power factor correction circuit 220 Can be determined.

Specifically, when it is determined that the phase difference between the measured voltage and the current exceeds the predetermined phase difference allowable range, the control module 400 controls the power factor correction circuit 220 of any one of the plurality of power factor correction circuits 220 connected in parallel 220 is operated so that the phase difference between the voltage and the current of any AC power source is remeasured in a state in which one of the power factor correction circuits 220 is operated so that the phase difference between the re- If it is determined that the phase difference tolerance range is exceeded, the process of causing the other power factor compensation circuit 220 to further operate is repeated. If it is determined that the phase difference between the re-measured voltage and current is within the pre- The number of operation of the plurality of power factor correction circuits 220 connected in parallel can be increased.

3, when the operation of the noise filter 210 and the power factor correction circuit 220 is determined by a single switch, the control module 400 determines whether the noise of the measured current waveform The noise filter 210 and the power factor correction circuit 220 are further operated until it is determined that the phase difference between the re-measured voltage and current is within the preset tolerance of the phase difference, And a more detailed description related thereto will be described later with reference to FIG.

If the manual mode is selected, the control module 400 determines whether the noise filter 210 and the power factor correction circuit 220 are operated or not according to the input signal generated through the input module 300, The number of operation of the plurality of noise filters 210 and the power factor correction circuit 220 provided in parallel can be determined.

5 is a diagram illustrating the configuration of an output module 500 of an intelligent electricity saving system according to an embodiment of the present invention in greater detail.

The output module 500 is a module for measuring the current and voltage obtained by separately measuring the current and voltage of the R-phase AC power supply line, the S-phase AC power supply line and the T-phase AC power supply line, Or when the waveform of the current is improved by the power saving module 200 and the phase difference between the voltage and the current is decreased, the waveform of the current measured before and after the improvement obtained through the measurement module 100 A first output LED and a second output LED may be provided in order to distinguish and output information about the measured voltage and current before and after compensation of information and power factor.

The first output LED is provided with individual LEDs so that the information to be output by the output module 500 can be checked as to whether it is current, voltage or power consumption depending on whether the LED is on or not. Usage can be displayed numerically.

Here, the first output LED and the second output LED may be separately provided for each AC power supply line of the three-phase AC power source so that information to be output is displayed separately. That is, the first output LED 510-1 and the second output LED 520-1 for the R-phase AC power source shown in FIG. 5, the first output LED 510-2 and the second output LED 510-2 for the T- 520-2, and a first output LED 510-3 and a second output LED 520-3 for the S phase AC power source, respectively.

In addition, the output module 500 is provided with a MODE LED, and can distinguish whether the output current, voltage, or power consumption is before the improvement of the current waveform and before the power factor correction, after the improvement of the current waveform, and after the power factor correction. For example, when the power saving module 200 does not operate, the MODE LED is turned off, and it can be recognized that the measured information is before the improvement of the current waveform and before the power factor compensation, The MODE LED can be turned on when the current waveform is improved and the phase difference between the voltage and the current is reduced.

FIG. 6 is a diagram for explaining a process of improving a current waveform and compensating a power factor according to a phase difference between a voltage and a current, using an intelligent electricity saving system according to an embodiment of the present invention.

The intelligent electricity saving system 10 according to the present embodiment is configured such that each AC power source connected to the three-phase AC power source through the measurement module 100 The current and voltage are separately measured on the supply line (S610).

Specifically, the intelligent electricity-saving system includes an R-phase AC power source, an S-phase AC power source, and an R-phase AC power source through a measurement module 100, which is separately connected to an R phase AC power supply line, an S phase AC power supply line, The current of the T phase AC power supply can be measured separately and the voltage of the R phase AC power, the S phase AC power, and the T phase AC power can be measured.

The current and voltage are measured for each AC power supply line, and when the automatic mode is selected, the control module 400 controls the current waveform and the voltage and current (current) according to each AC power supply line among the information stored in the storage module 600 (Step S620). In step S620, it is determined whether there is information indicating that the phase difference of the first and second signals is identical.

That is, the control module 400 can determine whether there is the same information among the previously stored information regarding the numerical value of the current and voltage of the specific AC power source, the phase difference between the current waveform and the current and voltage (S620) , The control module 400 determines that the same information does not exist (S620-No), the plurality of noise filters 210 connected to the specific AC power supply line and the plurality of power factor correction circuits 220 are both operated The current waveform of the specific AC power source is measured through the measurement module 100. When the current waveform is measured, the measured current waveform is compared with the previously stored current waveform model (S625), and the measured current waveform It can be determined whether the noise exceeds the predetermined noise allowable range (S630).

At this time, if it is determined that the noise of the measured current waveform exceeds the preset noise tolerance range (S630-No), the control module 400 determines that any of the plurality of noise filters 210 connected in parallel 210) is operated (S640). In the state in which one of the noise filters 210 is operated, the current waveform of any AC power source is re-measured, and the re-measured current waveform is compared with the previously stored current waveform model If it is determined that the noise of the re-measured current waveform exceeds the predetermined noise allowable range, the process of causing the other noise filter 210 to further operate is repeated. If the re-measured current waveform and the pre- The model is compared to compare the re-measured current waveform with the pre-stored current waveform model until it is determined that the noise of the re-measured current waveform is within the predetermined noise tolerance range A plurality of noise filters 210 connected in parallel can be additionally operated one by one.

If it is determined that the noise of the measured current waveform is within the preset noise tolerance range (S630-Yes), the control module 400 controls the noise filter 210 to adjust the number of operations of the noise filter 210, The phase difference between the voltage and the current of the specific AC power source is measured through the measurement module 100. When the phase difference between the voltage and the current is measured, The allowable range is compared (S645), and it is determined whether or not the phase difference between the measured voltage and the current is within the preset tolerance of phase difference (S650).

At this time, if it is determined that the phase difference between the measured voltage and current exceeds the pre-set phase difference allowable range (S650-No), the control module 400 determines that any one of the plurality of power factor correction circuits 220 connected in parallel The phase difference between the voltage and the current of any AC power source is re-measured in a state in which the power factor correction circuit 220 is further operated (S660) and one of the power factor correction circuits 220 is further operated, If it is determined that the phase difference between the measured voltage and current has exceeded the predetermined phase difference allowable range, the process of causing the other power factor correction circuit 220 to further operate is repeated, and the phase difference between the re- The plurality of power factor correction circuits 220 connected in parallel each time the phase difference between the re-measured voltage and current is compared with the predetermined phase difference allowable range until it is determined that the phase difference is within the pre- Each can be added to the operation.

If it is determined that the phase difference between the re-measured voltage and the current is within the predetermined phase difference tolerance range, the control module 400 determines that both the noise filter 210 and the power factor correction circuit 220 are not operated It is judged that the information of the phase difference between the current waveform and the voltage and the current and the noise of the remeasured current waveform are within the predetermined noise tolerance range and the phase difference between the remeasured voltage and current is within the predetermined phase difference tolerance range The information on the number of operation of the noise filter 210 and the number of operation of the power factor correction circuit 220 may be matched and stored in the storage module 600 in operation S670.

If it is determined that the same information exists (S620-Yes), the control module 400 refers to the number of operations of the noise filter 210 and the number of operations of the power factor correction circuit 220, The number of operations of the noise filter 210 and the power factor correction circuit 220 can be determined quickly (S680).

Accordingly, when the voltage and current are measured in the same way in the future, it is possible to quickly determine the number of operations of the noise filter 210 and the power factor correction circuit 220, thereby effectively improving the waveform of the current, And the amount of electricity used can be reduced.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limiting the scope of the invention as defined by the appended claims. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

100: Measurement module 110: Current measurement module
120: voltage measurement module 200: power saving module
210: Noise filter 211: Capacitor
220: power factor correction circuit 221: inductor
230: Switch circuit 231: Switch element
240: zero cross switch circuit 300: input module
400: Control module 500: Output module
510: first output LED 520: second output LED
511: LED element
600: storage module 700: power supply module

Claims (10)

A measurement module for measuring voltage and current of a three-phase AC power source supplied from the outside;
A power saving module for filtering the noise and reducing a phase difference between a voltage and a current of the three-phase AC power source so that the amount of use of the three-phase AC power source is reduced so that generation of noise of the three-phase AC power source is suppressed; And
And a control module for individually determining whether each of the noise filter and the power factor correction circuit operates according to the phase difference between the current waveform of the three-phase AC power source and the voltage and current of the three-phase AC power source measured by the measurement module and,
The measurement module comprising:
R phase AC power supply line, S phase AC power supply line and T phase AC power supply line so that the voltage and current of R phase AC power, S phase AC power and T phase AC power are measured separately for each AC power source Connected individually. And a voltage measuring module connected to the R-phase AC power supply line, the S-phase AC power supply line, the T-phase AC power supply line, and the N-phase AC power supply line, Respectively,
The power-
The S phase AC power supply line, the T phase AC power supply line, and the R phase AC power supply, the S phase AC power supply, and the T phase AC power supply are individually connected to the R phase AC power supply line, the S phase AC power supply line, Phase alternating current power source, the S phase alternating current power source, and the T phase alternating current power source,
The power-
A S phase AC power supply line, and a T phase AC power supply line, wherein the R phase AC power supply line, the S phase AC power supply line, and the T phase AC power supply line are each provided with a noise filter for improving the current waveform of the current, The plurality of noise filters and the plurality of power factor correction circuits are connected in parallel to each of the connected AC power supply lines,
The control module includes:
Wherein the operation of the plurality of noise filters and the plurality of power factor correction circuits connected in parallel for each AC power supply line is determined by comparing the current waveforms of the R-phase AC power, the S-phase AC power, and the T- Are individually determined according to the phase difference,
The control module includes:
When the plurality of noise filters connected in parallel are not operating, when the current waveform of any one of the three-phase AC power supplies is measured through the measurement module, the measured current waveform and the pre-stored current waveform model are compared Wherein when the noise of the measured current waveform is determined to exceed a predetermined noise tolerance range, any one of the plurality of noise filters connected in parallel is operated,
The current waveform of any one of the AC power supplies is remeasured in the state in which any one of the noise filters is operated and the re-measured current waveform is compared with the pre-stored current waveform model, Repeats the process of causing another noise filter to operate further if it is determined that the predetermined noise tolerance range is exceeded, comparing the re-measured current waveform with the pre-stored current waveform model, The number of operation of the plurality of noise filters connected in parallel is increased until it is determined that the noise of the waveform is within the predetermined noise tolerance range. delete delete The method according to claim 1,
The control module includes:
The S phase AC power source, the T phase AC power source, and the R phase AC power source, the S phase AC power source, and the T phase AC power source, So that information on the phase difference between the voltage before and after the decrease in the phase difference of the voltage and the current of the voltage and current is discriminated and outputted. delete delete The method according to claim 1,
The control module includes:
Wherein when the noise filter and the power factor correction circuit are operated by one switch, it is determined that the noise of the measured current waveform is within the predetermined noise tolerance range, Phase alternating-current power supply in a state where the number of operation of the noise filter is maintained, and determines whether or not the phase difference between the measured voltage and the current is within a predetermined allowable phase difference range However,
Wherein the power factor correction circuit further comprises a power factor correction circuit that is connected in parallel to the power factor correction circuit,
The phase difference between the voltage and the current of the AC power source is re-measured in a state in which one of the power factor correction circuits is further operated so that the phase difference between the re- Repeats the process of causing the other of the power factor correction circuits to operate further, repeats the process of further operating the other power factor correction circuit until the phase difference between the re-measured voltage and current is within the pre- So that the number of operation of the plurality of connected power factor correction circuits is increased. 8. The method of claim 7,
The control module includes:
The phase difference between the current waveform and the voltage and the current measured when the plurality of noise filters or the plurality of power factor correction circuits connected in parallel are not operated for each AC power source, And the information on the number of operation of the noise filter and the number of operation of the power factor correction circuit are matched and stored for each AC power source. 9. The method of claim 8,
The control module includes:
The current waveform and the voltage and current measured when the plurality of noise filters or the plurality of power factor correction circuits connected in parallel do not operate among information stored in the voltage and current of the three-phase AC power source measured through the measurement module If it is determined that there is the same information as the information on the phase difference, information on the number of operation of the noise filter and the number of operations of the power factor correction circuit, which are matched and stored, The number of operation of the intelligent electricity saving system. 9. The method of claim 8,
The measurement module comprising:
When the R-phase AC power supply line, the S-phase AC power supply line and the T-phase AC power supply line are individually connected, it is sensed that an overcurrent occurs or a supply of the AC power is cut off to each AC power supply line ,
The control module includes:
If it is determined that an overcurrent occurs in one of the AC power supply lines of the respective AC power supply lines through the power saving module or the supply of AC power is interrupted, the overcurrent occurs or the AC power supply To cause a warning alarm to be issued to the user,
Information on the measured current and voltage immediately before the occurrence of the overcurrent or the occurrence of the overcurrent in the alternating-current power supply line in which the supply of the alternating-current power is interrupted or the supply of the alternating-current power is cut off, Or the information about the noise filter and the power factor correcting circuit which are connected to the AC power supply line which is cut off the supply of the AC power are matched and stored.

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