KR100655245B1 - High efficiency plasma inverter - Google Patents

Abstract

A high efficiency plasma inverter is provided to reduce unnecessarily wasted power by supplying stable current to each component through a PFC(Power Factor Collection) circuit. In a high efficiency plasma inverter, a surge protection circuit(100) protects a panel and an inverter when over input voltage is inputted due to the lightning or counter electromotive force. An input filter unit(110) prevents a noise component or high frequency noise from flowing to a commercial power side by using a noise filter. A rectifying circuit unit(120) converts the noise filtered commercial power to a DC component for the inverter. A reactor unit(130) stores a pulsating wave introduced from the rectifying circuit unit(120). A smoothing circuit unit(140) generates stable voltage from the reactor unit(130). A PFC switching unit(150) of a PWM(Pulse Width Modulation) method controls pulse width to maintain PFC output voltage uniformly. A PFC controlling unit(160) compensates a power factor by coinciding a current phase of commercial power with a voltage phase. An auxiliary power unit(170) supplies DC voltage power of each device inside the inverter. An MCU(Micro Controller Unit) unit(180) controls the lighting shape of a panel by the voltage generated from the auxiliary power unit(170). A panel state detecting circuit unit(190) automatically detects the breakage of panel, short circuit of line or short of panel. A panel controlling unit(200) sets an oscillating point for each panel. A panel switching unit(210) switches PFC power by receiving a pulse output signal from the panel controlling unit(200). A transformer unit(220) performs vibration and transformation according to a capacitance component and an applied frequency value and turns on the panel.

Description

High Efficiency Plasma Inverter

1 is a circuit diagram showing a conventional basic inverter.

Figure 2 is a block diagram showing the overall configuration of a high efficiency plasma inverter according to the present invention.

3 is a graph showing the state signal of the panel detected by the panel state detection circuit of the high efficiency plasma inverter according to the present invention.

Figure 4 is a block diagram showing another embodiment for connecting a panel with a high efficiency plasma inverter according to the present invention.

** Description of the symbols for the main parts of the drawings **

100: surge protection circuit 110: input filter

120: rectifier circuit portion 130: reactor portion

140: smoothing circuit unit 150: PFC switching unit

160: PFC control unit 170: auxiliary power supply

180: MCU unit 190: panel state detection circuit unit

200: panel control unit 210: panel switching unit

220: transformer part

The present invention relates to an inverter that turns on a plurality of panels by one inverter and enables lighting by dividing one panel into blocks, and generates high frequency sine waves required for a panel for plasma advertisement by receiving commercial power. It is a high-efficiency plasma inverter that maximizes the capacity, high voltage, and power consumption to protect the panel by sensing various states of the panel connected to the panel and control the lighting pattern of each panel.

In general, an inverter is a device that converts DC power into AC power, and is distinguished from a converter that converts AC power into DC power. However, in recent years, an inverter that converts DC into AC with the development of the power electronics part. Inverter can be supplied cheaply, and it can be said that it has converter function and inverter function, and there is also a function to keep the frequency constant or convert according to the purpose of use.

The principle of the inverter is to control the rotational speed of the induction motor by converting a commercial AC power source into a DC power source, and then into an AC of arbitrary frequency and voltage. In a prior term, it refers to a power converter that converts a DC power source into an AC power source, but generally refers to a power converter that controls voltage and frequency of an AC power source.

The actual configuration of the inverter as described above is complicatedly formed into a converter (Converter) part for converting commercial AC power to DC power and an inverter (Inverter) part for cutting the DC power and converting to AC power with a changed voltage and frequency, Usually referred to as an inverter (Inverter).

1 is a circuit diagram showing a conventional basic inverter, as shown in FIG. 1, the input power is AC power, rectifies the AC power to DC power, and smoothes the DC power to make a DC power. Is inputted to the transformer by changing the polarity by alternating + and-by switching element (mainly IGBT). The transformer secondary is an AC power source, with separate drive boards and control boards that signal the switching elements, allowing the AC power characteristics to be created in the desired manner.

The inverter as described above has a problem in that it is not suitable for a device having a low output voltage and is suitable for a device having a low capacity.

In addition, damage to the circuit board including the inverter, which occurs due to breakage and disconnection of the device connected to the inverter, causes a short circuit or a deterioration of the human body.

In addition, the inverter that turns on the existing display panel does not turn on a plurality of panels by one inverter or divide the panel into blocks, and there is a problem in that the aesthetic satisfaction is not obtained because there is no change in lighting.

In order to solve the above problems, an object of the present invention is to provide an inverter that receives a commercial power source and generates a high frequency sine wave required for a plasma advertisement panel.

The present invention has a built-in protection circuit for detecting various states of the panel inside the inverter to detect the damage of the panel, the non-fastening of the panel, the overload condition due to the panel failure and to provide a function to prevent human body electric shock accidents due to rain leakage in the rain There is another purpose.

Another object of the present invention is to provide a function of gradually changing the backlight brightness of a panel from dark to bright when the power of the panel is turned on and off, and to simultaneously or sequentially turn on one panel or a plurality of panels. have.

In order to achieve the above object, the present invention relates to an inverter that turns on a plurality of panels by one inverter and enables lighting by dividing one panel by block, and the inverter receives a commercial power source for plasma advertisement. It generates the high frequency sine wave required for the panel, and the protection circuit which detects various states of the panel is built in to protect the panel and control the lighting pattern of each panel simultaneously or sequentially. It is a high efficiency plasma inverter that maximizes power consumption.

Hereinafter, with reference to the accompanying drawings to describe the present invention in detail.

Figure 2 is a block diagram showing the overall configuration of a high efficiency plasma inverter according to the present invention.

 As shown in FIG. 2, in the inverter for lighting a plurality of panels with one inverter, the inverter includes a panel when excessive input voltage is introduced by lightning or induction electromotive force of an inductive electric machine after AC power, which is a commercial power source, is input. A surge protection circuit unit 100 protecting the inverter;

An input filter unit that prevents leakage to the commercial power supply using a noise filter for noise components of commercial power inputted through the surge protection circuit unit 100 or high frequency noise generated inside the inverter. 110;

A rectifier circuit unit 120 for converting the commercial power whose noise is filtered by the input filter unit 110 into DC components required for an inverter;

A reactor unit 130 for storing the pulse flow introduced through the rectifier circuit unit 120;

A smoothing circuit unit 140 for generating a stable voltage in the reactor unit 130;

A power factor collection (PFC) switching unit 150 of a pulse width modulation (PWM) type controlling a pulse width to charge or discharge the reactor unit 140 and to maintain a constant power factor collection (PFC) output voltage; ;

A power factor collection (PFC) control unit 160 for correcting a power factor by matching a current phase of a commercial power supply modified by the input filter unit 110, the rectifier circuit unit 120, and the smoothing circuit unit 140 with a voltage phase;

An auxiliary power supply unit 170 that receives the voltage rectified by the rectifier circuit unit 120 and supplies DC voltage power of various elements in the inverter;

MCU (Micro Controller Unit) unit 180 for controlling the lighting pattern of the panel by the voltage generated by the auxiliary power supply unit 170;

A panel state sensing circuit unit 190 for automatically detecting a non-fastening of a panel, a breakage of the panel, a line break connected to the panel, and a short state before the panel under the control of the micro controller unit (MCU) unit 180;

The panel control unit 200 operates whether the frequency is generated by the ON / OFF signal from the microcontroller unit (180) and determines a point to be resonated for each panel as a part for determining a corresponding frequency for each panel. Wow;

A panel switching unit 210 which receives a pulse output signal from the panel control unit 200 and switches a PFC power;

A transformer unit 220 which performs a resonance operation and a transformer operation according to the capacitance component generated in the panel and the applied frequency value based on the amount of power transmitted from the panel switching unit 210 and turns on the panel; Plasma inverter.

Hereinafter, the high efficiency plasma inverter of the present invention configured as described above will be described in more detail for each component.

When the commercial power of AC 90V ~ 264V / 47HZ ~ 63HZ is input from the outside to the inverter, the surge protection circuit unit 100 is excessive input by the lightning or induction electromotive force of the induction motor against the input commercial power The panel and the inverter are protected when a voltage is introduced, and the surge protection circuit unit 100 forms a protection circuit using a varistor.

The commercial power introduced through the surge protection circuit unit 100 uses normal mode noise and common mode noise by using a noise filter in the input filter unit 110. To prevent noise components flowing into commercial power sources such as high frequency noise generated when switching inverters, etc., to be returned to the ground, or to be exhausted through heat generation, to prevent other components using commercial power. Do not give.

The commercial power transmitted through the input filter unit 110 is rectified by the rectifier circuit unit 120 to convert into a pulse voltage required for the inverter input, and commercial power is input to the inverter using a power thermistor. In this case, a large amount of current flows instantaneously to charge the capacitor, and has a function of suppressing excessive instantaneous inrush current generated.

The pulse wave of 120 HZ introduced through the rectifier circuit unit 120 is stored in the reactor unit 130. In addition, the reactor unit 130 is an energy tank that accumulates energy of rectified voltage, and the reactor unit 130 is generated by a power factor collection (PFC) switching operation in a power factor collection (PFC) switching unit 150 which is a switching unit for charging or discharging. Pulse Width Modulation (PWM) pulses are converted.

The pulse width modulation (PWM) pulse of the reactor unit 130 flows into the smoothing circuit unit 140 to smooth the DC 380V to 400V required for the inverter.

Here, the PFC (Power Factor Collection) switching unit 150 is input as a PWM (Pulse Width Modulation) switching unit for controlling the pulse width to maintain a constant PFC (Power Factor Collection) output voltage to DC 380V ~ 400V It keeps constant voltage at all times even if voltage fluctuates.

In general inverter or power supply device, since the voltage and current phase of the commercial power applied to the power is a phase deviation occurs due to the coil component and the condenser component, the inverter also smoothes the input filter unit 110 and the rectifier circuit unit 120, Since the phase deviation occurs while passing through the circuit unit 140, the power consumption of the commercial power increases, so the PFC (Power Factor Collection) control unit 160 is a power factor correction, which matches the current phase of the commercial power with the voltage phase to improve the power factor. As a part of compensation, the deviation of two phases is reduced to maximize the reduction of power consumption of commercial power.

Therefore, switching mode power supply (SMPS) or inverter, which is a modular power supply that converts electricity supplied from outside to suit various electric devices, has energy efficiency of 50% to 60%. On the other hand, it has an energy efficiency of 90% or more by a PFC (Power Factor Collection) circuit, that is, a power factor correction circuit.

In addition, the PFC control unit 160 detects an output voltage to generate a constant voltage of a power factor collection (PFC) output voltage of DC 380V to 400V, and converts the detected output voltage into a power factor collection (PFC). When the voltage decreases by comparing with the reference voltage inside the dedicated IC (Integrated Circuit), the pulse width of the PWM (Pulse Width Modulation) waveform is widened. On the contrary, when the voltage rises, the pulse width is narrowed to maintain constant DC voltage at all times.

The PFC control unit 160 may protect the panel from an overvoltage internally to protect the panel when the PFC output voltage rises more than necessary. Has the function to

The auxiliary power supply unit 170 that receives the voltage rectified by the rectifier circuit unit 120 and generates and supplies power of various integrated circuits (ICs) used in the inverter, converts the voltage received from the rectifier circuit unit 120 to DC 10V. Supply voltage of ~ 15V.

The MCU (Micro Controller Unit) unit 180 which receives the voltage generated by the auxiliary power supply unit 170 controls the lighting pattern of the panel as a core element inside the inverter.

The MCU (Micro Controller Unit) unit 180 programs the program of the gradation function having the effect of changing the brightness step by step when the panel is turned on in addition to the basic function of turning on / off the panel. It is possible to have various changes such as built in the unit 180 to give the panel a glossiness and a subtle change, and to light sequentially by dividing each block within one panel and also to panel # 1 to panel #N. Built-in drive circuit that determines whether the panel lights up at the same time or sequentially, and adjusts the light by turning it like the volume of the radio, so that each panel can be precisely and precisely adjusted to the desired brightness. Various lighting programs can be changed accordingly.

And the MCU (Micro Controller Unit) unit 180 includes a temperature sensor for detecting the internal temperature of the inverter to protect the inverter from the temperature sensor when the inverter is overheated.

In addition, the MCU (Micro Controller Unit) unit 180 is connected to the panel state sensing circuit unit 190 and performs various protection operations for protecting the panel according to the state signal detected by the panel state sensing circuit unit 190.

3 is a graph showing the state signal of the panel detected by the panel state detection circuit of the high efficiency plasma inverter according to the present invention.

As shown in FIG. 3, when the current supplied to the output of the inverter is monitored and the current is detected in the O ↔ I ₁ section, the panel state sensing circuit unit 190 recognizes that the panel is not fastened and supplies it to the panel. Cut off the power. Then, the inverter output is again sent out every second to sense the current of the supplied output, and if the current is the same section, the Hiccup operation of monitoring the output of the inverter is repeated every second.

If the current of I ₁ ↔ I ₂ is detected while repeating the Hiccup operation as described above, the panel is recognized as normal fastening, indicating that it is in a normal output state and transmitting to the MCU (Micro Controller Unit) to turn on the panel. Normalize

In addition, when the detection signal of the panel state gimji circuit unit 190 appears in the I ₂ ↔ I ₃ section, it is recognized as an abnormal state such as a breakage or short of the panel, and it is determined that an overcurrent has been output. Repeat the Hiccup operation in section I ₁ to determine whether the panel is normalized.

Therefore, the panel state detecting circuit unit 190 automatically detects a panel not fastened (no load), a panel broken (no load or overload), a line break connected to the panel, and a short state of the panel due to the above operation. The state is sensed and the power is cut off to suppress electric leakage in rainy days, electric shock accidents or leakage from other devices.

The panel controller 200 which operates whether or not a frequency is generated by the ON / OFF signal from the micro controller unit (MCU) unit 180 sets a point to be resonated for each panel as a part for determining a corresponding frequency for each panel. .

The circuit structure of the panel switching unit 210 which receives the pulse output signal from the panel control unit 200 to switch the PFC (Power Factor Collection) power has a clamp mode switching structure, and the switched PFC (Power) Factor Collection) transmits power to the transformer unit 220.

The transformer unit 220 which performs the resonance operation and the transformer operation according to the capacitance component generated in the panel and the frequency value applied to the panel switching unit 210 substantially turns on the panel. .

In addition, the panel controller 200, the panel switching unit 210, and the transformer unit 220 are configured to have the same number as the number of panels connected to the inverter.

Figure 4 is a block diagram showing another embodiment for connecting a panel with a high efficiency plasma inverter according to the present invention.

As shown in FIG. 4, only one panel controller 200, a panel switching unit 210, and a transformer unit 220 are provided for each panel connected to the inverter to control the lighting of the panel. .

As described above, the preferred embodiment according to the present invention has been described, but the present invention is not limited to the above-described embodiment, and the present invention is not limited to the scope of the present invention as claimed in the following claims. Anyone with knowledge of the present invention will have the technical spirit of the present invention to the extent that various modifications can be made.

As described in detail above, the high-efficiency plasma inverter according to the present invention uses a PFC (Power Factor Collection) circuit to supply more stable current to each component, reduce unnecessary power consumption, and unnecessary waste current. It is effective to prevent the temperature rise by switching to heating.

In addition, the high-efficiency plasma inverter according to the present invention has a built-in protection circuit for detecting the various states of the panel inside the inverter detects the overload condition due to panel breakage, non-fastening of the panel, panel failure, human body due to a short-circuit in the rain There is an effect that can perform a protective function to prevent the detection of accidents.

In addition, the high-efficiency plasma inverter according to the present invention has a gradation function and a drive circuit capable of sequentially lighting each block within a panel and simultaneously lighting a plurality of panels simultaneously or sequentially. It can make a variety of changes and has an aesthetic effect.

Claims (9)

In an inverter that turns on a plurality of panels by one inverter and enables to light by dividing one panel by blocks, A surge protection circuit to protect the panel and the inverter when an excessive input voltage is introduced by a lightning strike or an induction electromotive force of an inductive electric machine after AC power, which is commercial power, is input; An input filter unit which prevents leakage to the commercial power source using a noise filter against noise components of commercial power inputted through the surge protection circuit unit or high frequency noise generated inside the inverter; A rectifier circuit unit for converting the commercial power, from which the noise is filtered by the input filter unit, into DC components required for an inverter; A reactor unit for storing the pulse flow introduced through the rectifier circuit unit; A smoothing circuit unit generating a stable voltage in the reactor unit; A power factor collection (PFC) switching unit for controlling a pulse width to charge or discharge the reactor unit and to maintain a constant power factor collection (PFC) output voltage; A power factor collection (PFC) control unit configured to compensate for power factor by matching a current phase of a commercial power supply modified by the input filter unit, rectifier circuit unit, and smoothing circuit unit with a voltage phase; An auxiliary power supply unit receiving the voltage rectified by the rectifier circuit unit and supplying DC voltage power of various elements in the inverter; MCU (Micro Controller Unit) unit for controlling the lighting pattern of the panel by the voltage generated by the auxiliary power supply; A panel state sensing circuit unit for automatically detecting a panel not connected, a panel being broken, a line break connected to the panel, and a short state of the panel by controlling the micro controller unit (MCU); A panel controller which operates whether or not a frequency is generated by an ON / OFF signal from the micro controller unit (MCU) unit and sets a point to be resonated for each panel as a part for determining a corresponding frequency for each panel; A panel switching unit configured to switch a PFC (Power Factor Collection) power by receiving a pulse output signal from the panel control unit; A transformer unit configured to perform a resonance operation and a transformer operation according to a capacitance component generated in a corresponding panel and a frequency value applied to the amount of power transmitted from the panel switching unit, and to turn on a panel; High efficiency plasma inverter. The method of claim 1, The surge protection circuit unit is a high efficiency plasma inverter, characterized in that the configuration of the protection circuit using a varistor (Varistor). The method of claim 1, The rectifier circuit unit high efficiency plasma inverter, characterized in that for suppressing excessive instantaneous inrush current generated when the commercial power supply is initially turned on. delete The method of claim 1, The PFC control unit maintains a constant DC voltage by adjusting a pulse width of a pulse width modulation (PWM) waveform. The method of claim 1, The PFC control unit protects the panel when an overvoltage of the PFC output voltage occurs. The method of claim 1, The MCU (Micro Controller Unit) is a high efficiency plasma inverter, characterized in that when the panel is turned on (Gradation) function. The method of claim 1, The MCU (Micro Controller Unit) unit lights a plurality of panels at the same time or sequentially and a high efficiency plasma inverter, characterized in that for changing the various lighting by adjusting the brightness desired by the user for each panel. delete

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