KR100436527B1 - Electric power energy saver by using range between 500㎚ ~ 600nm and 1,000 ~ 10,000㎚ optical filter and by using of semi-conductor excited the energy of balance energy - Google Patents

Abstract

The present invention relates to an energy-saving device based on information control of a semiconductor excited with an optical filter and an energy balance energy, and a manufacturing device and a manufacturing method of the energy saving device. It is related to the electric power saving device. When looking at the dynamic structure of energy, when one pressure is applied to another system, a reaction resistance occurs, and the system under pressure refuses to accept any information, property, or function. As a result, the friction force that causes the resistance is generated and more energy is required in the system under pressure, and the present invention converts the resistance into a buffer force by controlling the direction and properties of the motion so that the friction force does not actually occur but rather fuses with each other. Energy using principle that only works Developing energy-saving devices that reduce burnout has an excellent effect of reducing energy consumption.

Description

Energy-saving device based on optical control of infrared range in the range of 1,000 ~ 10,000 ㎚ and visible range in the range of 500-600 nm, energy control energy-excited semiconductor, manufacturing apparatus and manufacturing method of the energy-saving device {Electric power energy saver by using range between 500 nm to 600 nm and 1,000 to 10,000 nm optical filter and by using of semi-conductor excited the energy of balance energy}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an energy saving device based on information control of an optical filter and an energy balanced energy excited semiconductor, and an apparatus and a manufacturing method of the energy saving device. The present invention relates to a power saving device and method.

1A is a circuit diagram and a pulse waveform diagram of an inverter for converting DC power to AC power in the conventional power saving device, respectively, in which the accumulated energy of the load is increased in the first period of the half cycle in which the silist 1, 2 is triggered. 4) back to the power supply, and in the case of the preceding power factor, the diode (3) (4) is energized in the second half of the cycle, which is called an inverting device.

A device that induces a power saving effect by controlling the rotation speed by converting the frequency by using the inverse converter has been mainstream.

1b shows a conventional frequency conversion of AC current as a power converter that performs frequency conversion of AC current to a cyclo converter circuit, which is a power converter, but 3 and 5 harmonics are generated in the process of frequency conversion. In case of inducing malfunction or reducing the life of the motor and malfunctioning or distortion of the waveform, there is a problem that can not be used at a high pressure of more than 660V decisively.

1C is a series resonant circuit diagram using an electronic ballast using a series / parallel resonant inverter used in a conventional lighting. Capacitor 5 and inductor 6 constitute a series resonant circuit for stable lighting of a load lamp. (7) is for starting the load lamp.

In terms of its function, it is appropriate to cope with the fluctuation of input voltage and high temperature and humidity by inserting lamp diversification and self-protection function that can attach several same or different lamps to one electronic ballast. By inserting the dimming function and making it highly functional, it takes the disadvantage of the magnetic circuit ballast and effectively saves the power. This reduces the size of the magnetic element and contributes to the compact and light weight of the ballast. Although high-efficiency power conversion is possible due to the development of high frequency switch, it is necessary to use a large capacity capacitance to reduce the burden on the device by suppressing the input voltage variation rate of the DC-DC converter, so that a large amount of energy is charged in a short time. Large current flows and the rectifier's input current type is discontinuous and Due to the peripheral device it is adversely affected by distortion of the input current and the high frequency of the input voltage.

FIG. 1D is a circuit diagram of a power factor improvement circuit capable of converting high-efficiency power in high frequency switching, which lowers the total high frequency distortion and operates the switching power supply as if it is a resistance load in the rectifier input stage.

Therefore, the power factor improvement circuit sets the input current according to the input voltage to make the voltage / current ratio constant so that the power factor becomes 1, but when the voltage / current ratio is not constant, phase shift or high frequency distortion occurs to lower the power factor. .

The reactance of the input impedance of the power factor improving circuit causes a phase shift of the input current with respect to the input low voltage, thereby lowering the power factor, and the harmonic distortion is a value representing the nonlinear degree of the input impedance of the power factor improving circuit.

Therefore, the change in the input impedance as a function of the input voltage causes distortion of the input current and the power factor is reduced due to the distortion, so that the effect of electric power saving is weak.

Another peak product for complex loads is a 1/10 capacity transformer-type linear decompression device, classified into a primary voltage coil and a secondary current coil wound on a TOROIDAL CORE, and wound on a voltage coil with five levels of voltage regulation. The ends of the voltage coil and current coil are connected in series to each other to use the inductive reactor designed to function as a series reactor so that the appropriate voltage and current can be controlled without deforming or damaging the AC power at all. It is a power saving device that adopts a new concept of control means that greatly improves the economics and reliability by making it possible to control.

This is not available for high capacity and high voltage as well. It is not suitable for precision machinery due to waveform distortion caused by artificial control of voltage, and due to the enlargement of machinery, it is restricted in installation place. There was no power saving device.

Accordingly, the present invention has been made to solve the above problems and an object of the present invention is a correction filter for adjusting the light intensity in a specific wavelength range of 500 nm to 600 nm in the visible region and 10 ³ nm to 10 ⁴ nm in the infrared region. Infrared filter and filter for visible and ultraviolet rays, and light, energy balance energy, in specific area in the active area of semiconductor are trapped and flowed to electric appliances or appliances connected to electric wires or tracks to improve operation efficiency It is to provide energy-efficient power savers for products such as electric motors, heaters, and lamps that receive energy.

The above object of the present invention is to eliminate the induced disturbance electromagnetic wave with the rectifying action, and to transmit a specific signal and specific energy, and when the energy equilibrium energy formed by the mid / infrared filter and the near-infrared filter is scanned on the semiconductor chip, The chip is ANDed at the input and input terminals of the chip, and the output value is transmitted to the input terminals CN1AC200V 1 and 2.In the same way, it is composed of a circuit having the functions of an OR gate in the mid-infrared region, an XOR gate in the near-infrared region, and a NAND function in the non-infrared region. thus the two circuits configured on the XY Cartesian robots and, with the visible range filter system and infrared range filter system, a belt conveyor, capable of producing an OP box and isolation using the energy balance of energy this device consisting of a control box 10 ³ Energy-saving device based on information control of semiconductor with excited optical filter and energy balance energy in the infrared range of ~ 10 ⁴ nm and visible range in the range of 500 nm to 600 nm And the manufacturing apparatus and manufacturing method thereof.

1A is a circuit diagram and a pulse waveform diagram of an inverter for converting DC power into AC power in a conventional power saving device,

1B is a cycloconverter circuit diagram of a conventional frequency conversion of AC power as a power converter;

1C is a series resonance circuit diagram using an electronic ballast using a series / parallel resonance type inverter used in a conventional lamp.

Figure 1d is a circuit diagram of a power factor improvement circuit capable of high efficiency power conversion in the conventional high frequency switching,

2 is a circuit diagram of eliminating rectification and induced disturbance electromagnetic waves in a preferred embodiment of the present invention, and controlling specific information by a low voltage electrical energy and light energy, and a circuit for transmitting and receiving a specific signal and specific energy.

3A is a plan view of an apparatus for manufacturing a power saver showing a preferred embodiment of the present invention;

Figure 3b is a side view of the manufacturing apparatus of the power saver showing a preferred embodiment of the present invention,

Figure 4 is a process chart showing step by step the manufacturing method of the present invention,

5 is a graph analyzing the power saving effect of a business building using the present invention power saver,

Figure 6 is a graph analyzing the power saving effect of the government office using the present invention power saver,

Figure 7 is a graph analyzing the power saving effect of the home using the power saver of the present invention.

Description of the main parts of the drawing

1, 2: Cylist 3, 4, 8, 9, 10, 11: Diode

5, 7, 18, 19, 20, 21: capacitor

6: inductor

12, 13, 14, 15, 16, 17, 26, 27: resistance

22: Input terminal 4 of U1PIC1654 / RC semiconductor chip

23: OSC1 / CLKIN input 16

24: Input terminal CN1AC220V 1

25: Input terminal CN1AC220V 2

28, 29: switch 30: motion control box

31: home position switch 32: X-Y Cartesian robot

33: inlet hole 34: home position return switch

35: operation switch 36, 37, 65: photosensor

38, 39: servo motor 40: working hand

41: linear motion bearing 42: cylinder

43: finger 44: visible filter 1

45: visible filter 2 46: visible filter 3

47: cable fixing device 48: visible light source

49: visible region filter system 50: dimming cap

51: belt conveyor 52: conveyor belt

53: sprocket 54: chain

55 geared motor 56 infrared filter system

57: mid-infrared filter 58: near-infrared filter

59: medium infrared light source 60: near infrared light source

61 Infrared Synthesis Filter 62 Infrared Cap

63: infrared station screw 64: infrared station investigation device

66: pin 67: pinhole

68: circuit board 69: lower power saver case

70: upper part of the power saver case 100-1: voltage transformer

100-2: U1PIC16C54 / RC Semiconductor Chip

Hereinafter, the configuration of the present invention will be described in detail with reference to the accompanying drawings for a preferred embodiment.

First of all, the present invention looks at the energy dynamic structure of the integrated electric power saving device systemized by the physical analysis method without the use of the engineering analysis method. Refuse to accept anything of nature, function, etc.

As a result, friction occurs in which resistance occurs, and the system under pressure requires more energy.

= Increases resistance when F = ma (1 + Δa) Δa> 0

The present invention mathematically converts the resistance shown in the above equation into a cushioning force by controlling the direction and property of the motion, so that the friction force does not actually occur, but rather only the affinity to fuse with each other reduces the exhaustion of energy.

∴ decreased resistance when F = ma (1 + Δa) Δa <0

Therefore, when the above formula is derived,

F = ma (1 + Δa) ----- (1)

m = F / (1 + Δa) ---- (1) '

W = 1 / 2mv ² ---- (2),

m = 2W / v ² ------ (2) 'Thus (1)' = (2) '

F / a (1 + Δa) = 2W / V ² ----- (3)

W = Fv ² / 2a (1 + Δa) ---- (3) '

Where a = v / t

= 1 W = 1 / 2Fv (1 + Δv) t ---- (4)

F: force, m: mass of material v: velocity, Δv: velocity displacement, a: acceleration, Δa: acceleration displacement, t: time, W: power energy

When the present invention is applied to the final equation, that is, the equation (4) which induces a new relationship, the frictional force (F) decreases in the case of Δv <0 and the power energy (W) decreases. The present invention will be described in detail with reference to FIGS. 2 to 7.

2 is a circuit diagram of eliminating rectification and induced disturbance propagation in a preferred embodiment and controlling specific information by a low voltage electrical energy and light energy, and a circuit for transmitting and receiving a specific signal and specific energy. , 18, 24, 25, 100-1 is used to eliminate the induced disturbance radio waves and to send and receive specific signals and specific energy. The circuit designed as above is called the circuit (A) and the circuit (A) When the current of the first ordinary voltage (110V, 220V, 380V, 440V) flows into the circuit, the low voltage is induced through the voltage transformer 100-1 by the capacitance. That is, circuit (A) induces the energy balance energy filtered by the infrared filter to the excited state and makes the environment of the initial inverted state.

The diodes 8, 9, 10, and 11 are to rectify and eliminate the induced disturbance electromagnetic waves.

A method of exchanging specific energy with a specific energy using resistors 12, 13, 14, 15, 16, 17 and capacitors 18, 19, 20, and 21, and exchanging specific signals with specific energy. Is a molecule or atom that occupies many energy levels, causing transitions between energy levels. In addition, in order to generate an inversion distribution, the atoms are left at a higher energy level, and the infrared wavelength (specific energy) of 1,000 nm to 10,000 nm filtered by the infrared filter is applied to the semiconductor (U1PCI16C54 / RC) by applying low voltage electricity. It induces optical pumping and delivers it in the form of pulse (special signal).

Next, by using the reference numerals 10, 11, 14, 15, 16, 17, 19, 20, 21, 22, 23, 26, 27, 28, 29, 100-2 specified by the electric and light energy of the low voltage The circuit designed as described above is referred to as a circuit (B), and the circuit (B) is an energy balance formed by a mid-infrared filter and a near-infrared filter in the U1PIC16C54 / RC semiconductor chip 100-2. When the energy (EVE-Energy Balance Energy) is scanned, the output value input terminal CN1AC220V 1 (24), input terminal AND gated to MCLR / Vpp input terminal 4 (22), OSC1 / CLKIN input terminal 16 (23) of U1PIC1654 / RC semiconductor chip The circuit is transmitted to CN1AC220V 2 (25) and has the same function as an OR gate in the mid-infrared region, an XOR gate in the near-infrared region, and a NAND gate in the non-infrared region.

That is, it has the following logic.

entity muxp is port (s: in std_logic_vector (near-infrared downto mid-infrared));

4, 16: in std_logic;

Input terminal 21, input terminal 22: out std_logic);

end muxp;

arcitecture infrared of muxp is

begin

process (EVE, mid-infrared, near-infrared)

begin

case EVE is

when "EVE" => input terminal (21), input terminal (22) <= mid-infrared and near-infrared;

when "medium infrared" => LED1 (23) <= medium infrared or near infrared;

when "near-infrared" => LED1 (23) <= medium-infrared xor near-infrared;

when other => LED1 (23) <= medium-infrared nand near-infrared;

end case;

end process;

end infrared;

A switch 28 having the logic of the circuit as described above, applying the circuit and the resistors 26 and 27 and the voltage required to form the inverted charge density and the inverted layer on the semiconductor surface and are automatically controlled according to the strength thereof. And (29) to configure a circuit to control specific information by low-voltage electrical energy and light energy.

Figure 3a or 3b is an energy balance energy manufacturing apparatus of the preferred embodiment XY quadrature robot apparatus, visible filter system, infrared filter system, belt conveyor, OP box, control box, compressor It is composed of sha.

The X-Y quadrature robot device is a control system that picks up a circuit board and transfers it to three kinds of visible filter to irradiate light energy of the visible filter.

The visible filter system is a device for storing information in a semiconductor chip that adjusts wavelength by color and controls energy density by brightness.

The infrared filter system is a device that changes the vibration state of a material molecule and simultaneously emits light by an infrared vortex with an infrared screw to transfer energy to a semiconductor chip.

The belt conveyor is a device for transferring the circuit board from the visible filter to the infrared filter.

The O and P boxes operate all operations by integrating switches for work and operation.

The control box is a control device for all the devices constituting the system and the wavelength intensity of the visible and infrared range and the associated sensor automatic setting control device.

The compressor is an air generating device for driving with an X-Y quadrature robot device as an aerodynamic feeder.

Figure 4 is a process diagram showing a step-by-step manufacturing method of the power saver of the preferred embodiment will be described with reference to Figure 3a or 3b.

Placing the circuit board in the inlet and matching the origin (S1);

Moving the circuit board to a visible filter (S2);

After the visible light filter sends a light source to the visible filter system, storing information on the semiconductor chip to control the energy density as wavelength and luminance by using a visible filter (S3);

Transferring the circuit board to the infrared filter system by riding on the Kenbei belt whose speed is controlled by the geared motor (S4);

Synthesizing two infrared regions of a mid-infrared light source and a near-infrared light source and scanning them with an infrared cap to give the semiconductor chip a function of energy transition (S5);

When the finished substrate comes out to the infrared filter system through the conveyor belt step of stopping the stopper by the photosensor (S6);

Inserting the pin into the pinhole and binding the A circuit and the B circuit, and then assembled in the lower insulating case and completed by combining with the top of the power saver case (S7).

The step (S1) of placing the circuit board in the inlet and setting the home position presses the home position switch 31 of the motion control box 30 to insert the completed circuit board into the standby position before the XY orthogonal robot 32 is operated. To the XY orthogonal robot 32 by pressing the zero point return switch 34, and when the origin is confirmed, operating the operation switch 35 to move the XY orthogonal robot 32 toward the inlet 33. will be.

In the step (S2) of moving the circuit board to the visible filter, the photoelectric sensor 36 (37) (poto senser) is operated by placing the completed circuit board on the inlet 33 to operate the servo motors 38 and 39. By the servo motor 38, the working hand 40 picks up the circuit board by the operation of the linear motion bearing 41, the cylinder 42, and the finger 43, and the visible filter 1 (44), the visible filter 2 (45), visible region filter 3 (46).

After the visible light filter sends a light source to the visible light filter system, the step of storing the information on the semiconductor chip to control the energy density as the wavelength control and the luminance by using the visible filter (S3) is a visible light filter 1, 2 3 (44) (45) (46) is provided with visible light source (48) when power is supplied through cable fixing device (47) to send light source to visible filter system (49). By using the visible filter 1, 2, 3 (44) (45) (46) to filter between 500 nm and 600 nm through will be.

The step (S4) of transferring the circuit board to the infrared filter system by using the Kenbei belt whose speed is controlled by the geared motor is transferred to the conveyor belt 52 on the belt conveyor device 51, and the semiconductor chip is connected to the sprocket 53 and the chain. The circuit board is sent into the infrared filter system 56 by the speed of the Kenvey belt 52 which is controlled by the geared motor 55 composed of 54.

The step (S5) of synthesizing two infrared regions of the mid-infrared light source and the near-infrared light source and scanning them with an infrared cap to give an energy transition to the semiconductor chip is a mid-infrared filter between 10 ³ nm and 10 ⁴ nm. ) And the near-infrared filter 58 synthesize the two infrared rays through the infrared composite filter 61 when the mid-infrared light source 59 and the near-infrared light source 60, which are powered through the infrared cable, emit light. By scanning the infrared cap 62 to change the vibration state of the material molecules, and gives the semiconductor chip a function of changing the energy by generating an infrared vortex with the infrared screw 63.

When the finished substrate comes out to the infrared filter system through the conveyor belt, the step of stopping adjustment by the photosensor (S6) increases the refractive index of the light trapping, that is, the infrared filter by using the infrared irradiation device 64. A substrate that traps and excites energy balance energy in the infrared region energy to increase the operation efficiency of the electric device and maximizes the power saving efficiency is completed and exits the infrared filter system 56 through the conveyor belt 52. The stop and progress are controlled by).

Inserting the pin into the pinhole and binding the A circuit and the B circuit, assembling the lower part of the insulating case, and combining the pin with the upper part of the power saving case (S7), inserts the pin into the pinhole and connects the A circuit and the B circuit to the circuit board. After binding, it is assembled at the bottom of the energy saver case and completed by combining with the top of the energy saver case.

Finally, the data analysis table supporting the above-described embodiments will be described as follows.

TABLE 1

Serim Paper Co., Ltd. Electricity Savings Data Analysis 2001

2001 / month Production (ton) Power consumption Unit usage Savings rate compared to last year's average Year-on-Year Savings January 15.196 8.295.000 545.87 3.04% 2.63% February 14.704 8.004.420 548.45 2.58% 0.51% In March 16.510 8.646.120 523.69 6.98% 3.97% April 16.035 8.254.260 514.77 8.57% 5.10% In May 16.653 8.511.300 511.10 9.22% 8.78% June 16.529 8.255.520 499.46 11.29% 10.49%

[Table 1] is 11.29% + 3.94% = 15.23% considering the average annual growth rate.

TABLE 2a

Analysis table for electrical savings in 1999

1999 A production quantity B production quantity Yield meter Power consumption Unit usage Average unit January 10,384 6,743 17,127 9,387,840 548,13 February 9,242 6,132 15,374 8,391,600 545,83 In March 10,031 6,925 16,956 9,222,780 543,92 April 9,549 6,600 16,149 8,870,820 549,31 In May 9,896 7,080 16,976 9,114,420 536,90 June 9,739 6,513 16,252 8,787,660 540,17 In July 9,793 6,262 16,055 8,929,200 556,16 August 9,902 6,621 16,523 9,169,440 554,95 September 9,952 6,757 16,709 8,720,880 521,93 October 10,581 7,086 17,667 9,216,900 821,70 541,96

TABLE 2b

Table of Analysis of Electricity Savings for 2000 Serim Paper Co., Ltd.

2000's A production quantity B production quantity Yield meter Power consumption Unit usage Average unit January 9,930 6,992 16,922 9,486,540 560.60 February 8,908 5,802 14,710 8,026,620 545.66 In March 10,273 6,913 17,186 9,371,880 545.32 April 9,789 6,758 16,547 8,975,400 542.42 In May 9,710 6,198 15,908 8,913,240 560.30 June 9,957 6,094 16,051 8,956,080 557.98 In July 10,115 6,141 16,256 9,079,560 558.54 August 8,863 5,830 14,693 8,264,760 562.50 September 9,254 4,802 14,056 7,964,880 566.65 October 9,605 4,730 14,335 8,067,360 562.77 556.27 November 14,692 8,836,000 601.42 December 15,321 9,127,000 595.72 563.32

TABLE 2c

Analysis Table of Electricity Savings for Serim Paper Co., Ltd. in 2001

2001 A production quantity B production quantity Yield meter Power consumption Unit usage Reduction from Average Monthly reduction rate January 9,335 5,861 15,196 8,295,000 545.87 -3.04 -2.63 February 8,941 5,763 14,704 8,064,420 548.45 -2.58 0.51 In March 10,018 6,492 16,510 8,646,120 523.69 -6.98 -3.97 April 9,850 6,185 16,035 8,254,260 514.77 -8.57 -5.10 In May 9,965 6,688 16,653 8,511,300 511.10 -9.22 -8.78 June 9,833 6,696 16,529 8,255,520 499.46 -11.29 -10.49

2001/2000 average = Average unit usage in January 2001/2000 (563.32)

Compared to 2001/2000 = January 2001/2000 Month

This is an increase of 3.94% on average in 2000/1999.

[Table 2a] [Table 2b] [Table 2c] is a table analyzing the electrical savings effect performed by the Serim Paper Co., Ltd. located in Daegu, South Korea.

TABLE 3

Analysis of electricity savings for 6 months in 2000 and 2001 for business buildings

year month January February In March April In May June In July August September October November December Unit usage in 2000 560.60 545.66 545.32 542.42 560.30 557.98 558.54 562.50 566.65 562.77 601.42 595.72 Unit usage in 2001 545.87 548.45 523.69 514.77 511.10 499.46 % Savings 2.63 -0.51 3.97 5.10 8.78 10.49

Table 3 shows a 10.49% savings after 6 months of installation compared with Table 2c and is shown graphically in FIG.

TABLE 4

Electricity saving analysis table for government offices

month term December January February In March April In May Power (kwh) December 99-April 00 11,855 13,853 14,501 13,180 11,437 9,360 Power (kwh) December 00-01 April 10,368 12,604 13,972 11,772 10,030 8,579 Savings (kwh) 14,87 1,249 529 1,408 1,407 781 Savings rate 12.54 9.02 3.65 10.68 12.30 8.34

[Table 4] is an analysis table showing the power saving effect by installing in a public office and analyzed the data, and confirmed the average savings effect of 9.42% 6 months after installation and shown in the graph in FIG.

TABLE 5

Electricity saving analysis table for home

January February In March April In May June In July August September October November December Power consumption in 2000 (kwh) (A) 278 320 256 277 277 249 240 227 227 233 190 214 Power in 2001 (kwh) (B) 242 242 209 237 222 234 224 Reduction rate (%) (A-B) / A × 100 12.95 24.38 18.36 14.44 19.86 6.02 6.67

[Table 5] is an analysis table showing the power saving effect for the home installed in the home, and analyzed the data showed an average of 14.7% savings compared to the previous year after installation, and is shown graphically in FIG.

As described above, the present invention stores information in the semiconductor chip to control the wavelength of the color using the visible band filter between 500 nm and 600 nm and to control the energy density using the luminance, and to store 10 ⁴ at 10 ³ nm. Infrared filter between ㎚ is used to change the vibration state of material molecules and to transfer the energy to the semiconductor chip, while confining energy balance energy among infrared energy by increasing the refractive index of the light trap, ie the infrared filter. In addition, since it has the effect of maximizing the operation efficiency of the electric device and maximizing the power saving efficiency, it is a very excellent invention in the electric industry.

Claims (6)

In the electric power saver, A circuit (8) 9, 12, 13, 14, 18, 24, 25, 100-1); The energy balance energy formed in the mid-infrared filter and the near-infrared filter is scanned on the semiconductor chip 100-2 by receiving the current in the inverted state, and thus the semiconductor chip MCLR / Vpp input terminal 4 (22) and OSC1 / CLKIN input terminal 16 (23). The output value AND gated at is transferred to the input terminal CN1AC220V 1 (24) and the input terminal CN1AC220V 2 (25) .In the same way, the output of the OR gate is OR gated to the input terminal CN1AC220V 1 (24) and the input terminal CN1AC220V 2 (25). NOR gated output value is transmitted to input terminal CN1AC220V 1 (24) and input terminal CN1AC220V 2 (25). (B) circuits (10, 11, 14, 15, 16, 17, 19, 20, 22, 23, 26, 27, 28, 29, 100-2) delivered to terminal CN1AC220V 2 (25). The optical filter in the infrared region of 103 to 104 nm and the visible region in the range of 500 nm to 600 nm and the information control of a semiconductor excited with energy balance energy Power saver. The method of claim 1, wherein the semiconductor entity muxp is port (s: in std_logic_vector (near-infrared downto mid-infrared)); 4, 16: in std_logic; Input terminal 21, input terminal 22: out std_logic); end muxp; arcitecture infrared of muxp is begin process (EVE, mid-infrared, near-infrared) begin case EVE is when "EVE" => input terminal (21), input terminal (22) <= mid-infrared and near-infrared; when "medium infrared" => LED1 (23) <= medium infrared or near infrared; when "near-infrared" => LED1 (23) <= medium-infrared xor near-infrared; when other => LED1 (23) <= medium-infrared nand near-infrared; end case; end process; end infrared; An energy-saving device based on information control of a semiconductor excited with an optical filter and an energy balance energy of 10 ³ to 10 ⁴ nm infrared region and 500 nm to 600 nm visible region, characterized in that the logic. In the electric power saver manufacturing apparatus, Energy Balanced energy excitation device is a WY orthogonal robot device that controls the optical energy of the visible filter by moving the circuit board to the visible filter, and a visible band that stores information on the semiconductor chip that controls the energy density by adjusting the wavelength and luminance by color. The filter system, an infrared filter system that changes the vibration state of material molecules and induces an infrared vortex with an infrared screw to transfer energy to the semiconductor chip, simultaneously performs optical trapping, and a circuit board in the infrared filter Belt conveyor to transfer to filter, O and P boxes that operate by integrating switches for work and operation, Control box to automatically control the system's control and wavelength intensity and sensor in visible and infrared range, and XY quadrature robot unit Infrared range of 10 ³ to 10 ⁴ nm and 500, characterized in that the compressor produces air for driving An energy-saving device manufacturing apparatus using information control of a semiconductor in which visible light filters and energy balance energy are excited in the range of ㎚ to 600 nm. According to claim 3, The infrared filter system is a device for changing the vibration state of the material molecules and the infrared vortex with an infrared screw to transfer the energy to the semiconductor chip to simultaneously perform the light trapping and energy balancing energy An apparatus for manufacturing a power saver by controlling an information of a semiconductor in which an infrared filter of 10 ³ to 10 ⁴ nm and a visible filter in the visible range of 500 nm to 600 nm and an energy balance energy are excited. 4. The method of claim 3 wherein the visible range filter system 10 to the information control of the energy density adjusted to the wavelength and the luminance in color characterized in that the memory on the semiconductor chip ³ ~ 10 ⁴ ㎚ infrared range and 500㎚ ~ 600㎚ of A device for manufacturing a power saver by controlling information of a semiconductor in which a visible light filter and an energy balance energy are excited. How to manufacture a power saver Placing the circuit board in the inlet and matching the origin (S1); Moving the circuit board to a visible filter (S2); After the visible light filter sends a light source to the visible filter system, storing information on the semiconductor chip to control the energy density as wavelength and luminance by using a visible filter (S3); Transferring the circuit board to the infrared filter system by riding on the Kenbei belt whose speed is controlled by the geared motor (S4); Synthesizing two infrared regions of a mid-infrared light source and a near-infrared light source and scanning them with an infrared cap to give the semiconductor chip a function of energy transition (S5); When the finished substrate comes out to the infrared filter system through the conveyor belt step of stopping the stopper by the photosensor (S6); Inserting the pin into the pinhole and binding the A circuit and the B circuit, and then assembled in the lower insulating case and completed by combining with the upper part of the energy-saving case (S7).