KR100967795B1 - Formed materials, electric detecting materials and object for electric detecting using magnet field induction - Google Patents

Abstract

The present invention is configured by mixing a superparamagnetic iron oxide colloidal photonic crystal that expresses color in response to a magnetic field with a resin composition on a gel to construct a detector and apply or attach the detector to a target, thereby visually checking whether the current of the target is flowing. The present invention provides a magnetic field sensitive magnetic field sensitive molded body, an inspection material, and an inspection object using superparamagnetic iron oxide nanocrystals that can be easily identified.

Detector, Magnetic Field, Superparamagnetic Iron Oxide Colloidal Crystal, Resin, Siloxane

Description

FORMED MATERIALS, ELECTRIC DETECTING MATERIALS AND OBJECT FOR ELECTRIC DETECTING USING MAGNET FIELD INDUCTION}

The present invention relates to a detector, in particular a superparamagnetic iron oxide colloidal photonic crystal having a characteristic of magnetic field-sensitive color expression and a polymer in the form of a gel is mixed, the magnetic field-sensitive molded body, the test material and the test target object is changed in color depending on the strength of the magnetic field It is about.

In general, in order to detect a current, a CT (Current Transformer) or a resistor is inserted to measure a current or a CT for a DC using a coil winding.

Such a CT for DC or CT for AC had a weak defect in noise, and it was difficult to electrically separate high current and low current when inserting a resistor. As a result, the current sensing method shown in FIG. 1 is used.

1 is a circuit diagram illustrating a current sensor according to an example of the prior art, and includes a current sensing unit 20, a comparison circuit unit 30, and an operational amplifier unit 40.

Such a current sensor easily measures the current flowing in the line by sensing the current flowing in the coil 1 through which the line 10 passes through the hall element 2 and outputting the magnitude of the detected signal as a voltage.

That is, the current sensing unit 20 is to detect the magnetic force radiated from the line through which the current flows, and the hall element 2 for detecting the magnetic force is installed in the coil or core 1 through which the line 10 passes. The output terminal of the Hall element 2 is connected to the inverting end and the non-inverting end of the associating amplifier OP1 via the resistors R1 to R2 of the comparison circuit unit 30.

The comparison circuit unit 30 is a circuit for comparing the signal detected and output by the hall element 2 of the current sensing unit 20 with a preset signal. The inverting terminal (-) of the associating amplifier OP1 is a resistor R1. It is connected to the output terminal of the Hall element 2 of the current sensing unit 20 via) and at the same time between the non-inverting terminal (+) and the inverting terminal (-) of the operational amplifier OP1 through a resistor (R3) Diodes D1 to D2 are connected to each other in reverse direction.

The operational amplifier 40 is configured to perform operational amplification on the signal compared and output from the comparison circuit unit 30, and the inverting terminal (−) of the operational amplifier OP2 is connected to the comparison circuit unit 30 through the resistor R4. Connected to the output terminal of the operational amplifier OP1 and connected to the output terminal of the operational amplifier OP2 through a potentiometer VT2 and a condenser C for adjusting the gain of the operational amplifier OP2. It is connected to the ground via the resistors R5 to R6 connected in series to the non-inverting terminal (+) of the amplifier OP2.

The current sensor configured as described above starts to operate in a state where a current 10 flows through the coil 1 in which the hall element 2 is installed.

Magnetic force is formed in the coil 1 of the current sensing unit 20 through which the line 10 passes, and the magnetic force formed in the coil 1 is sensed by the Hall element 2 of the current sensing unit 20. The signal sensed by the Hall element 2 is input to the inverting terminal (-) of the operational amplifier OP1 through the resistor R1 of the comparison circuit unit 30.

The operational amplifier OP1 of the comparison circuit unit 30 compares a sensing signal input to the inverting terminal (-) and a predetermined signal input to the non-inverting terminal (+) and compares the compared signal with the operational amplifier OP1. It is transmitted to the operational amplifier 40 through the output terminal.

The compared signal output from the comparison circuit unit 30 is input to the inverting terminal (−) of the operational amplifier OP2 through the resistor R4 of the operational amplifier 40.

The operational amplifier OP2 outputs a voltage signal proportional to the current flowing in the line 10 by amplifying the input signal.

Such a conventional technology is generated by collecting current from both ends of a line through which electricity flows, or by inducing electricity from a magnetic field generated by current flow using a coil or the like. Conventionally, the generated electrical signal is output to an output terminal of a light bulb or a speaker. Produce a detector to inform you through the power equipment, wires, tools, hard hats and attached.

Magnetic flux is generated in the line through which electricity flows in proportion to the intensity of electricity. When the wire wound in the form of coil approaches, electricity is induced to the coil by the magnetic flux. The intensity of the induced electricity is proportional to the strength of the magnetic flux, and the count of the magnetic flux is counted closer to the conducting wire. .

The electricity flowing by this principle causes a current to flow in a circuit connected to the coil, and the detector transforms the induced electricity into a light or voice signal that can be recognized by a human or a machine. Power devices and electrical safety devices use these types of detectors attached to various power devices or in the form of portable detectors.

However, such a detector loses its function when there is a problem in the circuit, and when the output terminal (light bulb or speaker) is deteriorated, its alarm function is lost, so it is necessary to maintain the maintenance circuit. There was a problem inevitably constrained in size and shape.

An object of the present invention is to form a detector by mixing a superparamagnetic iron oxide colloidal photonic crystal that expresses color in response to a magnetic field with a resin composition on a gel (gel) and apply or attach it to the target, thereby determining whether the current of the target is flowing. The present invention provides a magnetic field sensitive molded body, an inspection material, and an inspection object using superparamagnetic iron oxide nanocrystals that can be easily visually identified.

The magnetic field sensitive molded article of the present invention for achieving the above object includes a superparamagnetic magnetite colloidal photonic crystals having a characteristic of magnetic field sensitive color expression and a test material of transparent resin.

Specifically, the resin is characterized in that the polysiloxane-based resin, in particular, the polysiloxane-based resin is characterized in that the polydimethylsiloxane.

The molded body is characterized in that the detector, the molded body is characterized in that the heat treatment at a temperature of about 60 ℃ to 80 ℃.

The magnetic field sensitive inspection material of the present invention for achieving the above object includes a superparamagnetic magnetite colloidal photonic crystals and a transparent resin having characteristics of magnetic field sensitive color expression.

Specifically, the resin is characterized in that the polysiloxane-based resin, the resin is characterized in that the gel phase.

The test object of the present invention for achieving the above object is characterized in that it comprises a coating layer using a superparamagnetic magnetite colloidal photonic crystals (Superparamagnetic Magnetite Colloidal Photonic Crystals) having a characteristic of magnetic field-sensitive color expression and a transparent resin test material .

In addition, it is characterized in that it comprises a superparamagnetic Magnetite Colloidal Photonic Crystals (Superparamagnetic Magnetite Colloidal Photonic Crystals) having a characteristic of magnetic field-sensitive color expression and a molded body of a transparent resin.

Specifically, the coating layer or the molded body is characterized in that it is coated or attached to any one of the power device and motor, various tools, wires, safety clothing, hard hat and train rail.

It characterized in that it further comprises a protective film on the surface of the coating layer or the molded body, the resin is characterized in that the polysiloxane resin.

As described above, the present invention is installed in a device having a risk of a safety accident or a safety device capable of preventing the accident by using a detector in which a superparamagnetic iron oxide colloid photo crystal having a characteristic of magnetic field-sensitive color expression and a polymer in a gel form is mixed. By doing so, the operator can visually check whether the power supply from time to time can prevent safety accidents in advance, and there is no need for maintenance of the detector, thereby further improving safety and convenience.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a view showing a mixed material of the magnetic field sensitive detector according to the present invention.

First, superparamagnetic magnetite colloidal photonic crystals (Superparamagnetic Magnetite Colloidal Photonic Crystals) and a transparent resin in a gel (gel) state is mixed to produce a gel-like test material. When mixing the superparamagnetic iron oxide colloidal photonic crystal and the transparent resin, various known mixing techniques may be used so that the superparamagnetic iron oxide colloidal photocrystalline may be evenly distributed in the resin.

Of course, it is natural that various catalysts may be used to improve binding and mixing power of the superparamagnetic iron oxide (Fe ₃ O ₄ ) colloidal photonic crystal and the transparent resin.

As the material to be mixed with the superparamagnetic iron oxide colloidal photonic crystal, a resin having insulation and transparency without impairing the characteristics of the magnetic field sensitive color change is preferable. Examples thereof are not particularly limited, but it may be preferable that the resin is a siloxane resin in terms of mixing and binding with the superparamagnetic iron oxide colloidal photonic crystal.

In the above, the superparamagnetic iron oxide colloidal photonic crystal has a size of 30 to 200 nm, and is a material causing color change through wavelength change in response to a magnetic field. The superparamagnetic iron oxide colloidal photonic crystal shows a color change of various spectra (red, orange, yellow, green, blue, etc.) according to the intensity of the magnetic field in deionized water, and is grayed out in the absence of a magnetic field. .

3 is a color spectrum of a superparamagnetic iron oxide colloidal photonic crystal applied to the present invention according to the intensity of a magnetic field. FIG. 3 is a reflection spectrum of the superparamagnetic iron oxide colloidal photonic crystal mixed with an NdFeB magnet. to be. As shown in FIG. 3, it can be seen that the color expressed in the superparamagnetic iron oxide colloidal photonic crystal changes depending on the distance between the magnet and the supernatant iron oxide colloidal photonic crystal mixed solution and the magnet.

This superparamagnetic iron oxide colloidal photonic crystal is a novel substance reported by Professor Yadong, Yin of the University of California in 2007. For more details, see Jingping Ge et al, Angewandte Chemie.international edition. 2007, v46, See pp4342 ~ 4345, "Superparamagnetic Magnetite Colloidal Nanocrystal Clusters".

In addition, the resin mixed with the superparamagnetic iron oxide colloidal photonic crystal serves to surround the superparamagnetic iron oxide colloidal photonic crystal with a transparent or translucent material, and may be, for example, polydimethylsiloxane.

As such, the test material in which the superparamagnetic iron oxide colloidal photonic crystal is mixed with the transparent resin may be used in various forms. First, the test material is coated in the form of a coating and coated on the test target, and as shown in FIG. The test material may be poured into a mold and processed into a molded body of a desired shape. The test material or the molded article itself functions as a detector.

First, when the test material on the gel is applied to the test target in the form of a paint with a predetermined thickness, the test material is cured by heat treatment at a temperature of approximately 60 ° C to 80 ° C.

The reason for the heat treatment at a temperature of 60 ℃ to 80 ℃ is because it can remove the stickiness due to the gel phase as well as rapid curing.

Of course, if necessary, the protective film may be coated on the surface of the test material with a transparent liquid in order to protect the test material applied to the test object from the external environment.

When the test material is applied to the test target as described above, a magnetic field is generated when a current flows in the test target, and the superparamagnetic iron oxide colloid photocrystals contained in the test material react with the generated magnetic field to express a predetermined color. The user can visually check whether the object is powered.

The color expressed in the superparamagnetic iron oxide colloidal photonic crystal depends on the strength of the magnetic field, and the operator can intuitively know the intensity or the degree of danger through the color expressed in the test material.

It is preferable to apply the gel-based test material to a position to be easily identified by an operator when applying the test material to the test target.

On the other hand, where it is difficult to apply the gel-like test material, as shown in FIG. 4, the gel-type test material is poured into a mold of a predetermined shape and molded into a desired shape, and a vacuum is applied to the processed molded product to remove bubbles generated inside the molded product. The molded article is cured by heat treatment at a temperature of approximately 60 ° C. to 80 ° C. for 2 hours.

The reason for removing bubbles when forming the detector is to increase the expression of color, that is, the transparency of the color, and the reason for heat treatment at a temperature of about 60 ° C to 80 ° C is not only rapid curing but also stickiness due to gel phase. Because it can be removed.

Thus, the cured molded body is attached to a place where the user of the inspection target is easy to identify, so that the power supply can be visually easily checked.

The molded product cured as described above may also be coated with a separate transparent protective film on the surface of the molded product in order to protect it from the external environment.

The test object to which the test material is applied or the molded body is attached may be a variety of products, and the test object may include a transmitter, a transformer, a distribution panel, a relay, and the like used to generate, transmit, distribute, and distribute electric power of 100V or more. Included power equipment, various motors, various tools such as drivers and wrenches, nippers or pincers and spanners, and high voltage cables and overhead lines, medium and low voltage lines, bust, H-beams, insulators, etc. It can be any product that requires inspection, such as wires and their combinations, safety clothing, hard hats, safety gloves and train rails.

Accordingly, the present invention utilizes a physical phenomenon in which a superparamagnetic oxide colloidal photonic crystal having a size of 30 to 200 nm causes color change through a wavelength change in response to a magnetic flux (magnetic field). Whether or not the operator opens or closes the power supply by manufacturing a test material which is mixed with a transparent fluid such as to maintain its color development power and by coating the prepared test material on the surface of the test object or attaching it where visible visibility is possible in the form of a molded product. It's easy to visually check and work safely.

Accordingly, the present invention provides a visual indication of whether power is being supplied to a power device or a conductor that is in contact with or in proximity to an operator through a detector including a superparamagnetic iron oxide colloidal photonic crystal that requires no maintenance for safety in an electric room or a construction site. It is possible to prevent the risk of an electric accident in advance by labeling it to the worker and to provide convenience in manufacturing and use since it is easier and easier to manufacture and apply a detector that requires no maintenance.

Preferred embodiments of the present invention are disclosed for purposes of illustration, and those skilled in the art will be able to make various modifications, changes, and additions within the spirit of the present invention. Therefore, such modifications, changes and additions should be determined not only by the claims below, but also by equivalents to those claims.

1 is a circuit diagram showing a current sensor according to an example of the prior art.

2 is a view showing a mixed material of the magnetic field sensitive detector according to the present invention.

3 is a view showing a color spectrum of the superparamagnetic iron oxide colloidal photonic crystal applied to the present invention varies with the strength of a magnetic field.

4 is a view illustrating a molding process of the magnetic field sensitive detector according to the present invention.

Claims (13)

Superparamagnetic Magnetite Colloidal Photonic Crystals of 30 to 200 nm in size and having a characteristic of magnetic field-sensitive color expression are mixed with a gel-like transparent polydimethylsiloxane resin to form a molded article for inspection, and the molded article is formed. Magnetic field-sensitive molded body, characterized in that when cured by heat treatment at a temperature of 60 ℃ to 80 ℃. delete delete delete delete A superparamagnetic magnetite colloidal photonic crystal of 30-200 nm size having a characteristic of magnetic field-sensitive color expression and a gel-like transparent polydimethylsiloxane resin were mixed to form a test material for the test, and the test material Magnetic field-sensitive type of the material, characterized in that the coating to the object and then heat treated at a temperature of 60 ℃ to 80 ℃ to cure the test material. delete delete delete It includes a molded body or an inspection material in which a superparamagnetic magnetite colloidal photonic crystals having a characteristic of magnetic field-sensitive color expression and a transparent polydimethylsiloxane resin in a gel form are mixed, An inspection object, characterized in that a protective film is further formed on the surface of the material. The method according to claim 10, The molded object or the test material is a test object, characterized in that the coating or attached to any one of the power device and motor, various tools, wires, safety clothing, hard hat and train rail. delete delete

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