KR101506886B1 - Discharge energy by electromagnetic fields and electric shock prevention device using coil electrode - Google Patents

Abstract

The present invention relates to an apparatus for preventing electric discharge and flooding and electric shock using a coil electrode capable of reducing a leakage current while reducing a leakage current when a terminal electrically connecting an electric device is flooded.
A feature of the present invention is that an input power line 100 for inputting a commercial power source, an output line 200 for supplying a commercial power input by the input line 100 to the load, 200) is connected to both ends to attenuate the amount of energy flowing into the atmosphere, thereby reducing the discharge of energy. When the energy is supplied, the wavelength of the electric power and the wavelength of the electric current are made uniform, It is a circular shape with an inner diameter of 1.2 to 100 times larger than the diameter of the input wire (100) so as to prevent electric shock or electric shock through the liquid by flowing the electric energy to the electric device or the electronic device while ensuring operation even if it floods in rain or water. Shaped electrode 10 formed to have a length that is 1.2 to 100 times greater than the diameter of the input wire 100 while being rolled so that the input wire 100 and the output wire 200 are connected to both ends of the electrode 10, (10) The electrode includes a connection portion (11) consisting of projections which respectively protrude from both ends of the hole or the electrode 10 that is formed to penetrate.

Description

TECHNICAL FIELD [0001] The present invention relates to an apparatus for preventing electric discharge and inundation by using a coil electrode,

The present invention relates to an apparatus for preventing electric discharge and flooding and electric shock using a coil electrode capable of reducing a leakage current while reducing a leakage current when a terminal electrically connecting an electric device is flooded.

In general, electric and electronic devices are required to have a waterproof structure because of the possibility of short-circuit and electric shock accidents in places with high humidity or underwater. Various types of electric shock and discharge attenuation windows are disclosed for this purpose.

First of all, the recessed type socket is installed in an outlet box which is installed at the time of installing the wall and has an outer lid which covers the plug groove for plugging from the outside for the waterproof function to prevent water from penetrating into the socket Various technologies and structural materials such as energy saving, electromagnetic wave shielding and noise shielding technology have been developed and applied to electric devices and electronic products.

Here, Patent Application No. 10-2005-0059025 discloses a waterproof safety outlet in which a plug packing is provided in an outlet terminal hole and a grounding hole.

However, the conventional waterproof safety outlet can block the inflow of water penetrating from the outside of the wall to the front surface of the outlet, but it is possible to prevent the inflow of water flowing into the outlet box or the condensation inside the conduit due to the inflow of water due to the leakage of the wall itself There is a problem in that the condensation water can not be prevented from flowing to the wire fastening portion by carrying the electric wire, resulting in a short circuit or an electric shock.

In addition, Patent Registration No. 10-1197414 discloses a method in which input electrical energy is transferred to a DC by using a transformer and a diode, and a rectangular electrode plate and a rectangular electrode plate are attached to the wire connecting terminal. ≪ / RTI >

However, in the electric leakage preventing device of the prior art, there is a problem that the electric leakage preventing conductor for preventing the electric leakage is formed in the form of wrapping around the terminal block, thereby increasing the overall volume.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a device for preventing discharge and flooding and electric shock using a coil electrode capable of reducing a leakage current while reducing a leakage current when a terminal electrically connecting an electric device is flooded, .

An apparatus for preventing discharge and flooding of an electric wire using a coil electrode according to an embodiment of the present invention includes an input wire 100 to which a commercial power is input, an output wire 100 to supply a commercial power input from the input wire 100 to the load, The input wire 100 and the output wire 200 are connected at both ends to attenuate the amount of energy flowing to the atmosphere to reduce the discharge of energy and to equalize the wavelength of the power and the wavelength of the current when the energy is supplied, To extend the lifespan of appliances or electronic appliances and to prevent the electrical or electronic appliances from flowing into electrical appliances or electronic appliances while shutting off electrical energy to ensure operation even when flooded in rain or water, Shaped electrode 10 formed to have a length of 1.2 to 100 times the diameter of the input wire 100 while being wound in a circular form having an inner diameter of 1.2 to 100 times larger than the diameter of the input wire 100, And an electrode connection part 11 composed of a hole formed to be passed through both ends of the electrode 10 or the protrusion protruding from both ends of the electrode 10 so that the input wire 100 and the output wire 200 are connected to each other .

Preferably, the input wire 100 or the output wire 200 has a diameter of at least 2 mm.

Preferably, the electrodes 10 are in the form of a coil while being spaced apart by an interval W2 that is less than the thickness W1 of the metal wire.

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Preferably, the present invention comprises a plurality of partitions 22, each of which is composed of an insulator and spaced apart from the electrode 10 by a diameter of the electrode 10, for supporting both sides of the electrode 10, And a terminal block (20) formed to protrude from a surface of the terminal block (20).

Preferably, the terminal block 20 is formed with screw tabs 21 at both ends thereof.

The terminal block 20 may further include an offset member 30 fixed to the terminal block 20 so as to cover the electrode 10 and offset the leakage current leaking from the electrode 10.

The canceling member 30 preferably includes an upper insulating plate 31 covering the electrode 10, a side insulating plate 32 protruding downward from both sides of the upper insulating plate 31 and fixed to both sides of the terminal block 20, And connected to the attenuator 33 and the attenuator 33 that are positioned between the side insulating plates 32 and fixed to the lower portion of the upper insulating plate 31 to attenuate the current leaking from the electric wire 100. [ And a grounding portion 34 for grounding the microcurrent to be attenuated.

Preferably, the present invention provides an input power supply apparatus including an input wire 100 to which a commercial power is input, an output wire 200 for supplying a commercial power input by the input wire 100 to the load, an input wire 100 and an output wire And the output wires 100 and the output wires 200 are wound on the outer side in the form of coils each having an inner space formed at both ends thereof so that the fastening members 60 pass through the fastening members 60, It is possible to reduce the discharge of energy by attenuating the amount of energy flowing to the atmosphere and to equalize the wavelength of the power and the wavelength of the electric current when the energy is supplied so that the life of the electric appliance or the electric appliance is prolonged, A leakage preventing electrode 40 for preventing electric discharge or electric shock through the liquid by flowing electric energy into an electric device or an electronic device while confining electric energy so as to ensure operation even when the electric device is submerged, and a fastening member 60 penetrating through the leakage preventing portion 40, Of Gyeole by characterized in that it comprises a terminal block 20 which is fixed to the terminal member (50).

The present invention prevents electric discharge or electric shock through a liquid by confining energy or flowing quickly to a load even when an electric device or an electronic device is submerged in rain or water and attenuates the energy discharge by attenuating the amount of energy flowing into the liquid or atmosphere , It is possible to extend the lifetime of the electric device or the electronic device by making the wavelength of the power and the current of the electric power even when supplying the energy.

In case of applying an electric shock prevention terminal block and an electrode to an electric outlet to ensure stable operation even when electric or electronic equipment is submerged, if the electric outlet is exposed to rain during rain or the electric current is not leaked to the outside even if it is submerged in water, Therefore, normal power supply can be performed, and it is possible to operate normally without causing a malfunction or failure due to a leakage current, and at the same time, an electric shock accident can be prevented.

In addition, since electric leakage is prevented in a state where electric wires are connected to the electrodes, it is possible to prevent an increase in volume due to the need to additionally provide a separate structure for preventing electric leakage, thereby providing a slim shape.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a coil-type electrode-type discharge energy prevention and submerged electric shock prevention apparatus according to an embodiment of the present invention; FIG.
2 is a perspective view of a coil-type electrode-type discharge energy preventing and submerged electric shock preventing apparatus according to another embodiment of the present invention.
Figure 3 shows a side view of the present invention.
Figure 4 is a perspective view of the embodiment of Figure 3 applied.
5 is a perspective view showing a state in which the present invention is applied in a vertical state.
Figure 6 is a perspective view of the embodiment of Figure 5;
7 is a perspective view showing the use state of the present invention.
8 is a perspective view showing another use state of the present invention.
9 is a perspective view showing a terminal block according to the present invention.
10 is a perspective view showing an offset member coupled to a terminal block of the present invention;
11 is a perspective view showing a state in which an offset member is coupled to a terminal block of the present invention.
12 is a perspective view showing a state where the present invention is installed vertically on a terminal block;
13 is a perspective view of a coil-type electrode-type discharge energy prevention and flooding-and-electric-shock protection apparatus according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 and 2, an apparatus for preventing discharge and flooding electric shock using a coil electrode according to an embodiment of the present invention includes an input wire 100 to which commercial power is input, The output wire 200 supplying the commercial power to the load and the input wire 100 and the output wire 200 are connected at both ends to attenuate the amount of energy flowing into the air to reduce the discharge of energy, By extending the lifetime of electric and electronic equipment by adjusting the wavelengths of the current and the wavelength, it is possible to flow the electric energy to the electric device or the electronic device while inserting the electric energy so as to ensure the operation even when the electric device or the electronic device is immersed in rain or water, A coil shape which is formed to have a length of 1.2 to 100 times the diameter of the input wire 100 while being wound in a circular form having an inner diameter of 1.2 to 100 times larger than the diameter of the input wire 100 Of the electrode (10).

In addition, since the electrode 10 is formed in the form of a coil, it encloses the input wire 100 connected to the electrode connection part 11 and confines leakage current when it floods. That is, the electrode 10 is formed of a metal wire wound in the form of a coil, and the inner circumferential surface of the electrode 10 is spaced apart from the electric wires 100 and 200 by a predetermined distance to be 1.2 to 100 times larger so as to form an inner space The input wire 100 or the output wire 200 may have an inner diameter and a length of 2.4 mm to 200 mm when the diameter is at least 2 mm. Here, the electric wires 100 and 200 are preferably 2 mm to 2 cm. Particularly, it is preferable that the inner diameter and the length are 2 to 10 times larger than the diameter of the electric wires 100 and 200.

Further, as the internal space of the electrode 10 is formed, the operation of connecting the input wire 100 or the output wire 200 to the electrode connection portion 11 may be facilitated. Here, the electrode 10 can be firmly fixed to the terminal block 20 by a bolt, which is a fastening member 60 to be described later.

Also, as shown in FIG. 3, it is preferable that the electrode 10 is formed in a coil shape in a state of being spaced apart or in close contact with a gap W2 smaller than the thickness W1 of the metal wire. That is, when the electrode 10 is formed into a coil shape in a closely spaced or tight state by tightening the bolt as the fastening member 60, the electrode 10 becomes close to the cylindrical shape, have.

As shown in FIG. 4, '+' and '-''2 core wires are embedded in the sheath for supplying commercial power to the input wire 100 and commercial power is supplied to the output wire 200 To provide power, '+' and '-' two core wires are built into the sheath. Accordingly, the electrodes 10 are provided in a plurality of spaced apart states, so that two core wires of the input wire 100 and two core wires of the output wire 200 are connected to each other, thereby providing commercial power to the electric device.

As shown in Fig. 5, the electrode 10 may be used standing upright. Here, the same effect as in the horizontal state can be generated even when the electrode 10 is vertically erected while the input and output wires 100 and 200 are connected to both ends thereof. 6, the plurality of electrodes 10 are vertically erected, so that two core wires of the input wire 100 and two core wires of the output wire 200 are connected to each other, As shown in FIG.

7, when the electrode 10 is fitted and fixed to the input wire 100 or the output wire 200, the electrode 10 is separated from the core wire by the sheath, so that the electrode 10 may be discharged or leaked through the core wire It is possible to prevent the loss of current. That is, as shown in FIG. 8, the electrodes 10 are connected to each other with the electric pole interposed therebetween and can be mounted on the outer circumferential surface of the power cable through which the commercial current flows, so that the amount of energy flowing from the power cable to the atmosphere is reduced, As the discharge is reduced, the loss of the leakage current can be prevented.

As shown in FIG. 1, the electrode connection part 11 may be formed as a hole formed to pass through both ends of the electrode 10. These holes correspond to the screw tabs 21 of the terminal block 20. Therefore, the bolt as the fastening member 60 can be screwed to the screw tab 21 while passing through the hole as the electrode connecting portion 11 in a contact state such as a core wire of the electric wires 100 and 200 being wound. That is, the wires 10 and 100 can be detachably fixed to the terminal block 20 while the wires 100 and 200 can be detachably fixed to the electrode 10 by the engagement of the bolts as the fastening member 60. In addition, the electric wires 100 and 200 may be twisted and fixed while being inserted into the hole, which is the electrode connection part 11.

As shown in FIG. 2, the electrode connection part 11 may be a protrusion protruding from both ends of the electrode 10. The projections may be permanently fixed to the core wires of the electric wires 100 and 200 by soldering welding.

In this way, when the electrode 10 is immersed in a state where the electric wires 100 and 200 are connected, the electric current leaking through the core wire of the electric wire 100 is mostly introduced into the electrode 10 through the water, It will not leak to the extent possible. In other words, since the electrode 10 surrounds and encloses the electric wire 100, the leakage current does not flow out and flows only between the electrode 10 and the electrode connection part 11, . Therefore, even when the electrode 10 is submerged, the current can be stably supplied through the electric wires 100 and 200 without leakage, so that an electric shock accident does not occur even if the human body touches the water in which the submersion is caused.

As shown in FIGS. 9 to 11, the present invention further includes a terminal block 20 having an electrode 10 fixed to the upper portion and composed of an insulator. The terminal block 20 has screw tabs 21 at both ends and a plurality of partition walls 22 made of an insulator and spaced apart from each other by the diameter of the electrode 10 so as to support both sides of the electrode 10, And is formed to protrude from both sides. Accordingly, the barrier ribs 22 stand up from the upper surface of the terminal block 20 to form a space in which the electrode 10 can be received. That is, the electrode 10 is inserted between the barrier ribs 22 and fixed to the terminal block 20 by the above-described fastening member 60 or another fixing member, so that the separation can be prevented.

The terminal block 20 further includes an offset member 30 which is fixed to the terminal block 20 so as to cover the electrode 10 and which cancels the leakage current leaking from the electrode 10. The offset member 30 includes an upper insulating plate 31 covering the electrode 10, a side insulating plate 32 protruding downward from both sides of the upper insulating plate 31 and fixed to both sides of the terminal block 20, And is connected to the attenuating part 33 and the attenuating part 33 which are positioned between the side insulating plates 32 and fixed to the lower part of the upper insulating plate 31 so as to attenuate the current leaking from the electric wires 100 and 200, And a grounding portion 34 for grounding. Since the side insulating plates 32 are fixed in a state of being pressed against the terminal block 20, the upper insulating plate 31 can cover the electrodes 10 to prevent the electrodes 10 from contacting with the outside, 10 are prevented from being separated from the terminal block 20. The attenuation portion 33 is formed of a conductor. Therefore, although the current leaking from the electric wires 100 and 200 is not leaked to the outside by the electrode 10, it can be grounded by the grounding part 34 while being attenuated by the attenuating part 33 when some leakage occurs.

When the two electrodes 10 are formed so that two core wires of the input wire 100 and two core wires of the output wire 200 are connected to each other, 22 may be composed of three. Of course, in the case where the electrode 10 to which the 'N' wire to be grounded is connected is further constructed, the partition walls 22 must be further constituted in the terminal block 20. In addition, in the case where the barrier ribs 22 protrude downward from the terminal block 20, the above-described offset member 30 may be additionally provided and fixed to the lower portion of the terminal block 20.

Here, as shown in FIG. 12, the electrodes 10 may be disposed between the partitions 22 in a vertically erected state and fixed to the terminal block 20. That is, the electrode 10 can exhibit the same effect as in a horizontal state even when the electrode is vertically erected while the input and output wires 100 and 200 are connected to both ends.

As described above, in the present invention, when the electrode 10 electrically connecting the electric device is submerged, the leakage current can be reduced, thereby preventing an electric shock accident and ensuring normal operation of the electric device.

13, another embodiment of the present invention includes an input wire 100 to which commercial power is input, an output wire 200 to supply a commercial power input by the input wire 100 to the load, A fastening member 60 for fastening the input wires 100 and the output wires 200 to each other and a coil wound around the fastening members 60 so as to pass through the input wires 60, 100 and the output wire 200 are connected to each other to attenuate the amount of energy flowing into the air to reduce the discharge of energy and to equalize the wavelength of the power and the wavelength of the electric power when the energy is supplied, A leakage preventing electrode (40) for preventing electric discharge or electric shock through a liquid by flowing electrical energy to an electric device or an electronic device while confining electric energy so as to ensure operation even when the electric device or the electronic device is submerged in rain or water, And a terminal block 20 which is a terminal member 50 fixed by the fastening of the fastening member 60 is a through-40.

Here, since the input wire 100, the output wire 200, and the terminal block 20 are the same as those described above, the description of the configuration is omitted.

The fastening member 60 may be bolted to the screw tab 21 of the terminal block 20 in the same manner as described above.

The leakage preventing electrode 40 is formed in a coil shape so that both ends thereof are respectively wound to form an internal space. The leakage preventing electrode 40 is formed to have a diameter larger than the diameter of the screw shaft of the bolt as the fastening member 60 and smaller than the head of the bolt as the fastening member 60 . Since the leakage preventing electrode 40 is formed at both ends in the form of a coil, the bolt that is the fastening member 60 can penetrate into the inner space.

The bolts that are the fastening members 60 penetrate the internal spaces of the leakage preventing electrode 40 so that the input wires 100 and the output wires 200 are in contact with the screw tabs 21 of the terminal block 20, As shown in Fig. At this time, the leakage preventing electrode 40 can be fixed to the terminal block 20 in a state of being electrically connected to the electric wires 100 and 200 by the pressing of the bolts. In this state, when the leakage preventing electrode 40 is immersed in the water together with the electric wires 100 and 200, electric energy is flowed to the electric appliance or the electronic appliance while the electric energy is blocked, thereby preventing a short circuit or an electric shock through the liquid.

As described above, according to the present invention, leakage current is reduced by the leakage preventing electrode 40 when the electric wires 100 and 200 electrically connecting the electric device, the fastening member 60 and the leakage preventing electrode 40 are flooded, And the normal operation of the electric device can be ensured.

Further, the present invention relates to a method of connecting a coil-type electrode for energy supply to a power connection terminal or all electric devices and an inlet or an outlet of an electronic device, whereby the power connection portion, that is, the outlet, the cord or power connector, It is possible to prevent the occurrence of electric shock and to normalize the energy supply so as to normalize the electric power supply to the electric device or the electronic It can guarantee the operation of the device, so it can be said that it is a very useful invention that can be widely applied to home or office.

As such, the present invention can prevent leakage of electric current even when flooded, which prevents flooding and electric shock prevention of a current leakage circuit breaker, a manhole for preventing electric shocks, a flood prevention electric street lighting pole, a flood prevention electric lighting fixture, an energy leakage prevention streetlight, Leakage prevention method Cord reel, energy leakage prevention insulator, energy leakage prevention insulated wire, energy leakage prevention hanger, energy leakage prevention tension holding device, energy leakage prevention wire, united cable, energy leakage prevention transformer, energy leakage prevention tension control, MCC Immersion electric shock prevention terminal block, immersion electric shock prevention terminal block for PLC, immersion electric shock terminal block for control BOX, immersion electric shock prevention terminal block for connection, immersion electric shockproof electric socket for wall embedding, multi-tab flooded electric shockproof electric outlet, , Outdoor high-voltage power transmission sulla construction, outdoor low-voltage power transmission sulla construction, Construction of high voltage power transmission and distribution system, Indoor and outdoor high voltage power transmission and sailway construction, Industrial power transmission and distribution sludge and electric works, Commercial transmission and distribution sludge and electric works, Residential power transmission and distribution sludge and electric works, Electricity use site electric saving, Substation transformer installation work, Construction, outdoor transformer installation work, transmission and distribution sill construction, electric socket, socket mogul, electronic equipment, semiconductor equipment, power station, traffic light, broadcasting equipment, train history, train history, electronics products, ships, vehicles, , An energy connection cord such as a mobile phone, a computer, and an electronic logistics equipment, and the human energy and output energy of a plug connector, so that normal power supply can be easily performed.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is to be understood, therefore, that the above description is intended to be illustrative, and not restrictive, and that the scope of the present invention will be defined by the appended claims rather than the foregoing description, All changes or modifications that come within the scope of the equivalent concept are to be construed as being included within the scope of the present invention.

10: electrode 11: electrode connection
20: Terminal block 21: Screw tab
22: partition 30: offset member
31: upper insulating plate 32: side insulating plate
33: attenuation section 34: ground section
40: leakage preventing electrode 60: fastening member
100: Input wires 200: Output wires

Claims (9)

An input wire 100 to which commercial power is input,
An output wire 200 for supplying a commercial power input by the input wire 100 to the load,
The input wire 100 and the output wire 200 are connected at both ends to attenuate the amount of energy flowing into the air to reduce the discharge of energy and to equalize the wavelength of the power and the current at the time of energy supply, (100) so as to prevent electrical shorting or electric shock through the liquid by flowing electric power to the electric device or electronic device while protecting the electric energy to ensure operation even when the electric device or the electronic device is immersed in rain or water. A coil-shaped electrode 10 formed to have a length 1.2 to 100 times longer than the diameter of the input wire 100 while being wound in a circle having an inner diameter of 1.2 to 100 times,
The electrodes 10 are connected to both ends of the electrode 10 such that the input wires 100 and the output wires 200 are connected to both ends of the electrode 10, (11). The apparatus for preventing electric shock and inundation using a coil electrode according to claim 1,
The apparatus of claim 1, wherein the input wire (100) or the output wire (200) is at least 2 mm in diameter.
The apparatus of claim 1, wherein the electrodes (10) are spaced apart by an interval (W2) smaller than a thickness (W1) of the metal wire to form a coil.
delete The plasma display panel as claimed in claim 1, wherein the electrode (10) is fixed on the upper portion and is composed of an insulator, and a plurality of partition walls (22) composed of an insulator to support both sides of the electrode And a terminal block (20) protruded from the terminal block (20).
The apparatus of claim 5, wherein the terminal block (20) is provided with screw tabs (21) at both ends thereof.
The terminal block 20 further includes an offset member 30 fixed to the terminal block 20 so as to cover the electrode 10 so as to offset leakage current leaking from the electrode 10. [ A device for preventing discharge and inundation by using a coil electrode.
8. The apparatus of claim 7, wherein the offset member (30)
An upper insulating plate 31 covering the electrode 10,
A side insulating plate 32 protruding downward from both sides of the upper insulating plate 31 and fixed to both sides of the terminal block 20,
An attenuator 33 which is positioned between the side insulating plates 32 and fixed to the lower portion of the upper insulating plate 31 so as to attenuate a current leaking from the electric wire 100;
And a grounding part (34) connected to the attenuation part (33) and grounding the micro current to be attenuated.
An input wire 100 to which commercial power is input,
An output wire 200 for supplying a commercial power input by the input wire 100 to the load,
A fastening member 60 for fastening the input wire 100 and the output wire 200,
The input wires 100 and the output wires 200 are connected to the outer side so as to attenuate the amount of energy flowing into the atmosphere so that the energy of the energy To reduce the discharge and to equalize the wavelength of the electric power and the wavelength of the electric power at the time of energy supply, it is necessary to increase the lifetime of the electric device and the electric appliance, A leakage preventing electrode 40 for preventing a short circuit or an electric shock through the liquid by flowing to the device or the electronic device,
And a terminal block (20) which is fixed by fastening of the fastening member (60) with the leakage preventing electrode (40) positioned between the fastening members (60) Device.

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