KR101088686B1 - Arc inducing type driven rod apparatus having needles - Google Patents

Abstract

PURPOSE: An ARC discharge type needle grounding device is provided to consume a surge current by inducing arc discharge in a lightning surge applied to a ground rod in a ground fault. CONSTITUTION: A discharge pipe(11) discharge a lightning surge of a high voltage to the ground through arc discharge. The upper side of a ground rod(13) is connected to a protection target on the surface. A discharge terminal(15) discharges a fault current of a low voltage applied through the ground rod to the ground. A plurality of needle electrodes(17) generate arc with a surge voltage. An arc induction coil(21) induces arc. A reverse surge preventing device(30) prevents a second reverse surge applied to the protection target along the ground rod.

Description

ARC INDUCING TYPE DRIVEN ROD APPARATUS HAVING NEEDLES}

The present invention relates to an arc discharge type needle grounding device, and in particular, a surge, an abnormal voltage, and an overcurrent caused by a lightning bolt are discharged to the earth as well as the secondary reverse surge applied to the protected device through the ground rod from the earth. The present invention relates to an arc discharge type needle grounding device capable of realizing low impedance characteristics to prevent noise and voltage displacement in small power electronic equipment.

In general, grounding is widely used as a means to protect the human body as well as the equipment by limiting the current in the form of an impulse generated by a lightning strike or by limiting the overcurrent or overvoltage which may be accidentally introduced into a power supply-related equipment such as a power system. Has been used.

However, as the IT industry develops these days, the concept of grounding not only prevents surges, abnormal voltages, and overcurrents, but also low-power small electronic devices mainly composed of semiconductor elements, for example, electronic control equipment (computer devices) and telecommunications. In facilities, etc., it has a greater meaning in implementing low impedance characteristics to prevent noise and voltage displacement.

On the other hand, since various surges contain harmonics, voltage drop due to ground conductor impedance, negligible at commercial frequency, induced voltage between conductors, and capacitance of earth are greatly affected. Is another aspect. Currently used electronic control and communication equipment is sensitive to electrical noise, so there is an urgent need for countermeasures against potential rises or induced voltages of ground conductors when the surge is invaded.

In order to solve the above problems, the present invention prevents the first reverse surge (B1) flowing from the ground while quickly and discharge the surge voltage applied to the ground rod from the discharge tube to the ground through the arc discharge, and the ground rod and the ground An object of the present invention is to provide an arc discharge needle grounding device for effectively blocking secondary reverse surge (B2) applied to a device to be protected through a reverse surge prevention device disposed between protection devices.

In order to achieve the above object, the present invention is a discharge tube embedded in the ground and discharges a high voltage surge surge to the ground through arc discharge; A grounding rod inserted into the discharge tube in a state spaced apart from the inner circumferential surface of the discharge tube and having an upper end connected to a device to be protected on the ground; A discharge end connected to a lower end of the ground rod for discharging a low voltage fault current applied through the ground rod to the ground; A plurality of precipitation electrodes installed on the ground rod to generate an arc by a surge voltage applied to the ground rod; An arc induction coil wound below the ground rod and connected to the discharge end to generate an electric potential difference between the settling electrode and the discharge tube to induce an arc, and act as an impedance to the first reverse surge flowing into the discharge end from the ground. ; And an reverse surge prevention device disposed between an upper end of the ground rod and the protected device to prevent a second reverse surge from being transferred to the protected device along the ground rod.

The reverse surge prevention element may be installed in the protected device or separately installed outside the protected device.

The reverse surge prevention element may be connected at least two or more in parallel between the upper end of the ground rod and the protected device.

The reverse surge prevention device is preferably a unidirectional diode, and may be formed of a semiconductor diode.

The present invention may of course further include a discharge gap located between the plurality of precipitation electrodes and the arc induction coil and connected to the ground rod and the inner circumference of the discharge tube.

The plurality of precipitation electrodes may be arranged in the circumferential direction of the ground rod, or may be arranged in the spiral direction along the outer circumference of the ground rod. In this case, the plurality of precipitation electrodes are preferably made of stainless steel to sufficiently withstand the melting caused by the arc.

As described above, in the present invention, arc discharge can be induced by a lightning surge applied to the ground rod in the event of a ground fault, and a considerable portion of the impact current can be consumed, and the potential difference between the ground and the ground rod can be quickly suppressed through the discharge gap. The discharge can be made, and the reverse surge prevention element is disposed between the ground rod and the protected device (low power small electronic equipment such as an information and communication facility) to effectively block the secondary reverse surge applied to the protected device. There is an advantage that the failure of the protected device can be prevented in advance.

1 is a schematic diagram showing an arc discharge needle grounding device according to an embodiment of the present invention,
2 and 3 are views showing various arrangements of a plurality of precipitation electrodes,
4 is a view showing an example in which the secondary reverse surge prevention device of the arc discharge needle grounding device according to an embodiment of the present invention is set in parallel.

Hereinafter, with reference to the accompanying drawings will be described the configuration of the arc discharge needle grounding device according to an embodiment of the present invention.

Referring to FIG. 1, the arc discharge needle grounding device 10 according to an embodiment of the present invention includes a discharge tube 11, a ground rod 13, a discharge end 15, a plurality of precipitation electrodes 17, and a discharge gap. 19, an arc induction coil 21 and a reverse surge prevention element 30 are included.

The discharge tube 11 is formed to a predetermined length and is embedded in the ground. Since the discharge tube has a larger diameter than the ground rod 13, the discharge tube can be contacted with a larger area with the ground, thereby reducing the ground resistance by extending the cross-sectional area of the ground electrode with respect to the incident frequency current. do.

The ground rod 13 is formed to have a diameter smaller than the inner diameter of the discharge tube 11, and the upper portion of the ground rod 13 is inserted in an insulated state from the discharge tube 11 by the insulator 12 when inserted into the discharge tube 11. The ground rod 13 has a lead wire 13a to which a grounding device 41, such as an electronic control facility or a communication facility, is connected.

In this case, the ground rod 13 is formed to have a length substantially corresponding to the length of the discharge tube 11, the lower end is connected to the discharge terminal 15 to prevent a commercial frequency fixed current that is not discharged to the ground through the discharge tube 11 Discharge to the ground through the front end (15).

A plurality of precipitation electrodes 17 are installed in the ground rod 13 to protrude from the outer circumference of the ground rod 13 toward the inner circumferential surface of the discharge tube 11. In this case, the tips of the plurality of precipitation electrodes 17 are set to be spaced apart from the inner circumferential surface of the discharge tube 11 by a predetermined distance, and the gap is induced to easily generate an arc between the precipitation electrode 17 and the inner circumferential surface of the discharge tube 11. In addition, it is preferable to maintain an appropriate distance to block the reverse surge flow into the discharge tube (11) from the ground.

The plurality of precipitation electrodes 17 may be arranged in the circumferential direction along the outer circumference of the ground rod 13 as shown in FIG. 2. In addition, the plurality of precipitation electrodes 17 are arranged in a spiral shape in consideration of the fact that the brain is a traveling wave and that the arc energy increases in proportion to the square of the discharge current. ) Can be protected.

In addition, the plurality of precipitation electrodes 17 is preferably made of stainless steel rather than copper or aluminum to withstand the melting due to the arc. The melting point of such stainless steel is about 1400 ° C. or higher, which is much higher than that of copper at 1083 ° C. or aluminum at 660 ° C.

The discharge gap 19 is interconnected between the inner circumferential surface of the discharge tube 11 and the ground rod 13, and is located between the plurality of precipitation electrodes 17 and the arc induction coil 21. The discharge gap 19 may suppress the potential difference between the ground and the ground rod 13 as the plurality of precipitation electrodes 17 discharge the low voltage to the ground in contact with the outer circumference of the discharge tube 11 while the discharge electrodes 17 discharge the high voltage. . Accordingly, the discharge gap 19 induces a stable discharge start voltage and enables rapid discharge.

The discharge gap 19 may be used at least one, but it can double the effect when using a plurality.

The arc induction coil 21 is wound along a lower portion of the ground rod 13 by a predetermined length and connected to the discharge end 15.

The arc induction coil 21 induces an arc by generating a potential difference between the plurality of precipitation electrodes 17 and the discharge tube 11 when a surge voltage is applied to the ground rod 13. In addition, the arc induction coil 21 can effectively suppress the first reverse surge B1 flowing from the ground into the discharge stage 15 due to the high impedance Z of the L.C value. Furthermore, the arc induction coil 21 also acts as a converter for discharging the commercial frequency leakage current to the ground through the discharge stage 15.

The reverse surge prevention element 30 is disposed between the upper end of the ground rod 13 and the to-be-protected device 40, for example, on the ground line 41 of the to-be-protected device 40 and is to be protected along the ground rod 13. To prevent the second reverse surge (B2). The reverse surge suppression element 30 is made of a unidirectional diode and preferably made of a semiconductor diode.

The reverse surge suppression element 30 is disposed on the ground line 41 of the device 40 to be installed inside the device 40 to be protected or to the outside of the device 40, for example, the ground rod 13 side. It is also possible to be installed separately from the device to be protected 40 at a position adjacent to it.

As shown in FIG. 4, at least two or more reverse surge prevention devices 30 may be connected in parallel. In this case, an effect of dispersing the secondary reverse surge B2 applied to the device to be protected 40 may be obtained. have.

Reference numeral 50 in FIG. 1 denotes a ground bus bar to which ground wires of a plurality of devices to be protected are connected.

As described above, the present invention can induce an arc discharge with respect to the lightning surge applied to the ground rod 13 in the event of a ground fault, and consume a considerable amount of impact current, and through the discharge gap 19, the ground and the ground rod 13 Fast discharge can be achieved by suppressing the potential difference between

In addition, the present invention arranges the reverse surge prevention element 30 between the ground rod 13 and the protected device 40 (such as low-power small electronic equipment such as information and communication equipment) to be applied to the protected device 40. By effectively blocking the reverse surge (B2) it is possible to prevent the failure of the device to be protected 40 in advance.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto, and the technical idea of the present invention and the following by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

11: discharge tube 13: ground rod
15: discharge stage 17: precipitation electrode
19: discharge gap 21: arc induction coil
30: Reverse surge prevention element

Claims (8)

A discharge tube embedded in the ground and discharging high voltage surges to the ground through arc discharge;
A grounding rod inserted into the discharge tube in a state spaced apart from the inner circumferential surface of the discharge tube and having an upper end connected to a device to be protected on the ground;
A discharge end connected to a lower end of the ground rod for discharging a low voltage fault current applied through the ground rod to the ground;
A plurality of precipitation electrodes installed on the ground rod to generate an arc by a surge voltage applied to the ground rod;
An arc induction coil wound below the ground rod and connected to the discharge end to generate an electric potential difference between the settling electrode and the discharge tube to induce an arc, and act as an impedance to the first reverse surge flowing into the discharge end from the ground. ; And
And an reverse surge prevention element disposed between an upper end of the ground rod and the protected device to prevent a second reverse surge from being transferred to the protected device along the ground rod. The method of claim 1,
The reverse surge prevention element is an arc induction needle grounding device, characterized in that installed in the protected device or separately installed outside the protected device. The method of claim 1,
The reverse surge prevention element is an arc induction needle grounding device, characterized in that at least two parallel connection between the upper end of the ground rod and the protected device. 4. The method according to any one of claims 1 to 3,
The reverse surge prevention device is an arc induction needle grounding device, characterized in that the unidirectional diode. The method of claim 4, wherein
The reverse surge prevention element is an arc induction needle grounding device, characterized in that the semiconductor diode. The method of claim 1,
And a discharge gap disposed between the plurality of precipitation electrodes and the arc induction coil and connected to the ground rod and the inner circumference of the discharge tube. The method of claim 1,
The plurality of precipitation electrodes are arranged in the circumferential direction of the ground rod, or arc-induced needle grounding device characterized in that arranged in a spiral direction along the outer circumference of the ground rod. 8. The method of claim 1 or 7,
The plurality of precipitation electrodes are arc induction needle grounding device characterized in that made of stainless steel.

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