KR101381805B1 - Apparatus and method for monitoring ground line - Google Patents

Abstract

The present invention relates to an apparatus for monitoring a ground line. The apparatus includes an open circuit sensing unit having an open circuit sensing line positioned at the outer surface of a ground line to surround an outer surface of the ground line; a sensing signal generating unit connected to a side of the open circuit sensing line to output an open circuit sensing signal; a sensing signal receiving unit connected to the other side of the open circuit sensing line and receiving the open circuit sensing signal transmitted through the open circuit sensing line, measuring a frequency and impedance indicating the reception state of the signal, and outputting the result of the measurement as an open circuit sensing line state signal; and a controller connected to the sensing signal receiving unit and reading the open circuit sensing line state signal received from the sensing signal receiving unit to determine the frequency and impedance and to compare at least one of the determined frequency and impedance with at least one between a reference frequency and reference impendence to determine the state of the ground line. [Reference numerals] (21) Setting switch; (22) Control unit; (23) Memory; (24) Sensing signal generating unit; (25) Sensing signal receiving unit; (26) Communications unit

Description

Ground wire condition monitoring device {APPARATUS AND METHOD FOR MONITORING GROUND LINE}

The present invention relates to a ground wire state monitoring device.

In general, a range in which radio waves arrive and communicate is called a zone, and the zone is divided into at least one cell.

Current mobile carriers are constructing a base station, which is a repeater, to improve the quality of mobile communication by performing a relay role between a mobile terminal such as a mobile communication terminal and a switching station on a cell.

Therefore, there is one base station for each cell, and in addition to the interface function between the mobile terminal and the switching center, the base station is provided with incoming / outgoing signal transmission, call channel designation, call channel monitoring, and self-diagnosis function to perform communication in the corresponding cell. To control.

As such, the operation of the base station plays a very important role in communication. If the ground line connected to the base station is damaged or lost, the operation of the base station adversely affects the operation of the normal base station, thereby preventing normal communication.

Therefore, the ground wire is buried in the ground to prevent damage or theft of the ground wire due to a disaster such as lightning.

As such, even when the ground wire is buried in the ground, part of the ground wire is exposed to the ground for connection with the base station installed on the ground.

Therefore, the part exposed to the ground is always exposed to the risk of damage or theft due to the disaster.

Therefore, there is an urgent need for a monitoring device that detects disconnection or damage of electric lines such as ground and signal lines.

Republic of Korea Patent Application Publication No. 10-2007-0073416 (Name of the invention: ground wire detection device of a mobile communication repeater)

Therefore, the technical problem to be achieved by the present invention is to accurately detect the installation state of the ground wire.

Ground wire disconnection monitoring device according to an aspect of the present invention is a disconnection detection unit having a disconnection detection line located on the outer surface of the ground wire to surround the outer surface, a detection signal connected to one side of the disconnection detection line to output a disconnection detection signal Generation unit, a detection signal receiving unit connected to the other side of the disconnection detection line receives the disconnection detection signal transmitted through the disconnection detection line, and measures the frequency magnitude and impedance corresponding to the reception state and outputs it as the disconnection detection line state signal. And determine the frequency magnitude and the impedance by reading the disconnection detection line state signal received from the detection signal receiver and connected to the detection signal receiver, and at least one of the determined frequency magnitude and the impedance is selected from among the reference frequency magnitude and the reference impedance. Determine the state of the ground wire in comparison with at least one It is a control unit.

The control unit may determine the state of the ground line as a disconnected state when the frequency magnitude of the disconnection detection line state signal is determined to be a set frequency magnitude and thus the disconnection detection signal is not received by the detection signal receiver.

The controller may determine the state of the ground line as a check state when the frequency magnitude of the disconnection detection line state signal does not exist within an error range of the reference frequency magnitude.

The controller determines whether the determined impedance is within an error range of the reference impedance when the frequency magnitude of the disconnection detection line state signal is within an error range of the reference frequency magnitude, and the determined impedance is equal to the reference impedance. If it does not exist within the error range, the state of the ground line may be determined as a check state.

The ground line state monitoring apparatus according to the feature may be connected to the control unit, and may further include a setting switch for maintaining a first state or a second state, wherein the control unit is configured such that the state of the setting switch is set to the first state. The frequency and impedance determined by the disconnection detection line state signal received from the detection signal receiver for the first time after changing to the second state may be set as the reference frequency and the reference impedance.

The ground line state monitoring apparatus according to the feature may further include a communication unit connected to the control unit, and the control unit outputs a ground line state signal of a corresponding state to the communication unit according to the determined state of the ground line, and the communication unit The ground line state signal may be output to the management device through wireless communication or wired communication.

According to another aspect of the present invention, a method for monitoring a ground line state may include outputting a driving signal to a detection signal generator to operate the detection signal generator to output a disconnection detection signal to a disconnection detection line, and a detection signal receiver connected to the disconnection detection line. Determining whether the disconnection detection line status signal received from the receiver is received; and when the disconnection detection line status signal is received, the frequency magnitude and impedance of the disconnection detection signal received by the detection signal receiving unit are determined using the disconnection detection line status signal. Determining, when the determined frequency magnitude is a set frequency magnitude, determining a state of a ground wire as a disconnected state; when the determined frequency magnitude is out of an error range of a reference frequency magnitude, checking a state of the ground wire Determining that the frequency magnitude is a reference frequency magnitude Comparing the determined impedance with an error range of a reference impedance when present within an error range, and determining the state of the ground line as a normal state when the determined impedance is within an error range of a reference impedance, and determining the And if the impedance is outside the error range of the reference impedance, determining the state of the ground line as a check state, wherein the disconnection sensing line surrounds the outer surface of the ground line.

According to this characteristic, the state of a ground line is determined using the disconnection detection line detachably attached to the outer surface of a ground line. As a result, it is not necessary to design the ground wire and the disconnection detection wire integrally, and the detachment of the disconnection detection part is easily performed as necessary, thereby reducing the installation cost and improving the user's satisfaction.

In addition, since the state of the ground line surrounded by the disconnection sensing line is determined using the state of the impedance as well as the frequency magnitude of the disconnection sensing signal received through the disconnection sensing line, the state of the grounding line is more accurately determined.

1 is a block diagram of a ground line state monitoring apparatus according to an embodiment of the present invention.
2 is a schematic perspective view of a disconnection detecting unit according to an exemplary embodiment of the present invention.
3 is a diagram schematically illustrating a state in which a disconnection detecting unit is installed in a ground line according to an exemplary embodiment of the present invention.
4A and 4B are flowcharts illustrating operations of a ground line state monitoring device according to an embodiment of the present invention, respectively.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

The ground line state monitoring apparatus of the present invention will now be described with reference to the accompanying drawings.

First, the structure of the ground line state monitoring apparatus according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 3.

The ground line state monitoring apparatus according to an embodiment of the present invention includes a disconnection detecting unit 10 surrounding at least a portion of the ground line 1 exposed to the ground, a setting switch 21 for setting a reference frequency magnitude and a reference impedance, The control unit 22 connected to the setting switch 21, the memory 23 connected to the control unit 22, and the detection signal generator 24 connected to one side of the control unit 22 and the disconnection detecting unit 10. ), A detection signal receiver 25 connected to the other side of the control unit 22 and the disconnection detection unit 10, and a communication unit 26 connected to the control unit 22.

In general, the ground line 1 is connected to one side of the ground terminal of the device, such as a base station, the other side is buried in the ground to provide a ground of the device.

The ground wire 1 is a coated wire made of copper (Cu) or the like, and is made of a signal transmission line composed of stranded wire or single wire and an insulating material such as PVC (polyvinyl chloride) to cover the signal transmission portion. The covering part is provided.

The ground line 1 is partially buried in the ground as shown in FIG. 3 so that one terminal of the ground line 1 is grounded in the ground and the other part is exposed to the ground and connected to the ground terminal of the corresponding device such as a base station installed on the ground.

When a part of the ground wire 1 is exposed to the ground as described above, the disconnection detecting unit 10 surrounds at least a part of the outer surface of the exposed ground wire 1.

As shown in FIG. 2, the disconnection detecting unit 10 also includes a disconnection detecting line 11, which is a signal transmission line for transmitting a disconnection sensing signal output from the sensing signal generator 24, in the same manner as the ground line 1. In order to protect the 11, the coating part 12 is provided.

In this case, the disconnection detection line 11 may also be formed of a twisted pair or a disconnected wire, and may be an unshielded twisted pair cable (UTP), a shielded twisted pair cable (STP), or the like.

Accordingly, the detection signal generator 24 and the detection signal receiver 25 are electrically and physically connected to the disconnection detection line 11 of the disconnection detection unit 10, respectively.

Since the disconnection detecting unit 10 has a wiring form as illustrated in FIG. 2, the disconnection detecting unit 10 is wound on the outer surface of the ground wire 1 which is easily exposed to the outside by an installer or an administrator, and is peeled off as necessary. It does not need to be formed integrally with 1).

For this reason, installation and disassembly are easy on the outer surface of the ground wire 1, and it is easily installed on the ground wire 1 already installed.

In the present example, the disconnection detecting unit 10 is in the form of a wire as described above, but alternatively, the disconnection detecting unit 10 may be formed in various forms such as a cover shape in which at least a part of the outer surface of the ground line 1 can be completely enclosed. have. In this case, the signal transmission portion is configured in the form of a wiring, and the cover portion covering the signal transmission portion is designed in various shapes such as a rectangle, so that the disconnection detection line 11 is formed on the outer surface of the ground line 1. It is installed roundly.

As described above, since the disconnection detection line 11 of the disconnection detection unit 10 surrounds the ground wire 1, an operating state (eg, an impedance state) of the disconnection detection line 11 is connected to the ground wire 1. Will be affected by interference.

The setting switch 21 is a switch that is turned on or off by an administrator or installer, and provides a signal of a corresponding state according to an off state (eg, a first state) or an on state (eg, a second state). It outputs to the control part 22.

The control unit 22 may determine the disconnection or damage state of the disconnection detecting line 11 by using the impedance and the frequency of the signal received from the detection signal receiving unit 25 according to the operation of the setting switch 21. Set the reference impedance.

The memory 23 stores a reference impedance magnitude and a reference frequency magnitude for determining whether the disconnection detection line 11 is disconnected.

At this time, when it is determined that the setting switch 21 is in an on state or vice versa by the state of the signal output from the setting switch 21, the control unit 22 operates the detection signal generator 24 to disconnect the wire. The detection line 11 outputs a disconnection detection signal of an AC state having a predetermined frequency magnitude, and sets the magnitudes of the first measured impedance and frequency as the reference impedance and the reference frequency magnitude and stores them in the corresponding address of the memory 23. .

As described above, when setting the reference frequency magnitude and the reference impedance by using the setting switch 21, the installer or the administrator detects the disconnection detection line 11 and the disconnection detection line 11 is normally installed on the ground line 1 when the ground line 1 is in a normal state. When the line 11 is also in the normal state, the setting switch 21 is operated to set the reference frequency magnitude and the reference impedance.

 However, differently, the impedance and the frequency magnitude determined according to the experiment operation separately performed regardless of the operation of the setting switch 21 may be directly stored in the memory 23 as the reference impedance and the reference frequency magnitude.

The reference impedance may vary depending on the thickness and length of the disconnection detection line 11, the thickness and length of the ground line 1, and the reference frequency may also vary depending on the thickness and length of the disconnection detection line 11.

In this case, the setting switch 21 may be omitted.

The sensing signal generator 24 operates according to the driving signal output from the controller 22 and outputs a disconnection sensing signal having a corresponding frequency magnitude and amplitude to the disconnection sensing line 11 at a set period.

As such, the disconnection detection signal output from the detection signal generator 24 flows along the disconnection detection line 11 and is applied to and received by the detection signal receiver 25.

Therefore, when the disconnection detection line 11 is disconnected or broken, the detection signal reception unit 25 does not receive the disconnection detection signal, or the reception state is an abnormal state rather than a normal state.

In addition, as described above, since the disconnection sensing unit 10 and the ground line 1 are in physical contact with each other, an electrical interference phenomenon occurs between the ground line 1 and the disconnection sensing unit 10. Accordingly, the impedance state of the signal received by the detection signal receiver 25 through the disconnection detection line 11 is not only a state of the disconnection detection line 11, that is, whether the ground wire 1 is disconnected or damaged. Depends on.

The detection signal receiver 25 measures whether the disconnection detection signal applied through the disconnection detection line 11 and the impedance of the disconnection detection line 11 are measured, and outputs the disconnection detection line state signal of the corresponding state to the controller 22. do.

For example, when the disconnection detection line 11 is disconnected, the signal output from the detection signal generator 24 is not input to the detection signal receiver 25, and the disconnection detection line 11 or the ground line 1 may not be input. The magnitude of the impedance measured by the detection signal receiver 25 varies according to the disconnection or damage degree and the presence or absence of the ground wire 1.

In general, impedance is the ratio of current and voltage in a signal line such as ground line 1.

A transmission line such as the ground line 1 has an input impedance Zs and a load impedance Z _L formed in series, and the characteristic impedance Zo is calculated by the following equation (1).

Where R is conductor resistance, C is capacitance (F / m), L is inductance (H / m), and G is conductance (S / m).

If a transmission line having such an impedance specification has the same characteristic characteristic as that of the transmission line installed on the transmission line and the load impedance, there is no voltage standing wave ratio or current standing wave ratio on the line, so the amount of attenuation of the signal increases, but Reflection does not occur.

However, when the characteristic impedance and the load impedance are different from each other, there is a voltage standing wave ratio and a current standing wave ratio in the transmission line, which causes reflection loss due to impedance mismatch between the transmission lines of the transmission line.

Accordingly, the detection signal receiver 25 measures the structural reflection loss by measuring the degree of mismatch between the input impedance Zs of each frequency of the transmission line with the characteristic impedance Zo of the transmission line, and the frequency magnitude of the received signal using the same. Determine.

The characteristic impedance, one of the important factors that determine the characteristics of a transmission line, is defined as the ratio of voltage and current applied to the transmission line, which represents the inherent characteristics of the transmission line as a complex defined in a certain frequency domain. At a constant frequency, it has a constant value regardless of the length of the transmission line.

However, if the characteristic impedance is out of the range of the specified value according to the transmission line, a rapid increase in the return loss causes an error occurrence rate during data transmission and a stability of the voice signal.

Therefore, the detection signal receiver may measure and use the characteristic impedance.

The frequency of the characteristic impedance may be 20 Hz to 16 MHz.

Accordingly, the detection signal receiver 25 measures the impedance according to the frequency magnitude of the disconnection detection signal and the state of the disconnection detection line 11 and the ground line 1 determined according to whether the measured disconnection detection signal is received. It outputs to the control part 22 as a status signal.

For this reason, the controller 22 compares the frequency magnitude and impedance input from the detection signal receiver 25 with the reference frequency magnitude and the reference impedance to determine the situation of the ground line 1 and outputs a ground line state signal of the corresponding state.

In this case, the controller 22 may output the position information of the ground line 1 by using the information stored in the memory 23. In this case, the location information of the ground line 1 is already stored in the memory 23.

The communication unit 26 outputs a ground line state signal output from the control unit 22 to the outside through wireless or wired communication.

Accordingly, the ground line status signal applied from the communication unit 26 is received by a control unit (eg, a network management system (NMS)) of the management apparatus managing the corresponding ground line 1 such as a base station.

The management device that receives the ground line state signal determines whether the current ground line 1 is normal or an abnormal state other than a normal state due to disconnection or scratch, using the state of the ground line state signal.

Therefore, when the state of the ground line 1 is in an abnormal state by the ground line state signal, the management device can output a warning signal to quickly and accurately inform the manager of the abnormal state of the ground line state signal. In this case, the warning signal may be transmitted to a mobile phone or a computer of a registered administrator to notify at least one administrator of an abnormal state of the ground line 1 through a text or an email.

To this end, the communication unit 26 may use a communication method such as RS232C, RS485, or use Ethernet or a telephone network.

In addition, for wireless communication, the communication unit 26 uses a wireless modem (MODEM) to connect to Wi-Fi (WiFi), Bluetooth, code division multiple access (CDMA), wideband code division multiple access (WCDMA), and LTE (long). A ground line state signal may be transmitted in a term evolution (LET) and a long term evolution-advanced (LET-A) scheme.

Next, the operation of the ground line state monitoring apparatus will be described in detail with reference to FIG. 2.

When power required for the operation of the ground line state monitoring device is supplied due to the operation of the power supply unit (not shown), and the ground line state monitoring device is operated, the controller 22 starts an operation (S10).

First, an operation for measuring the reference frequency magnitude and the reference impedance corresponding to the state of the current disconnection detecting line 11 and storing it in the memory 23 is performed.

To this end, the administrator first changes the setting switch 21 from the off state to the on state, and then changes the state of the setting switch 21 from the off state to the on state and is detected by the detection signal receiver 25 for the first time. Set the magnitude and impedance of the disconnection detection signal as the reference frequency and reference impedance.

For the setting operation of the reference frequency magnitude and the reference impedance, the control unit 22 first reads the signal applied from the setting switch 21 (S11) so that the state of the signal output from the setting switch 21 is turned off. It is determined whether it has changed to the on state (S12).

When the state of the signal output from the setting switch 21 is changed from the off state to the on state, the controller 22 outputs the driving signal to the detection signal generator 24.

Accordingly, the detection signal generator 24 starts an operation according to the driving signal applied from the controller 22 and outputs the disconnection detection signal of an AC state having a frequency and amplitude of a predetermined magnitude to the disconnection detection line 11.

Thus, the disconnection detection signal is applied toward the detection signal receiver 25 along the disconnection detection line 11.

Then, the sensing signal receiver 25 determines the frequency magnitude and impedance of the disconnection sensing signal received through the disconnection sensing line 11, and outputs a ground line state signal of the corresponding state to the controller 22.

Therefore, when the ground line state signal is input from the detection signal receiver 25 for the first time after the state of the setting switch 21 is changed from the off state to the on state (S14), the control unit 22 uses the ground line state signal to adjust the frequency magnitude. The impedance magnitude is determined and the determined frequency magnitude and impedance value are stored in the memory 23 as the reference frequency magnitude and the reference impedance (S15).

In this way, when setting the reference frequency magnitude and the reference impedance for determining whether the ground wire 1 is disconnected or an abnormal state by using the setting switch 21, an abnormal setting switch by a person other than a designated person such as an administrator or an installer ( In order to prevent the operation of the 21, the setting switch 21 may be located inside the case (case) of the ground wire state monitoring device so as not to be exposed to the outside.

As such, when the reference frequency magnitude and the reference impedance corresponding to the state of the current disconnection detecting line 11 are set, the controller 22 determines whether the set time has elapsed by using a timer (not shown) or the like (S16). ).

When the set time has elapsed, the controller 22 outputs the driving signal to the detection signal generator 24 again (S17).

Then, the controller 22 waits for the disconnection detection line state signal output from the detection signal receiver 25 (S18).

When the disconnection detection line status signal is input from the detection signal receiver 25, the controller 22 determines the frequency magnitude and the impedance using the input disconnection detection line status signal (S19).

Next, it is determined whether the disconnection detection line 11 is in the disconnection state by using the frequency magnitude determined by the input disconnection detection line state signal (S20).

That is, when the disconnection detection line 11 is disconnected, the disconnection detection signal output from the detection signal generator 24 is not input to the detection signal receiver 25.

Therefore, when the disconnection detection signal output from the detection signal generator 24 is not input within the set time, the detection signal receiver 25 is in a state in which the disconnection detection signal is not received due to the disconnection of the disconnection detection line 11. The determination is made, and the set frequency (for example, 0 Hz) in the disconnection state is changed into a digital signal and output to the control unit 22 in frequency magnitude.

At this time, since the controller 22 knows the time point at which the driving signal is output to the detection signal generator 24, the controller 22 notifies the detection signal receiver 25 of the output time point of the driving signal, and the detection signal receiver 25 detects the driving signal. It can be determined whether the set time has elapsed based on the output time point. In this case, it is more accurately determined whether the disconnection detection signal is not received by the disconnection of the disconnection detection line 11 or the disconnection detection signal due to the signal delay.

When the frequency magnitude determined by the disconnection detection line state signal applied from the detection signal receiving unit 25 is determined to be the disconnection state of the disconnection detection line 11 (S20), the control unit 22 causes the ground line to be lost due to theft or lightning. Together with (1), the disconnection detecting line 11 is also determined to be disconnected, and the state of the ground wire 1 is determined to be disconnected (S21).

Therefore, the control unit 22 outputs the ground line state signal and the position information of the ground line 1 to the management device such as the base station in a state indicating the disconnection state of the ground line 1 through the communication unit 26 (S22). In step S16, the detection signal generator 24 is operated every set time to monitor the state of the ground line 1 using the disconnection detection line 11.

For this reason, the management apparatus quickly and accurately recognizes that the ground line 1 is in the disconnection state by using the ground line state signal received through the communication unit 26, so that the administrator can quickly perform the necessary action.

However, when the state of the disconnection detection line 11 determined by the disconnection detection line state signal received from the detection signal receiver 25 is not the disconnection detection line 11 is disconnected, the controller 22 determines that the determined current The frequency magnitude is compared with the reference frequency magnitude to determine whether the current frequency magnitude is within an error range of the reference frequency magnitude (S23).

If the determined current frequency magnitude is out of the error range of the reference frequency magnitude, the controller 22 determines that the state of the disconnection detection line 11 is abnormal rather than a normal state in which the detection signal is normally transmitted due to covering or damage. do.

In this manner, when the state of the disconnection detecting line 11 surrounding the ground wire 1 is abnormal even though it is not disconnected, the ground wire 1 is also determined to be in a damaged or partially broken state.

Therefore, the control unit 22 determines the state of the ground line 1 as a state in need of inspection (S24), and outputs the state of the ground line state signal to the management device through the communication unit 26 (S25).

For this reason, the management apparatus allows the inspection of the ground line 1 to be performed by using the state of the ground line state signal output from the ground line state monitoring device, thereby preventing further failure or economic loss.

However, when the frequency magnitude of the determined disconnection detection line state signal is within an error range of the reference frequency magnitude, the controller 22 detects that the disconnection detection signal is detected by the detection signal generator 25 at the magnitude of the predetermined frequency. To be received.

In this case, the control unit 22 compares the current impedance determined in step S19 with the reference impedance to determine whether the current impedance is within an error range of the reference impedance (S26).

If the determined current impedance value is within the error range of the reference impedance, the controller 22 determines that the impedance of the disconnection detecting line 11 affected by the ground line 1 is the same as that of the reference impedance in a normal state, and thus disconnection. Not only the sensing line 11 but also the state of the grounding line 1 is determined to be a normal state (S27).

Therefore, the control unit 22 outputs the ground line state signal and the ground line 1 position information in the normal state to the management device through the communication unit 26 (S28), and then proceeds to step S16. For this reason, the management device confirms that the state of the ground line 1 is normal by using the ground line state signal received.

However, when the determined current impedance value does not exist within the error range of the reference impedance, the controller 22 is in an abnormal state in which the disconnection detection line 11 is not in a normal state and needs to be checked by the ground line 1. It determines (S29).

That is, when the ground wire 1 is damaged, the impedance of the disconnection detection line 11 also increases due to the increase in the impedance of the ground line 1, so that the measured impedance of the disconnection detection line 11 is larger than the reference impedance. Will be maintained.

In addition, when only the ground wire 1 wound by the disconnection detection line 11 is lost without damaging the disconnection detection line 11, and there is no grounding wire 1 surrounded by the disconnection detection line 11, The influence of the impedance by the ground wire 1 disappears. Therefore, in this case, the measured disconnection sensing line 11 has a smaller value than the reference impedance.

As such, even if the frequency of the disconnection detection line state signal input to the detection signal receiver 25 maintains the reference frequency level, the impedance of the disconnection detection signal received by the detection signal receiver 25 depends on the state of the ground line 1. Will change.

Therefore, when the determined current impedance value is different from the reference impedance, the control unit 22 determines the state of the ground wire 1 as a state requiring inspection (S29).

Then, the control unit 22 outputs to the management device through the communication unit 26 to the state of the ground line state signal to the check state (S30).

Next, the controller 22 proceeds to step S16 and outputs a detection signal to the disconnection detection line 11 at every set time to monitor the state of the ground line 1.

For this reason, the management apparatus determines the state of the ground line 1 according to the ground line state signal output from the ground line state monitoring device, so that the inspection operation of the ground line 1 is performed.

In this example, the control unit 22 outputs the ground line state signal to the external management device via the communication unit 26.

However, in an alternative example, the detection signal receiver 25 may output the disconnection detection line status signal to the controller 22 directly through an additional communication unit such as the communication unit 26 to an external management device.

Accordingly, the disconnection detection line status signal is received by the control unit (eg, NMS) of the management apparatus, and the control unit that has received the disconnection detection line status signal uses the disconnection detection line status signal in the same manner as the operation described by the controller 22. Thus, it is determined whether the state of the ground line 1 is a disconnection state factor checking state or a normal state.

In this case, the step of transmitting the ground line state signal through the communication unit 26 to inform the management apparatus of the ground line state is omitted.

As described above, since the ground line 1 is determined using only the reception of the sensed disconnection detection signal, the ground line 1 is determined by using the impedance change, and thus the installation state of the ground line 1 is accurately determined.

In addition, by installing the disconnection detection unit 10 on the ground line (1) already installed to determine the installation state of the desired ground line (1). Therefore, it is not necessary to design integrally with the ground wire 1, and the detachable detection unit 10 can be easily attached and detached as necessary, thereby reducing installation costs and improving user satisfaction.

In the case of this example, the ground wire 1 is determined, for example, whether the ground wire 1 is disconnected, but it is obvious that the present invention can be applied to other transmission lines that transmit electric signals without being limited thereto.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

21: setting switch 22: control unit
23: memory 24: detection signal generator
25: monitoring signal receiving unit 10: disconnection detecting unit
11: disconnection detection line 12: covering part

Claims (7)

Disconnection detection unit having a disconnection detection line located on the outer surface of the ground wire to surround the outer surface,
A detection signal generator connected to one side of the disconnection detection line and outputting a disconnection detection signal;
A detection signal receiver connected to the other side of the disconnection detection line to receive the disconnection detection signal transmitted through the disconnection detection line, measuring a frequency magnitude and an impedance corresponding to a reception state, and outputting the signal as a disconnection detection line state signal; and
Read the disconnection detection line state signal received from the detection signal receiver to determine a frequency magnitude and an impedance, and determine at least one of the determined frequency magnitude and impedance at least one of a reference frequency magnitude and a reference impedance. A control unit for determining the state of the ground line in comparison with
Lt; / RTI >
The control unit is configured to determine the state of the ground line as a disconnected state when the frequency magnitude of the disconnection detection line state signal is determined to be a set frequency magnitude and thus the disconnection detection signal is not received by the detection signal receiver.
Ground wire condition monitoring device. delete In claim 1,
And the control unit determines the state of the ground line as a check state when the frequency magnitude of the disconnection detection line state signal does not exist within an error range of the reference frequency magnitude. In claim 1,
The controller determines whether the determined impedance is within an error range of the reference impedance when the frequency magnitude of the disconnection detection line state signal is within an error range of the reference frequency magnitude, and the determined impedance is equal to the reference impedance. And a ground line state monitoring device for determining the state of the ground line as a check state when not present within an error range. In claim 1,
A setting switch connected to the control unit and maintaining a first state or a second state;
The control unit is further configured to determine the frequency magnitude and impedance determined by the disconnection detection line state signal received from the detection signal receiver for the first time after the state of the setting switch is changed from the first state to the second state. Set to impedance
Ground wire condition monitoring device. In claim 1,
Further comprising a communication unit connected to the control unit,
The control unit outputs a ground line state signal of a corresponding state to the communication unit according to the determined state of the ground line,
The communication unit outputs the ground line state signal to a management device by wireless communication or wired communication.
Ground wire condition monitoring device. Outputting a driving signal to a detection signal generator to operate the detection signal generator to output a disconnection detection signal to a disconnection detection line;
Determining whether a disconnection detection line status signal received from a detection signal receiver connected to the disconnection detection line is received;
Determining the frequency magnitude and impedance of the disconnection detection signal received by the detection signal receiver by using the disconnection detection line status signal when the disconnection detection line status signal is received;
Determining the state of the ground line as a disconnected state when the determined frequency magnitude is a set frequency magnitude,
Determining the state of the ground line as a check state when the determined frequency magnitude is out of an error range of a reference frequency magnitude,
When the determined frequency magnitude is within an error range of a reference frequency magnitude, comparing the determined impedance with an error range of a reference impedance, and
Determining the state of the ground line as a normal state when the determined impedance is within an error range of a reference impedance, and determining the state of the ground line as a check state when the determined impedance is out of an error range of the reference impedance.
Lt; / RTI >
The disconnection detection wire surrounds the outer surface of the ground wire.
How to monitor ground wire condition.

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