JP2010080129A - Surge counter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an inexpensive surge counter having a small installation space and consuming less power in recording the magnitudes of surge currents and the number of times of the occurrence of surge currents. <P>SOLUTION: The surge counter records the magnitudes of surge currents and the number of times of the occurrence of surge currents on a recording sheet 2 by operating an electromagnet 31 using output currents due to surges occurring in a target line 1, thus there is no need of providing an external power supply for operating a recording section 30. Furthermore, since the recording sheet 2 is fed by utilizing the return motion of the electromagnet 31, there is no need of providing an external power supply for operating a paper feed section 50. Thus, it is possible to provide a surge counter capable of reducing the power consumption in recording the occurrence of surges to zero or to a very small value. Moreover, since the recording operation of surges and the paper feed operation are performed with merely the operation of the electromagnet 31 as the power source, a compact and inexpensive surge counter having a very simple structure can be provided. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a technique of a surge counter that records the magnitude of the surge current / voltage generated in cables due to lightning strikes and the number of occurrences thereof.

  For example, when a single disturbance signal such as a lightning surge current / voltage generated by lightning enters a communication device or information processing device, it causes physical failure or malfunction of these devices. There is a possibility of causing not only equipment failure but also very large social loss and economic loss such as suspension of various services. In order to prevent device failure and malfunction due to such disturbance signals, statistically investigate the frequency of lightning surge current generation, its magnitude, and its intrusion route, and install appropriate surge protection devices appropriately. It is important to take such measures. In addition, in order to confirm the effect of countermeasures, investigating the frequency and magnitude of lightning surge current after countermeasures and evaluating the implemented countermeasures can improve problems such as missing countermeasures and lack of tolerance, This is important in increasing the certainty of measures against lightning surges. However, it is very difficult to measure the frequency and magnitude of lightning surge current because lightning is a natural phenomenon and occurs very little and various intrusion paths can occur.

  Conventionally, as a method for detecting the magnitude of such a disturbance signal and the intrusion route, as shown in FIG. 27, the sensor 103 is connected to various possible lightning surge inflow / outflow routes such as a communication line and a power line connected to the apparatus 100. Is used to record the lightning surge current waveforms detected by the sensors at each measurement point at the same time using one (at most about two) oscilloscopes 105 used as a signal waveform recording device. It was. In that case, a control / recording device 107 for recording a plurality of data and controlling the oscilloscope 105 is required. Further, it is necessary to use an AC power source (not shown) as a power source for the oscilloscope 105 and the control / recording device 107, and it is necessary to use an insulating transformer 111 in order to avoid the influence from the commercial power source 109. Furthermore, it was necessary to use an uninterruptible power supply (not shown) such as UPS in preparation for a power failure. Thus, since the measuring equipment using an oscilloscope becomes large-scale, a great initial cost is required and a large installation space is required.

  On the other hand, as another measurement method, a surge counter that records only the magnitude and date and time of occurrence of lightning surge current may be used. As shown in FIG. 28, this surge counter 113 has the merit that it can be measured with almost no installation space, but it requires a large capacity battery 115 as a power source for operation and a measurable path is one point. Therefore, it is necessary to install a large number of surge counters in order to identify the lightning surge intrusion route. Further, such a surge counter 113 is expensive because an electronic circuit such as an A / D conversion unit, a data recording unit, and a generation time recording unit is necessary. There was a problem that would be enormous.

  In addition, there is a method using a magnetic steel piece or the like for measuring only the magnitude of the lightning surge current, but there is a problem that only the maximum value of the lightning surge generated during the installation period is recorded and the measurement accuracy is low.

Such conventional techniques are disclosed in Patent Document 1 and Non-Patent Documents 1 to 3.
JP-A-5-89939 Sankosha Co., Ltd., “Surge Counter”, [online], [Search September 10, 2008], Internet <http://www.sankosha.co.jp/product/category.html?cid=71> Otowa Electric Industry Co., Ltd., “Surge Counter LED Display Type”, [online], [Search September 10, 2008], Internet <http://www.otowadenki.co.jp/product/all/d-0570 .html> Morinaga Electronics Co., Ltd., “Thunder Surge Counter”, [online], [Search September 10, 2008], Internet <http://alp-plp.co.jp/document/pdf/catalog_mlc.pdf>

  As mentioned above, long-term observation is required to measure lightning surges that occur at low frequency, and in conventional technologies such as oscilloscopes and surge counters, it is necessary to continuously supply power to them. Therefore, there is a problem that it is necessary to use an AC power source or a large-capacity battery, and there is a problem that an operation such as replacing the battery is required because it is difficult to secure a power source particularly in outdoor observation.

  In addition, since it is necessary to provide many observation points in order to identify the lightning surge current path, a large number of sensors must be installed, and there is a problem that an initial investment for equipment is burdened.

  Furthermore, in the measurement using an oscilloscope or a surge counter, there is a problem that the place where the measurement can be performed is limited because an installation space for the device is required.

  Furthermore, when measuring using magnetic steel pieces, there is a merit that the above problems can be solved, but there is a problem that only the maximum value of lightning surge generated during the measurement period can be measured, and the measurement accuracy is low. It was.

  The present invention has been made in view of the above, and when recording the magnitude of the surge current caused by lightning strikes and the number of occurrences thereof, the power consumption for the recording is reduced and the installation counter is small and inexpensive. It is an issue to provide.

  The invention according to the first claim detects a surge generated in the conductor to be detected, outputs a current or voltage proportional to the magnitude of the surge, and an electromagnet using the output current or output voltage. Recording means for recording an identification display proportional to the magnitude of the surge by pressing a pressing portion interlocked with the operation to the recording medium, and the electromagnet after the surge passes through the detected conductor The gist of the invention is to have a recording medium feeding means for feeding the recording medium in a certain direction by using an operation of returning to a position.

  The invention according to a second aspect further includes branching means for branching the output current or the output voltage into a positive output and a negative output, and the recording means uses the positive output. The gist of the invention is that it is composed of positive recording means for recording the identification display and negative recording means for recording the identification display using the negative output.

  The gist of the invention according to the third aspect is that it further comprises a date and time recording means for recording the date and time of occurrence of the surge on the recording medium in association with the identification display.

  According to a fourth aspect of the present invention, the recording medium is recording paper, the pressing portion is a conical needle attached to the tip of the electromagnet, and the recording means includes the conical needle. The gist is to make a hole in a size proportional to the size of the surge by pressing against the recording paper.

  According to a fifth aspect of the invention, the recording medium is recording paper, the pressing portion is a plurality of needles attached to the tip of the electromagnet, and the recording means records the plurality of needles to the recording medium. The gist is to press a sheet of paper and make a number of holes proportional to the magnitude of the surge.

  The invention according to the sixth aspect is a pressure measuring film capable of changing a gray scale display according to a pressure applied to the recording medium, wherein the recording means presses the pressing portion against the pressure measuring film, The gist is to display light and shade proportional to the magnitude of the surge.

  ADVANTAGE OF THE INVENTION According to this invention, when recording the magnitude | size of the surge current resulting from a lightning strike, etc., and the frequency | count of the occurrence, it is possible to provide a surge counter which can reduce the power consumed for the recording and has a small installation space and is inexpensive.

[First Embodiment]
FIG. 1 is a configuration diagram showing the overall configuration of the surge counter according to the first embodiment. A surge current / voltage pickup sensor 10 is installed close to the conductor 1 to be detected, which is a surge intrusion path, and is output from the surge current / voltage pickup sensor 10 when a surge generated in the conductor 1 to be detected is detected. By operating the electromagnet 31 using the output current or output voltage, a hole is made in the recording paper 2 with a force proportional to the magnitude of the surge. Further, by operating the paper feeding unit 50 using the return operation of the electromagnet 31, a plurality of surges can be recorded on the recording paper 2. The size and number of occurrences of the surge can be determined based on the size and number of holes formed in the recording paper 2. Hereinafter, the configuration and function of the surge counter according to the present embodiment will be specifically described.

  FIG. 2 is a functional block diagram showing functional blocks of the surge counter according to the first embodiment. This surge counter is configured to include a current / voltage detection unit 10, a recording unit 30, and a paper feeding unit 50.

  The current / voltage detection unit 10 corresponds to the surge current / voltage pickup sensor 10 shown in FIG. 1, and detects and detects a surge flowing through the measured line 1 (corresponding to the detected conductor 1 described above). A function of outputting a current or voltage proportional to the magnitude of the surge is provided. When detecting current, CT (current transformer), Rogowski coil, shunt resistance, etc. can be used. When detecting voltage, voltage probe, voltage divider, etc. can be used, and the measurement environment It is possible to select appropriately according to. Of course, when detecting current and voltage, both a CT and a voltage probe can be used. In addition, the measured line 1 may be exemplified by a power line and a ground line included in a communication device or an information processing device, or a communication line used when the device communicates with another communication device or the like. it can. In the present embodiment, it is assumed that the output from the current / voltage detection unit 10 is an output current, and the following description will be continued. Of course, it goes without saying that the same effect can be obtained even if the output voltage is used instead of the output current.

  The recording unit 30 operates the electromagnet 31 using the output current from the current / voltage detection unit 10, presses the pressing unit 32 linked to the operation of the electromagnet 31 against the recording paper 2, and is proportional to the magnitude of the surge. A function of recording the identification display on the recording paper 2 is provided. Specifically, the electromagnet 31 is pushed downward by a force proportional to the magnitude of the output current, and the recording paper 2 is used using a conical needle attached to the tip of the electromagnet 31 (corresponding to the pressing portion 32). Make a hole in the recording. In this case, since a force proportional to the detected surge is applied to the recording paper 2, as shown in FIG. 3, the magnitude of the surge current generated is determined from the size of the recorded hole. Can do. As for the size of the holes recorded on the recording paper 2, as shown in FIG. 4, it is easy to create a hole pattern corresponding to the output current from the current / voltage detection unit 10 in advance. It will be possible to judge.

  The paper feeding unit 50 has a function of rotating the upper and lower rollers sandwiching the recording paper 2 and feeding them in a certain direction by using an operation in which the electromagnet 31 returns to the original position after the surge passes through the line to be measured 1. ing.

  Here, a series of recording operations and paper feeding operations in the recording unit 30 and the paper feeding unit 50 will be described. The diagram shown on the left side of FIG. 5 shows a state where no surge is detected. The maintenance unit 33 formed on the outer surface of the electromagnet 31 is in a state in which the paper feed trigger 52 formed on the top of the paper feed unit 50 is maintained at a predetermined height so as not to contact the claw 53. . The diagram shown in the center of FIG. 5 shows a state in which the electromagnet 31 is moved downward due to the passage of the surge and a hole is formed in the recording paper 2 to record the occurrence and magnitude of the surge. As the electromagnet 31 operates, the maintenance unit 33 also moves downward, so that the trigger 52 falls down and the claw 53 is pushed down. The figure shown on the right side of FIG. 5 shows a state in which the electromagnet 31 has returned upward after passing through the surge. As the electromagnet 31 returns, the maintenance unit 33 moves upward, so that the trigger 52 is pulled up and the claw 53 returns to the initial state. The paper feeding unit 50 rotates the roller 51 and feeds the recording paper 2 in a certain direction based on the operation of the claw 53 returning to the original position. Thereafter, the surge counter transitions to the next recording wait state. When the paper feeding operation is more reliably realized, it is possible to support the operation with a spring that does not require a power source. In addition, the operation of returning the electromagnet to the original position can be realized by using, for example, a force that the spring 34 inserted below the maintenance unit 33 returns to the original position.

  According to the present embodiment, the electromagnet 31 is operated by the output current caused by the surge generated in the measured line 1 to record the magnitude and the number of occurrences of the surge on the recording paper 2, so that the recording unit 30 is operated. Does not require an external power supply. Further, since the recording paper 2 is fed using the return operation of the electromagnet 31, an external power source for operating the paper feeding unit 50 is not required. Therefore, it is possible to provide a surge counter that can reduce the power consumed for recording the occurrence of a surge to zero or slightly. In addition, since the surge recording operation and the paper feeding operation are performed using only the operation of the electromagnet 31 as a power source, it is possible to provide a surge counter that has a very simple structure and is small and inexpensive.

[Modification 1]
Modification 1 of the surge counter according to the first embodiment will be described. This modification 1 takes into account that the surge is bipolar (damped vibration waveform). As shown in FIG. 6, the current / voltage detection unit 10, the branching unit 70, and the positive recording unit 30 a, a negative recording unit 30 b, and a paper feeding unit 50. The configuration shown in FIG. 2 further includes a branching unit 70, and the recording unit 30 is transformed into a positive recording unit 30a and a negative recording unit 30b so that recording can be performed for each polarity. It has become.

  The branching unit 70 branches the output current from the current / voltage detection unit 10 into a positive output current and a negative output current, and outputs the positive output current to the positive recording unit 30a. The output current is output to the negative recording unit 30b. When the output from the current / voltage detection unit 10 is an output voltage, the output voltage is branched into a positive output voltage and a negative output voltage, and the positive output voltage is output to the positive recording unit 30a. In addition, a function of outputting a negative output voltage to the negative recording unit 30b is provided. Specifically, this can be realized by using a diode.

  The positive recording unit 30a and the negative recording unit 30b operate in the same manner as the recording unit 30 shown in FIG. 2, and the positive polarity in which the recorded surge is separated by the branching unit 70 is positive. Recording is performed by the recording unit 30a, and negative recording is performed by the negative recording unit 30b. Specifically, the positive polarity recording unit 30a pushes down the electromagnet of the positive polarity recording unit 30a with a force proportional to the branched positive polarity, and has a conical shape attached to the tip of the electromagnet. It has a function of making a hole on the left side of the recording paper 2 using a needle and recording (see FIG. 7). On the other hand, the negative recording portion 30b uses a conical needle attached to the tip of the electromagnet, which pushes down the electromagnet of the negative recording portion 30b with a force proportional to the branched negative polarity. The recording paper 2 has a function of making a hole on the right side of the recording sheet (see FIG. 7).

  According to the first modification, the positive polarity recording unit 30a and the negative polarity recording unit 30b record the surges of each polarity separately on the left and right, so that the surge polarity can be grasped, and the surge inflow / outflow path can be determined. Judgment can be made more reliably.

[Modification 2]
Modification 2 of the surge counter according to the first embodiment will be described. As shown in FIG. 8, the second modified example includes a current / voltage detection unit 10, a recording unit 30, a date / time recording unit 90, and a paper feeding unit 50. The configuration shown in FIG. 2 further includes a date / time recording unit 90.

  At the same time as the date and time recording unit 90, the recording unit 30 pushes down the electromagnet downward with a force proportional to the magnitude of the output current or output voltage and opens a hole in the recording paper 2 using a conical needle. Based on a trigger from the recording unit 30, a function of recording the date and time when the surge occurred in the recording sheet 2 in association with the hole of the recording sheet 2 is provided (see FIG. 9). In addition, if this trigger is implement | achieved mechanically, it can also be considered as a trigger by detecting that the electromagnet of the recording part 30 act | operated. Moreover, if it implement | achieves electrically, it can consider making the trigger by detecting the electric current or voltage which generate | occur | produces in the electromagnet of the recording part 30. FIG.

  According to the second modification, a slight amount of power is required for the clock operation and recording operation of the date / time recording unit 90, but the date / time recording unit 90 records the surge occurrence date / time in association with the hole in the recording paper 2. It becomes possible to specify the date and time of occurrence of the surge. Further, even when recording is performed using a plurality of surge counters, it is possible to easily associate each data of each surge counter based on the occurrence date and time.

[Modification 3]
Modification 3 of the surge counter according to the first embodiment will be described. This modified example 3 realizes the modified example 1 and the modified example 2 at the same time. The current / voltage detecting unit 10, the branching unit 70, the positive recording unit 30a, the negative recording unit 30b, The configuration includes a date and time recording unit 90 and a paper feeding unit 50. The configuration shown in FIG. 2 further includes a branching unit 70 and a date and time recording unit 90, and the recording unit 30 can be transformed into a positive recording unit 30a and a negative recording unit 30b and recorded for each polarity. The configuration is modified to.

  The branching unit 70 branches the output current from the current / voltage detection unit 10 into a positive output current and a negative output current, and outputs the positive output current to the positive recording unit 30a. The output current is output to the negative recording unit 30b. When the output from the current / voltage detection unit 10 is an output voltage, the output voltage is branched into a positive output voltage and a negative output voltage, and the positive output voltage is output to the positive recording unit 30a. In addition, a function of outputting a negative output voltage to the negative recording unit 30b is provided. Specifically, this can be realized by using a diode.

  The positive recording unit 30a and the negative recording unit 30b operate in the same manner as the recording unit 30 shown in FIG. 2, and the positive polarity in which the recorded surge is separated by the branching unit 70 is positive. Recording is performed by the recording unit 30a, and negative recording is performed by the negative recording unit 30b. Specifically, the positive polarity recording unit 30a pushes down the electromagnet of the positive polarity recording unit 30a with a force proportional to the branched positive polarity, and has a conical shape attached to the tip of the electromagnet. A recording function is provided by making a hole on the left side of the recording paper 2 using a needle. On the other hand, the negative recording portion 30b uses a conical needle attached to the tip of the electromagnet, which pushes down the electromagnet of the negative recording portion 30b with a force proportional to the branched negative polarity. The recording paper 2 has a function of making a hole in the right side of the recording.

  The date and time recording unit 90 is configured such that the positive recording unit 30a and the negative recording unit 30b push the electromagnet downward with a force proportional to the magnitude of the output current or output voltage, and use a conical needle. The recording paper 2 is recorded by making holes on the left and right, respectively, and at the same time, the date and time when the surge occurred is associated with the left and right holes of the recording paper 2 based on triggers from the positive recording section 30a and the negative recording section 30b. It has a function to record. In addition, if this trigger is implement | achieved mechanically, it can also be considered as a trigger by detecting that each electromagnet of the positive recording part 30a and the negative recording part 30b was operated. Moreover, if it implement | achieves electrically, it can consider making the trigger by detecting the electric current or voltage which generate | occur | produces in the electromagnet of the recording part 30. FIG.

  According to the third modification example, the positive polarity recording unit 30a and the negative polarity recording unit 30b record the surges of the respective polarities separately, so that the polarity of the surge can be grasped, and the inflow / outflow path of the surge is determined. Judgment can be made more reliably. Further, although a slight power source is required for the clock operation and recording operation of the date / time recording unit 90, the date / time recording unit 90 records the occurrence date and time of the surge on the recording paper 2 in association with the left and right holes of the recording paper 2, respectively. It becomes possible to specify the date and time of occurrence of the surge. Further, even when recording is performed using a plurality of surge counters, it is possible to easily associate each data of each surge counter based on the occurrence date and time.

[Second Embodiment]
Next, a second embodiment will be described. In the second embodiment, the pressing portion 32 of the recording portion 30 is a plurality of conical needles having different lengths as shown in FIG.

  FIG. 11 is a functional block diagram showing functional blocks of a surge counter according to the second embodiment. This surge counter is configured to include a current / voltage detection unit 10, a recording unit 30, and a paper feeding unit 50.

  The current / voltage detection unit 10 has a function of detecting a surge that flows through the measured line 1 and outputting a current or voltage that is proportional to the magnitude of the detected surge. When detecting current, CT, Rogowski coil, shunt resistor, etc. can be used. When detecting voltage, voltage probe, voltage divider, etc. can be used, and it is appropriate for the measurement environment. It is possible to select. Of course, when detecting current and voltage, both a CT and a voltage probe can be used. In addition, the measured line 1 may be exemplified by a power line and a ground line included in a communication device or an information processing device, or a communication line used when the device communicates with another communication device or the like. it can. In the present embodiment, it is assumed that the output from the current / voltage detection unit 10 is an output current, and the following description will be continued. Of course, it goes without saying that the same effect can be obtained even if the output voltage is used instead of the output current.

  The recording unit 30 operates the electromagnet 31 using the output current from the current / voltage detection unit 10, presses the pressing unit 32 linked to the operation of the electromagnet 31 against the recording paper 2, and is proportional to the magnitude of the surge. A function of recording the identification display on the recording paper 2 is provided. Specifically, the electromagnet 31 is pushed downward with a force proportional to the magnitude of the output current, and a plurality of conical needles with different lengths attached to the tip of the electromagnet 31 (corresponding to the pressing portion 32). Is used to make a hole in the recording paper 2 for recording. In this case, since a force proportional to the detected surge is applied to the recording paper 2, as shown in FIG. 12, the magnitude of the generated surge current can be determined from the number of recorded holes. it can. The number of holes recorded on the recording paper 2 can be easily determined by creating a hole pattern corresponding to the output current from the current / voltage detector 10 in advance as shown in FIG. become able to.

  The paper feeding unit 50 has a function of rotating the upper and lower rollers sandwiching the recording paper 2 and feeding them in a certain direction by using an operation in which the electromagnet 31 returns to the original position after the surge passes through the line to be measured 1. ing.

  According to the present embodiment, the electromagnet 31 is operated by the output current caused by the surge generated in the measured line 1 to record the magnitude and the number of occurrences of the surge on the recording paper 2, so that the recording unit 30 is operated. Does not require an external power supply. Further, since the recording paper 2 is fed using the return operation of the electromagnet 31, an external power source for operating the paper feeding unit 50 is not required. Therefore, it is possible to provide a surge counter that can reduce the power consumed for recording the occurrence of a surge to zero or slightly. In addition, since the surge recording operation and the paper feeding operation are performed using only the operation of the electromagnet 31 as a power source, it is possible to provide a surge counter that has a very simple structure and is small and inexpensive.

[Modification 1]
Modification 1 of the surge counter according to the second embodiment will be described. This modification 1 takes into account that the surge is bipolar (damped vibration waveform). As shown in FIG. 14, the current / voltage detection unit 10, the branching unit 70, and the positive recording unit 30 a, a negative recording unit 30 b, and a paper feeding unit 50. The configuration shown in FIG. 11 is further provided with a branching unit 70, and the recording unit 30 is transformed into a positive recording unit 30a and a negative recording unit 30b so that recording can be performed for each polarity. It has become.

  The branching unit 70 branches the output current from the current / voltage detection unit 10 into a positive output current and a negative output current, and outputs the positive output current to the positive recording unit 30a. The output current is output to the negative recording unit 30b. When the output from the current / voltage detection unit 10 is an output voltage, the output voltage is branched into a positive output voltage and a negative output voltage, and the positive output voltage is output to the positive recording unit 30a. In addition, a function of outputting a negative output voltage to the negative recording unit 30b is provided. Specifically, this can be realized by using a diode.

  The positive recording unit 30a and the negative recording unit 30b operate in the same manner as the recording unit 30 shown in FIG. 11, and the positive type in which the recorded surge is separated by the branching unit 70 is positive. Recording is performed by the recording unit 30a, and negative recording is performed by the negative recording unit 30b. Specifically, the positive polarity recording unit 30a pushes down the electromagnet of the positive polarity recording unit 30a with a force proportional to the branched positive polarity, and has a length attached to the tip of the electromagnet. The recording paper 2 is provided with a function of making a hole on the left side of the recording paper 2 using a plurality of different conical needles (see FIG. 15). On the other hand, the negative recording portion 30b pushes down the electromagnet of the negative recording portion 30b with a force proportional to the branched negative polarity, and a plurality of different lengths attached to the tip of the electromagnet. The recording paper 2 is provided with a function of making a hole on the right side of the recording paper 2 using a conical needle (see FIG. 15).

  According to the first modification, the positive polarity recording unit 30a and the negative polarity recording unit 30b record the surges of each polarity separately on the left and right, so that the surge polarity can be grasped, and the surge inflow / outflow path can be determined. Judgment can be made more reliably.

[Modification 2]
Modification 2 of the surge counter according to the second embodiment will be described. As illustrated in FIG. 16, the second modification includes a current / voltage detection unit 10, a recording unit 30, a date / time recording unit 90, and a paper feeding unit 50. The configuration shown in FIG. 11 further includes a date and time recording unit 90.

  The date and time recording unit 90 presses the electromagnet downward with a force proportional to the magnitude of the output current or output voltage, and uses a plurality of conical needles with different lengths to make holes in the recording paper 2. At the same time as opening and recording, it has a function of recording the date and time when the surge occurred in association with the hole of the recording paper 2 based on the trigger from the recording unit 30 (see FIG. 17). In addition, if this trigger is implement | achieved mechanically, it can also be considered as a trigger by detecting that the electromagnet of the recording part 30 act | operated. Moreover, if it implement | achieves electrically, it can consider making the trigger by detecting the electric current or voltage which generate | occur | produces in the electromagnet of the recording part 30. FIG.

  According to the second modification, a slight power source is required for the clock operation and the recording operation of the date / time recording unit 90, but the date / time recording unit 90 associates the surge occurrence date / time with the hole of the recording sheet 2 to Since it is recorded, it becomes possible to specify the date and time of occurrence of the surge. Further, even when recording is performed using a plurality of surge counters, it is possible to easily associate each data of each surge counter based on the occurrence date and time.

[Modification 3]
A modification 3 of the surge counter according to the second embodiment will be described. This modified example 3 realizes the modified example 1 and the modified example 2 at the same time. The current / voltage detecting unit 10, the branching unit 70, the positive recording unit 30a, the negative recording unit 30b, The configuration includes a date and time recording unit 90 and a paper feeding unit 50. 11. The configuration shown in FIG. 11 further includes a branching unit 70 and a date / time recording unit 90. The recording unit 30 can be transformed into a positive recording unit 30a and a negative recording unit 30b and can be recorded for each polarity. The configuration is modified to.

  The branching unit 70 branches the output current from the current / voltage detection unit 10 into a positive output current and a negative output current, and outputs the positive output current to the positive recording unit 30a. The output current is output to the negative recording unit 30b. When the output from the current / voltage detection unit 10 is an output voltage, the output voltage is branched into a positive output voltage and a negative output voltage, and the positive output voltage is output to the positive recording unit 30a. In addition, a function of outputting a negative output voltage to the negative recording unit 30b is provided. Specifically, this can be realized by using a diode.

  The positive recording unit 30a and the negative recording unit 30b operate in the same manner as the recording unit 30 shown in FIG. 11, and the positive type in which the recorded surge is separated by the branching unit 70 is positive. Recording is performed by the recording unit 30a, and negative recording is performed by the negative recording unit 30b. Specifically, the positive polarity recording unit 30a pushes down the electromagnet of the positive polarity recording unit 30a with a force proportional to the branched positive polarity, and has a length attached to the tip of the electromagnet. The recording paper 2 is provided with a function of making a hole on the left side using a plurality of different conical needles. On the other hand, the negative recording portion 30b pushes down the electromagnet of the negative recording portion 30b with a force proportional to the branched negative polarity, and a plurality of different lengths attached to the tip of the electromagnet. The recording paper 2 is provided with a function of making a hole on the right side of the recording paper 2 using a conical needle.

  The date and time recording unit 90 includes a plurality of conical needles having different lengths by positively pressing the electromagnet downward with a force proportional to the magnitude of the output current or output voltage. The recording paper 2 is used to make holes on the left and right sides for recording, and at the same time, based on the triggers from the positive recording section 30a and the negative recording section 30b, the date and time when the surge occurred is recorded in the left and right holes of the recording paper 2, respectively. A function of recording on the recording paper 2 in association with each other is provided. In addition, if this trigger is implement | achieved mechanically, it can also be considered as a trigger by detecting that each electromagnet of the positive recording part 30a and the negative recording part 30b was operated. Moreover, if it implement | achieves electrically, it can consider making the trigger by detecting the electric current or voltage which generate | occur | produces in the electromagnet of the recording part 30. FIG.

  According to the third modification example, the positive polarity recording unit 30a and the negative polarity recording unit 30b record the surges of the respective polarities separately, so that the polarity of the surge can be grasped, and the inflow / outflow path of the surge is determined. Judgment can be made more reliably. Further, although a slight power source is required for the clock operation and recording operation of the date / time recording unit 90, the date / time recording unit 90 records the occurrence date and time of the surge on the recording paper 2 in association with the left and right holes of the recording paper 2, respectively. It becomes possible to specify the date and time of occurrence of the surge. Further, even when recording is performed using a plurality of surge counters, it is possible to easily associate each data of each surge counter based on the occurrence date and time.

[Third Embodiment]
FIG. 18 is a configuration diagram showing the overall configuration of the surge counter according to the third embodiment. A surge current / voltage pickup sensor 10 is installed close to the conductor 1 to be detected, which is a surge intrusion path, and is output from the surge current / voltage pickup sensor 10 when a surge generated in the conductor 1 to be detected is detected. By operating the electromagnet 31 using the output current or the output voltage, pressure is applied to the pressure measurement film 3 with a pressure proportional to the magnitude of the surge. Further, by operating the paper feeding unit 50 using the return operation of the electromagnet 31, a plurality of surges can be recorded on the recording paper 2. Since the pressure measurement film 3 can display the color with different shades depending on the pressure applied, the magnitude and number of occurrences of the surge are determined based on the degree and the number of shades recorded on the recording paper 2. It becomes possible. Hereinafter, the configuration and function of the surge counter according to the present embodiment will be specifically described.

  FIG. 19 is a functional block diagram showing functional blocks of a surge counter according to the third embodiment. This surge counter is configured to include a current / voltage detection unit 10, a recording unit 30, and a paper feeding unit 50.

  The current / voltage detection unit 10 has a function of detecting a surge that flows through the measured line 1 and outputting a current or voltage that is proportional to the magnitude of the detected surge. When detecting current, CT, Rogowski coil, shunt resistor, etc. can be used. When detecting voltage, voltage probe, voltage divider, etc. can be used, and it is appropriate for the measurement environment. It is possible to select. Of course, when detecting current and voltage, both a CT and a voltage probe can be used. In addition, the measured line 1 may be exemplified by a power line and a ground line included in a communication device or an information processing device, or a communication line used when the device communicates with another communication device or the like. it can. In the present embodiment, it is assumed that the output from the current / voltage detection unit 10 is an output current, and the following description will be continued. Of course, it goes without saying that the same effect can be obtained even if the output voltage is used instead of the output current.

  The recording unit 30 operates the electromagnet 31 using the output current from the current / voltage detection unit 10, presses the pressing unit 32 ′ linked to the operation of the electromagnet 31 against the recording paper 2, and is proportional to the magnitude of the surge. A function of recording the identification display on the pressure measurement film 3 is provided. Specifically, the electromagnet 31 is pushed downward with a force proportional to the magnitude of the output current, and the pressure applied to the recording paper 2 by using the truncated cone-shaped pressing portion 32 ′ attached to the tip of the electromagnet 31. To record. In this case, since a pressure proportional to the detected surge is applied to the recording paper 2, as shown in FIG. 20, the magnitude of the surge current generated from the recorded gray level can be determined. . As shown in FIG. 21, the gray level recorded on the recording paper 2 can be easily determined by creating a gray level corresponding to the output current from the current / voltage detector 10 in advance. become.

  The paper feeding unit 50 has a function of rotating the upper and lower rollers sandwiching the recording paper 2 and feeding them in a certain direction by using an operation in which the electromagnet 31 returns to the original position after the surge passes through the line to be measured 1. ing.

  Here, a series of recording operations and paper feeding operations in the recording unit 30 and the paper feeding unit 50 will be described. The diagram shown on the left side of FIG. 22 shows a state where no surge is detected. The maintenance unit 33 formed on the outer surface of the electromagnet 31 is in a state in which the paper feed trigger 52 formed on the top of the paper feed unit 50 is maintained at a predetermined height so as not to contact the claw 53. . The diagram shown in the center of FIG. 22 shows a state where the electromagnet 31 is moved downward by the passage of the surge and the pressure and pressure are applied to the recording paper 2 to record the occurrence and magnitude of the surge. As the electromagnet 31 operates, the maintenance unit 33 also moves downward, so that the trigger 52 falls down and the claw 53 is pushed down. The figure shown on the right side of FIG. 22 shows a state in which the electromagnet 31 has returned upward after passing through the surge. As the electromagnet 31 returns, the maintenance unit 33 moves upward, so that the trigger 52 is pulled up and the claw 53 returns to the initial state. The paper feeding unit 50 rotates the roller 51 and feeds the recording paper 2 in a certain direction based on the operation of the claw 53 returning to the original position. Thereafter, the surge counter transitions to the next recording wait state. When the paper feeding operation is more reliably realized, it is possible to support the operation with a spring that does not require a power source. In addition, the operation of returning the electromagnet to the original position can be realized by using, for example, a force that the spring 34 inserted below the maintenance unit 33 returns to the original position.

  According to the present embodiment, the electromagnet 31 is operated by the output current caused by the surge generated in the measured line 1 to record the magnitude and the number of occurrences of the surge on the recording paper 2, so that the recording unit 30 is operated. Does not require an external power supply. Further, since the recording paper 2 is fed using the return operation of the electromagnet 31, an external power source for operating the paper feeding unit 50 is not required. Therefore, it is possible to provide a surge counter that can reduce the power consumed for recording the occurrence of a surge to zero or slightly. In addition, since the surge recording operation and the paper feeding operation are performed using only the operation of the electromagnet 31 as a power source, it is possible to provide a surge counter that has a very simple structure and is small and inexpensive.

[Modification 1]
Modification 1 of the surge counter according to the third embodiment will be described. This modification 1 takes into account that the surge is bipolar (damped vibration waveform). As shown in FIG. 23, the current / voltage detection unit 10, the branching unit 70, the positive recording unit, and the like. 30 a, a negative recording unit 30 b, and a paper feeding unit 50. The configuration shown in FIG. 19 further includes a branching unit 70, and the recording unit 30 is transformed into a positive recording unit 30a and a negative recording unit 30b so that recording can be performed for each polarity. It has become.

  The branching unit 70 branches the output current from the current / voltage detection unit 10 into a positive output current and a negative output current, and outputs the positive output current to the positive recording unit 30a. The output current is output to the negative recording unit 30b. When the output from the current / voltage detection unit 10 is an output voltage, the output voltage is branched into a positive output voltage and a negative output voltage, and the positive output voltage is output to the positive recording unit 30a. In addition, a function of outputting a negative output voltage to the negative recording unit 30b is provided. Specifically, this can be realized by using a diode.

  The positive recording unit 30a and the negative recording unit 30b operate in the same manner as the recording unit 30 shown in FIG. 19, and the positive polarity in which the recorded surge is separated by the branching unit 70 is positive. Recording is performed by the recording unit 30a, and negative recording is performed by the negative recording unit 30b. Specifically, the positive polarity recording part 30a pushes down the electromagnet of the positive polarity recording part 30a with a force proportional to the magnitude of the branched positive polarity, and has a truncated cone shape attached to the tip of the electromagnet. The recording unit 2 has a function of applying a pressing pressure to the left side of the recording paper 2 using the pressing portion 32 '(see FIG. 24). On the other hand, the negative recording portion 30b pushes the electromagnet of the negative recording portion 30b downward with a force proportional to the branched negative polarity, and the truncated cone-shaped pressing portion attached to the tip of the electromagnet 32 'is used to apply a pressing pressure to the right side of the recording paper 2 for recording (see FIG. 24).

  According to the first modification, the positive polarity recording unit 30a and the negative polarity recording unit 30b record the surges of each polarity separately on the left and right, so that the surge polarity can be grasped, and the surge inflow / outflow path can be determined. Judgment can be made more reliably.

[Modification 2]
A modification 2 of the surge counter according to the third embodiment will be described. As shown in FIG. 25, the second modified example includes a current / voltage detection unit 10, a recording unit 30, a date / time recording unit 90, and a paper feeding unit 50. The configuration shown in FIG. 19 further includes a date and time recording unit 90.

  The date and time recording unit 90 presses the electromagnet downward with a force proportional to the magnitude of the output current or output voltage and applies pressure to the recording paper 2 using the truncated cone-shaped pressing unit 32 '. And a function of recording the date and time when the surge occurred in association with the density of the recording paper 2 based on a trigger from the recording unit 30 (see FIG. 26). In addition, if this trigger is implement | achieved mechanically, it can also be considered as a trigger by detecting that the electromagnet of the recording part 30 act | operated. Moreover, if it implement | achieves electrically, it can consider making the trigger by detecting the electric current or voltage which generate | occur | produces in the electromagnet of the recording part 30. FIG.

  According to the second modification, a slight power source is required for the clock operation and the recording operation of the date / time recording unit 90. However, the date / time recording unit 90 associates the surge occurrence date / time with the shading of the recording paper 2 to the recording paper 2 Since it is recorded, it becomes possible to specify the date and time of occurrence of the surge. Further, even when recording is performed using a plurality of surge counters, it is possible to easily associate each data of each surge counter based on the occurrence date and time.

[Modification 3]
Modification 3 of the surge counter according to the third embodiment will be described. This modified example 3 realizes the modified example 1 and the modified example 2 at the same time. The current / voltage detecting unit 10, the branching unit 70, the positive recording unit 30a, the negative recording unit 30b, The configuration includes a date and time recording unit 90 and a paper feeding unit 50. The configuration shown in FIG. 19 further includes a branching unit 70 and a date and time recording unit 90, and the recording unit 30 can be transformed into a positive recording unit 30a and a negative recording unit 30b and can be recorded for each polarity. The configuration is modified to.

  The branching unit 70 branches the output current from the current / voltage detection unit 10 into a positive output current and a negative output current, and outputs the positive output current to the positive recording unit 30a. The output current is output to the negative recording unit 30b. When the output from the current / voltage detection unit 10 is an output voltage, the output voltage is branched into a positive output voltage and a negative output voltage, and the positive output voltage is output to the positive recording unit 30a. In addition, a function of outputting a negative output voltage to the negative recording unit 30b is provided. Specifically, this can be realized by using a diode.

  The positive recording unit 30a and the negative recording unit 30b operate in the same manner as the recording unit 30 shown in FIG. 19, and the positive polarity in which the recorded surge is separated by the branching unit 70 is positive. Recording is performed by the recording unit 30a, and negative recording is performed by the negative recording unit 30b. Specifically, the positive polarity recording part 30a pushes down the electromagnet of the positive polarity recording part 30a with a force proportional to the magnitude of the branched positive polarity, and has a truncated cone shape attached to the tip of the electromagnet. The recording unit 2 has a function of applying a pressing pressure to the left side of the recording paper 2 using the pressing portion 32 '. On the other hand, the negative recording portion 30b pushes the electromagnet of the negative recording portion 30b downward with a force proportional to the branched negative polarity, and the truncated cone-shaped pressing portion attached to the tip of the electromagnet 32 'is used to apply a pressing pressure to the right side of the recording paper 2 for recording.

  The date and time recording unit 90 uses the pressing unit 32 'to push the electromagnet downward with a force proportional to the magnitude of the output current or output voltage of the positive recording unit 30a and the negative recording unit 30b. Recording is performed by applying pressure to the left and right, respectively, and at the same time, the date and time when the surge occurs is associated with the left and right shades of the recording paper 2 based on triggers from the positive recording unit 30a and the negative recording unit 30b. 2 has a recording function. In addition, if this trigger is implement | achieved mechanically, it can also be considered as a trigger by detecting that each electromagnet of the positive recording part 30a and the negative recording part 30b was operated. Moreover, if it implement | achieves electrically, it can consider making the trigger by detecting the electric current or voltage which generate | occur | produces in the electromagnet of the recording part 30. FIG.

  According to the third modification example, the positive polarity recording unit 30a and the negative polarity recording unit 30b record the surges of the respective polarities separately, so that the polarity of the surge can be grasped, and the inflow / outflow path of the surge is determined. Judgment can be made more reliably. Further, although a slight power source is required for the clock operation and recording operation of the date / time recording unit 90, the date / time recording unit 90 records the date and time of occurrence of the surge on the recording paper 2 in association with the left and right shades of the recording paper 2, respectively. It becomes possible to specify the date and time of occurrence of the surge. Further, even when recording is performed using a plurality of surge counters, it is possible to easily associate each data of each surge counter based on the occurrence date and time.

  Finally, according to the present invention, a surge counter that does not require a power source or operates with a weak current can be configured at low cost, so that each of communication devices and information processing devices can be used in places where it is difficult to secure a commercial power source or a large capacity battery. A plurality of interface wires can be installed, and the surge current and / or surge voltage that enters can be easily measured, so that data for surge protection can be easily collected.

  Further, since the structure is simple, it is possible to easily reduce the size and weight. That is, the degree of freedom of measurement is greatly increased, such as enabling direct installation to a cable that could not be installed so far.

  Furthermore, since the recording length can be freely changed by changing the length of the recording paper, it is easy to match the measurement period, and since no power source is required, the maintenance cost can be greatly reduced. Further, since connection of the power supply line is not required, it is easy to ensure insulation, and unnecessary wraparound of surges can be easily prevented.

It is a lineblock diagram showing the whole surge counter composition concerning a 1st embodiment. It is a functional block diagram which shows the functional block of the surge counter which concerns on 1st Embodiment. It is a figure which shows the example of recording on a recording paper. It is a figure which shows the pattern of the hole corresponding to an output current. FIG. 5 is a diagram illustrating a series of operations of a recording unit and a paper feeding unit. It is a functional block diagram which shows the functional block of the modification 1 of the surge counter which concerns on 1st Embodiment. It is a figure which shows the example of recording on a recording paper. It is a functional block diagram which shows the functional block of the modification 2 of the surge counter which concerns on 1st Embodiment. It is a figure which shows the example of recording on a recording paper. It is a structural diagram which shows the structure of the press part of the recording part which concerns on 2nd Embodiment. It is a functional block diagram which shows the functional block of the surge counter which concerns on 2nd Embodiment. It is a figure which shows the example of recording on a recording paper. It is a figure which shows the pattern of the hole corresponding to an output current. It is a functional block diagram which shows the functional block of the modification 1 of the surge counter which concerns on 2nd Embodiment. It is a figure which shows the example of recording on a recording paper. It is a functional block diagram which shows the functional block of the modification 2 of the surge counter which concerns on 2nd Embodiment. It is a figure which shows the example of recording on a recording paper. It is a block diagram which shows the whole structure of the surge counter which concerns on 3rd Embodiment. It is a functional block diagram which shows the functional block of the surge counter which concerns on 3rd Embodiment. It is a figure which shows the example of recording on a recording paper. It is a figure which shows the density | concentration level corresponding to an output current. It is a figure which shows a series of operation | movement of a recording part and a paper feeding part. It is a functional block diagram which shows the functional block of the modification 1 of the surge counter which concerns on 3rd Embodiment. It is a figure which shows the example of recording on a recording paper. It is a functional block diagram which shows the functional block of the modification 2 of the surge counter which concerns on 3rd Embodiment. It is a figure which shows the example of recording on a recording paper. It is a figure which shows the conventional waveform recording method. It is a figure which shows the conventional surge counter.

Explanation of symbols

10 ... Current / voltage detector (Surge current / voltage pickup sensor)
DESCRIPTION OF SYMBOLS 30 ... Recording part 30a ... Positive polarity recording part 30b ... Negative polarity recording part 31 ... Electromagnet 32 ... Pressing part 33 ... Maintenance part 34 ... Spring 50 ... Paper feeding part 51 ... Roller 52 ... Trigger 53 ... Claw 70 ... Branching part 90 ... Date and time recording unit 100 ... device 103 ... sensor 105 ... oscilloscope 107 ... control / recording device 109 ... commercial power supply 111 ... insulation transformer 113 ... surge counter 115 ... high capacity battery

Claims (6)

Detecting means for detecting a surge generated in the conductor to be detected and outputting a current or voltage proportional to the magnitude of the surge;
Recording means for operating an electromagnet using the output current or output voltage, pressing a pressing portion linked to the operation against a recording medium, and recording an identification display proportional to the magnitude of the surge;
Recording medium feeding means for feeding the recording medium in a certain direction by using an operation in which the electromagnet returns to the original position after the surge has passed through the detected conductor;
A surge counter characterized by comprising: Further comprising branch means for branching the output current or the output voltage into a positive output and a negative output;
The recording means includes a positive recording means for recording the identification display using the positive output and a negative recording means for recording the identification display using the negative output. The surge counter according to claim 1, wherein:   The surge counter according to claim 1 or 2, further comprising a date and time recording means for recording a surge occurrence date and time on the recording medium in association with the identification display. The recording medium is recording paper, and the pressing portion is a conical needle attached to the tip of the electromagnet,
4. The recording device according to claim 1, wherein the recording unit presses the conical needle against the recording paper to open a hole having a size proportional to the size of the surge. 5. Surge counter. The recording medium is recording paper, and the pressing portion is a plurality of needles attached to the tip of the electromagnet,
The surge counter according to any one of claims 1 to 3, wherein the recording means presses the plurality of needles against the recording paper to open a number of holes proportional to the magnitude of the surge. . The recording medium is a pressure measuring film capable of changing the density display according to the pressure applied,
4. The surge counter according to claim 1, wherein the recording unit presses the pressing portion against the pressure measurement film and displays a light and shade proportional to the magnitude of the surge. 5.