JP2012138305A - Discharge frequency meter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a discharge frequency meter capable of easily changing operation sensitivity of the discharge frequency meter, protecting an ammeter with sure, and stabilizing display of the ammeter even in the case where the current that flows at always contains a high frequency component.SOLUTION: In the discharge frequency meter, one end of a first zinc oxide element r1 is connected to an arrester AR. An input end of a rectifier ReC is connected to one end and the other end of the first zinc oxide element. A first capacitor C1 is charged with an output voltage of the rectifier. A count up coil T is driven by the electric charge of discharge of the first capacitor. A protection circuit is connected to the other end of the first zinc oxide element. The ammeter Am is connected to the protection circuit. A variable resistor R1 is connected parallel to the first zinc oxide element.

Description

  Embodiments of the present invention relate to a discharge power meter that counts the number of discharges of a power arrester, for example.

  For example, in a high voltage power facility that constructs a power system such as a transmission line, a substation, a switching station, or a power plant, a power arrester is installed to protect the facility itself from lightning strikes. The lightning arrester is provided with a discharge power meter for counting the number of discharges.

  Since various currents flow through the arrester, for example, the operation sensitivity of the discharge frequency meter is adjusted so as not to count discharges other than lightning strikes. Conventionally, this adjustment is performed at the time of installation, and there has been no change in specifications after installation or unexpected change in required performance. In other words, since the discharge frequency meter is mainly installed on the grounding line of the power arrester, the resistance value of the sensitivity adjustment resistor can be uniquely determined and applied in advance based on the specifications from the supplier. It was mainstream. This was also an essential essence for the design of high-current / high-voltage devices that tend to avoid the provision of devices that cause failure, such as contacts for switching resistance values.

  In addition, when the electric discharge meter is installed outdoors, it is completely sealed and is covered with an instrument panel even when installed in an indoor instrument panel in order to improve environmental resistance. For this reason, after installation, it may be difficult to adjust the sensitivity of the discharge meter for structural reasons.

  In recent years, with the update of peripheral devices and the change in circuit configuration, there is an increasing demand for adjusting the operation sensitivity of the discharge meter. However, since the discharge meter is completely sealed or installed in the instrument panel, it is difficult to easily adjust the sensitivity after installation.

  Further, the discharge meter is provided with an ammeter, and this ammeter can display a leakage current. That is, since the discharge power meter is connected between the ground terminal of the lightning arrester and the ground, a leakage current flowing through the lightning arrester always flows through the discharge power meter. This leakage current is displayed on the ammeter. This ammeter is protected from current during lightning strikes by a large capacity gap. However, since the lightning strike current is often a large current, a large load is placed on the large-capacity gap, and there is a problem of lack of reliability from the viewpoint of preventing the ammeter from being destroyed.

  Furthermore, as described above, a current always flows in the discharge meter, and although it is extremely rare, a high-frequency component may be included in the current. Due to this high frequency component, there is a problem that the display of the ammeter is not stable.

JP 2003-217787 A

  Therefore, it is possible to easily change the operation sensitivity of the discharge meter, to protect the ammeter reliably, and to stabilize the display of the ammeter even when high-frequency components are included in the constantly flowing current Is to provide.

  According to the discharge power meter of the embodiment, the first zinc oxide element having one end connected to the lightning arrester, the rectifier connected in parallel to the first zinc oxide element, and the first charged by the output voltage of the rectifier. 1 capacitor, a count-up coil driven by a discharge charge of the first capacitor, a protection circuit connected to the other end of the first zinc oxide element, and an ammeter connected to the protection circuit; And a variable resistor connected in parallel to the first zinc oxide element and adjusting the operation sensitivity of the ammeter.

The circuit shown in order to explain the principle of operation of a discharge meter. A circuit showing an example of a discharge meter with a leak current meter. The circuit which shows the electric discharge meter which concerns on 1st Embodiment. The figure which shows the characteristic of a ZnO element. The circuit which shows the discharge dynamometer which concerns on 2nd Embodiment. The circuit which shows the discharge frequency meter which concerns on 3rd Embodiment.

  Hereinafter, embodiments will be described with reference to the drawings.

  First, the principle of operation of the discharge frequency meter will be described with reference to FIG.

  As shown in FIG. 1, the basic circuit of the discharge meter includes a zinc oxide element (hereinafter referred to as ZnO element) r1, a capacitor C1, and a count-up coil T. One end a of the ZnO element r1 is connected to the lightning arrester AR, and the other end b is grounded. A capacitor C1 and a count-up coil T are connected in parallel to the ZnO element r1.

  In the basic circuit configured as described above, when a lightning strike current (for example, an impulse current having a wave tail length of several microseconds to several tens of microseconds) flows in the ZnO element r1, the characteristic between the ZnO elements r1 causes the ab terminals to be connected. Produces a voltage. This voltage charges the capacitor C1. When the electric charge charged in the capacitor is discharged, the count-up coil T is driven, and the number of discharges is counted by a counter (not shown). When the count-up coil T is driven once, the number of lightning strokes “1” is displayed on the discharge frequency meter.

  At this time, the operation sensitivity of the discharge frequency meter, in which the boundary points between the operation and the non-operation of the discharge frequency meter with the wave tail length of the impulse current as the horizontal axis and the magnitude of the impulse current as the vertical axis, is called the operation sensitivity of the discharge frequency meter.

  Further, not only the lightning strike current but also a switching surge current, a high frequency alternating current, a commercial frequency alternating current or a direct current flows through the ZnO element r1. For this reason, the discharge frequency meter is operated by these currents. The switching surge current is a current generated by the switching operation of a power switch to protect other power devices from lightning strikes or failure of power devices connected to high voltage lines, for example, several hundred microseconds to several millimeters. It is an impulse current having a wave tail length of seconds.

  Lightning strike current and switching surge current are often defined as impulse currents having a relatively short wave tail length compared to alternating currents, and this is called discharge meter operation sensitivity in the impulse region. On the other hand, the high frequency alternating current, the commercial frequency alternating current, and the direct current have a wave tail length that is relatively longer than the impulse current and is in the region from several tens of milliseconds to direct current. This is called motion sensitivity.

  On the other hand, FIG. 2 shows a general circuit of a type of discharge meter that can display the current constantly flowing through the discharge meter with an ammeter. This is called a discharge dynamometer with a leakage current meter, and usually has a feature that can display the leakage current of a lightning arrester and can display the number of lightning strike currents when a lightning strike occurs.

  This discharge ampere meter with a leakage current meter is composed of a ZnO element r1, a rectifier ReC, a capacitor C1, a count-up coil T, a resistance R2 for protecting the ammeter and cutting high frequency, and a large capacity. A gap Ga, an ammeter protecting resistor R3, an ammeter Am, and an ammeter protecting Zener diode ZD are provided.

  One end a of the ZnO element r1 is connected to a lightning arrester (not shown). For example, the input terminal of a full-wave rectifier ReC is connected between terminals a and b of the ZnO element r1. A capacitor C1 and a count-up coil T are connected to the output terminal of the rectifier ReC. For this reason, the count-up coil T can be reliably driven with respect to the vibrating lightning strike current. Between the terminal b and the ground terminal c of the ZnO element r1, a resistance R2 for ammeter protection and high frequency cut and a zener diode ZD for ammeter protection are connected in series, and a connection node between the resistor R2 and the zener diode ZD and the terminal c The ammeter protection resistor R3 and the ammeter Am are connected in series. Further, a large capacity gap Ga is connected between the terminals bc.

  In the above configuration, the current that always flows through the lightning arrester flows along the route of r1 → R2 → R3 → Am, and the current value is displayed by the ammeter Am. At this time, the capacitor C1 is charged by the voltage generated between the terminals a and b by the current constantly flowing through the ZnO element r1, and the count-up coil T is driven by the discharge of the charge. Further, the current flowing into the ammeter Am through the path of R2 → R3 → Am is shunted by the resistor R2 and the Zener diode ZD, and the ammeter Am is protected from being broken by the overflow current.

  On the other hand, the lightning strike current and the switching surge current flow along a route r1 → Ga. At this time, a voltage is generated between the ZnO element r1 terminals a and b, and the capacitor C1 is charged by this voltage. Due to the discharge of the electric charge, the count-up coil T is driven and the number of discharges is counted. The lightning strike current and the switching surge current flowing into the ammeter Am through the path of r1 → R2 → R3 → Am during a lightning strike or switching surge are limited by the resistor R2 and the Zener diode ZD, and the ammeter Am is protected. In other words, since most of the lightning strike current and switching surge current flow through the large capacity gap Ga, it is important that the Ga has a large capacity gap.

(First embodiment)
FIG. 3 shows the first embodiment. 3, the same parts as those in FIGS. 1 and 2 are denoted by the same reference numerals, and the description thereof is omitted.

  In the first embodiment, the configuration of the present embodiment is added to the discharge meter with a leak current meter shown in FIG. Specifically, a variable resistor R1 for adjusting the sensitivity of the discharge dynamometer is connected between terminals a and b of a ZnO element (first ZnO element) r1. That is, the variable resistor R1 is connected in parallel to the ZnO element r1. The variable resistor R1 is configured such that the sensitivity of the discharge frequency meter can be selected from, for example, three levels of high-medium-low.

  As shown in FIG. 3, the variable resistor R <b> 1 is provided with, for example, a plurality of tap electrodes 12 in the resistor 11, and a movable contact 13 of the switch can be in contact with the tap electrodes 12. The movable contact 13 is provided with an operation element 14, and by operating the operation element 14, the movable contact piece 13 is driven to change the resistance value. The change of the resistance value adjusts the sensitivity of the discharge frequency meter. The configuration of the variable resistor R1 is not limited to this, and can be modified.

  When the discharge meter is, for example, a completely sealed type, the movable contact 13 of the switch and its operation element 14 are covered with an elastic member, for example, a rubber cover, and can be operated via this cover.

  In addition, when the discharge frequency meter is installed in, for example, an instrument panel, the switch operator is arranged so as to be operable from the instrument panel.

  Furthermore, in the first embodiment, a ZnO element (second ZnO element) r2 is connected between the terminals bc instead of the large-capacity gap Ga shown in FIG. The ZnO element r2 has different characteristics from the ZnO element r1.

FIG. 4 shows an example of the characteristics of the ZnO elements r1 and r2. As shown in FIG. 4, for example, the operation start voltage (r2V ₂ mV) of the ZnO element r2 is set smaller than the operation start voltage (r1V ₁ mV) of the ZnO element r1 (r1V ₁ mV >> r2V _2). mV).

  Further, the first embodiment includes an ammeter protection diode D and a high frequency cut capacitor C2 instead of the Zener diode ZD shown in FIG. The diode D is connected to the resistor R3 and the ammeter Am so that the polarities of a plurality of diodes are reversed, and effectively protects the ammeter Am against forward and reverse currents flowing through the ammeter Am. .

  The high frequency cut capacitor C2 is connected between the resistor R2 and the terminal c, and bypasses the high frequency component flowing through the ammeter Am.

  In the above configuration, the leakage current that always flows through the lightning arrester AR flows to the ammeter Am through a route of R1 → R2 → R3 → Am, and the current value is displayed by the ammeter Am. At this time, the capacitor C1 is charged with the voltage generated between the terminals a and b by the current that constantly flows through the ZnO element r1, and the count-up coil T is driven by the discharge of the charge, and the counter performs the counting operation. There is. For this reason, by adjusting the variable resistor R1 and adjusting the sensitivity of the discharge dynamometer, it is possible to prevent counting of the leakage current that always flows through the lightning arrester AR.

  Further, the current flowing into the ammeter Am through the path of R2 → R3 → Am is controlled by the resistor R2 and the diode D, and the ammeter Am is protected from being destroyed by the overflow current.

  Further, due to the ZnO element r2, the current flowing through the path R1 → R2 also flows through the path R1 → r2. For this reason, the ZnO element r2 can prevent the ammeter Am from being destroyed by an excessive current, and can reliably protect the ammeter Am.

  Further, a high-frequency component current that makes the display of the ammeter Am unstable flows through a path of R1 → R2 → C2. For this reason, it is possible to stabilize the display of the ammeter Am.

  On the other hand, the lightning strike current and the switching surge current flow along a route r1 → r2. At this time, a voltage is generated between the terminals a and b, and the capacitor C1 is charged with this voltage. When the electric charge charged in the capacitor C1 is discharged, the count-up coil T is driven, and the discharge frequency is counted.

  According to the first embodiment, the variable resistor R1 is connected in parallel to the ZnO element r1, and the voltage generated between both ends of the ZnO element r1 can be adjusted. For this reason, the sensitivity of the discharge meter can be adjusted as appropriate by adjusting the variable resistor R1. Therefore, even after the discharge frequency meter is installed in the power equipment, the sensitivity can be adjusted as necessary, so that the discharge frequency can be counted stably.

  In addition, fine adjustment of the operation sensitivity in the AC (alternating current) region should carefully select R1, R2, R3, and Am, and the characteristics of the ZnO element r1 are also related. However, the ZnO element r1 is a very important component because it is also a main circuit for passing a lightning current, and it is not a good idea to change the characteristics of the ZnO element r1. Therefore, connecting the variable resistor R1 in parallel to the ZnO element r1 and switching the variable resistor R1 to enable fine adjustment of the operation sensitivity in the AC region does not require a change in the characteristics of the main circuit. Thus, it has an excellent effect that it can adjust the operation sensitivity in the AC region while maintaining the basic performance.

  Furthermore, according to the first embodiment, a large current out of the current that always flows in the ammeter Am flows in the ZnO element r2. For this reason, an excessive current that destroys the ammeter Am can be bypassed by the ZnO element r2. Therefore, the ammeter Am can be reliably protected.

  In addition, the high frequency component of the constantly flowing current flows through the resistor R2 and the capacitor C2. For this reason, the display of the ammeter Am can be stabilized.

  Further, the use of the diode D in place of the Zener diode ZD enables a low-cost configuration.

(Second Embodiment)
FIG. 5 shows a second embodiment. In the third embodiment, the same parts as those in the first embodiment are denoted by the same reference numerals, and only different parts will be described.

  In the second embodiment, a high-pass filter circuit including a high-frequency cut capacitor C3 and a resistor R4 is further added to the first embodiment to cut off the high-frequency current flowing through the ammeter. That is, one end of the resistor R4 is connected to a connection node between the resistor R2 and the capacitor C2, and the other end is connected to a connection node between the resistor R3 and the diode D. One end of the capacitor C3 is connected between the connection node of the resistor R4 and the diode D and the terminal c.

  In the above configuration, among the current that always flows through the lightning arrester AR, the current of the high frequency component that makes the display of the ammeter Am unstable flows along the route of R1 → R2 → C2, and on the route of R1 → R2 → R4 → C3. Also flows. For this reason, since it can suppress further that the electric current of a high frequency component flows into ammeter Am, it is possible to stabilize the display of ammeter Am.

  According to the second embodiment, the same effect as in the first embodiment can be obtained. Furthermore, by providing a filter circuit composed of the resistor R4 and the capacitor C3, the display of the ammeter Am with respect to the current of the high frequency component can be stabilized as compared with the first embodiment.

  In addition, an arbitrary frequency can be filtered by appropriately selecting the resistors R2 and R4 and the capacitors C2 and C3. For this reason, since the electric current containing the high frequency component which always flows into a discharge frequency meter can be suppressed exactly according to the installation place of a discharge frequency meter, the discharge frequency meter which has the ammeter Am of the very stable display is comprised. It is possible.

(Third embodiment)
FIG. 6 shows a third embodiment. In the third embodiment, the configuration shown in FIG. 2 is modified, and the same reference numerals are given to the same portions as those in FIGS.

  In FIG. 6, a variable resistor R1 for sensitivity adjustment is connected between terminals a and b of the ZnO element r1. This variable resistor R1 has the same configuration as in the first and second embodiments.

  In the above configuration, the sensitivity of the discharge meter can be adjusted by switching the resistance value of the variable resistor R1 as in the first and second embodiments.

  Further, the current that always flows through the lightning protection AR flows to the ammeter Am through the path of R1, R2, R3, and Am. For this reason, the magnitude of the current flowing into the ammeter Am can be adjusted by switching the variable resistor R1. Therefore, it is possible to change the operation sensitivity of the discharge frequency meter in the AC region. That is, according to the third embodiment, the operation sensitivity of the discharge frequency meter can be changed easily.

  In addition, this invention is not limited to the said 1st thru | or 3rd embodiment, Of course, various deformation | transformation implementation is possible in the range which does not change a summary.

  AR ... Arrester, r1, r2 ... First and second ZnO elements, ReC ... Rectifier, C1, C2 ... Capacitor, T ... Count-up coil, R1 ... Variable resistor, R2, R3 ... Resistor, ZD ... Zener diode, D ... Diode, Am ... Ammeter.

Claims (6)

A first zinc oxide element having one end connected to a lightning arrester;
A rectifier having an input end connected to one end and the other end of the first zinc oxide element;
A first capacitor charged by the output voltage of the rectifier;
A count-up coil driven by the discharge charge of the first capacitor;
A protection circuit connected to the other end of the first zinc oxide element;
An ammeter connected to the protection circuit;
And a variable resistor connected in parallel to the first zinc oxide element.   The discharge power meter according to claim 1, wherein the protection circuit includes a second zinc oxide element connected to the other end of the first zinc oxide element.   3. The discharge frequency meter according to claim 2, wherein an operation start voltage of the second zinc oxide element is lower than an operation start voltage of the first zinc oxide element.   The discharge power meter according to claim 2, wherein the protection circuit further includes a series circuit of a first resistor and a second capacitor connected to the other end of the first zinc oxide element.   The discharge power meter according to claim 4, wherein the protection circuit further includes a protection diode connected in parallel to the second capacitor.   6. The discharge frequency meter according to claim 4, wherein the protection circuit further includes a high-frequency cutoff filter circuit connected in parallel to the second capacitor.

Images