KR200174974Y1 - Digital v/a lcd monitoring apparatus in metering out fit - Google Patents

Abstract

The present invention relates to a device for detecting the voltage and current values of electricity supplied to a consumer's electricity meter when a combination of a power supply meter (MO F = metering out fit) and an electricity meter is used. It is possible to visually identify the electric state (current, voltage) that the amount of electricity flowing through the installation is displayed on the LCD display window as a number. The present invention relates to an electric quantity monitoring device displaying numerical values. The present invention is composed of instrument transformer (TR) and transformer transformer (MOF) of high-voltage power supply equipment composed of current transformer (CT) and resistor (R) and a sensing circuit for monitoring current and voltage. After configuring the secondary coil (TR), the capacitor (C), and the resistor (R), the wires drawn from the instrument transformer (TR) and the current transformer (CT) are each sensing circuit composed of a voltage detecting circuit and a current detecting circuit. It is connected to the power supply, and the power is supplied to the capacitor (C) and the resistor (R) in the line drawn in series, the sensing circuit is connected to the microprocessor, the microprocessor includes an LCD display, an alarm device, In the LCD display window, the current electric state, that is, the current and voltage of R phase, S phase, and T phase is displayed numerically, and the shorted phase among the phases displays voltage and current as 0. At the same time, the alarm device It was made to be dynamic.

Description

Digital V / A LCD Supervisor in Power Supply Transformer

The electric state (voltage, current), etc. of the customer of the present invention is detected and displayed visually, and if an abnormal voltage flows into the customer or if there is a short circuit in the wire, this is visually displayed, and an alarm is generated to cope with this problem. It relates to an electric monitoring device.

As a conventional patent document corresponding to the present invention, Utility Model Publication No. 91-4583 entitled: "Failure time identification device of power meter by detecting disconnection in instrument transformer (MOF)" (hereinafter, abbreviated as conventional design) can be seen. have.

Such a conventional design enables to identify the fixed time of the watt-hour meter by detecting the disconnection in the transformer of the instrument (MOF). It can be seen that the total elapsed time from the hour to the confirmation can be identified by a known counter circuit.

In ordinary high-voltage power supply facilities, if the current line or voltage line in the transformer of the instrument is not operated due to an unexpected short circuit, if the user immediately detects it and notifies the supplier, the electricity bill calculation problem used up to that point is There is no possibility of any fertilization between the supplier and the user, but if it is discovered after a long time, it is used for the reason that the user or supplier cannot confirm exactly when the failure occurred. In calculating the electricity bill, there are always a lot of application materials, especially in large factories that use a lot of electricity. The prior art proposal has an unexpected short circuit to a high-voltage power installation. When the electricity meter indicating the electricity consumption does not operate, the total elapsed time from the first failure to the confirmation and repair of the relevant person is easily displayed even when the failure is found after a long time since the failure occurred. This is to exclude the fertilization factor due to the electricity bill between the supplier side of the electricity user and to prevent the user from being disadvantaged due to miscalculation of the electricity bill. It has a damping circuit for detecting the short circuit of the current transformer and the instrument transformer installed therein, the sensing circuit has a counter circuit that is operated in association with it, the counter circuit is a power supply connected to the line of the instrument transformer for operating it Circuitry, and the counter circuit It can be seen that a normal electricity meter is connected.

Such a conventional design has only a function of detecting a disconnection between a current transformer installed in an instrument transformer and an instrument transformer so as to operate a normal counter circuit in the event of disconnection.

The present invention can visually determine the current electrical state by visually displaying the current state of the consumer, ie voltage, current, etc. on the LCD display without the help of a separate tester equipment, and abnormal voltage on any one of the RS T phases. When an abnormal current is generated or disconnected, it is displayed as a numerical value and an alarm is activated to deal with it immediately.In addition, the microprocessor circuit of the present invention detects an accurate time until recovery of a disconnection of a wire, thereby reducing the electricity bill. It is to clarify the fertilization.

1 is a block diagram schematically illustrating the overall configuration of the present invention.

2 is a circuit diagram of a power supply unit of the present invention.

3 is a circuit diagram of the voltage detector of the present invention.

4 is a circuit diagram of the current detection unit of the present invention.

The present invention relates to a device for detecting the voltage and current values of electricity supplied to a consumer's electricity meter when a combination of a power supply meter (MO F = metering out fit) and an electricity meter is used. Electricity monitoring device that displays numerically how much electricity flows by installing it and displays the electric status (voltage, current) visually so that trouble can be repaired immediately by notifying it when the disconnection on RST is broken. It is about.

Instrument transformers (MOF), (A) of high-voltage receiving equipment consisting of transformers (TR ₁ ), (TR ₂ ), (TR ₃ ) and current transformers (CT ₁ ), (CT ₂ ), (CT ₃ ) In having a sensing circuit B for detecting current and voltage, the secondary coils TR ₁ -V, TR ₂ -of the respective instrument transformers TR ₁ , TR ₂ , and TR ₃ . V), (TR ₃ -V), the secondary coils and capacitors (C ₁ -C ₃ ) and resistors (R ₁ -R) of the instrument transformer (TR ₁ ), (TR ₂ ), (TR ₃ ) ₂ ) the capacitor and resistor (C ₁ ) (R ₁ ), (C ₂ ) (R ₂ ), (C ₃ ) (R ₃ ) and current transformers (CT ₁ ), (CT ₂ ), (CT ₃ ) Each line (I _1H -I _3H ), (I _1L -I _3L ) drawn from the sensing circuit (B) consisting of a power supply circuit (C), a voltage detection circuit (D) and a current detection circuit (E) and The sensing circuit (B) is connected to the microprocessor (2), and the microprocessor (2) is connected to the LCD display (3), the alarm device (4), the conventional power meter (5). will be.

In the above, the power supply circuit C of the sensing circuit B is connected to the rectifier diodes d ₁ , d ₂ from the R line through the capacitor C ₁ and the resistor R ₁ , as shown in FIG. 2. ) And a resistor (R ₄ ), and are connected to rectifier diodes (d ₃ ), (d ₄ ) and resistor (R ₅ ) from the S line through a capacitor (C ₂ ) and a resistor (R ₂ ). from across the capacitor (C ₃₎ and a resistor (R ₃₎ into a direct current via a rectifier diode _{(d 5), (d 6} ) and being connected to a resistance (R _6), a capacitor for ripple voltage (C _4, C ₅₎ consists ever conversion, and to stabilize the voltage regulator (RG) and a capacitor (C _6), it supplies a stabilized power supply via the (C _7). Therefore, even if power is supplied to only one of the three phases of (RN), (SN), and (TN), power can be supplied. In the above description, the resistors R ₄ , R ₅ , and R ₆ are protection resistors of the regulator RG.

In the above, the voltage detection circuit D of the monitoring circuit B is connected to the bridge diode D ₁ and the transformer TR _{2 to the} secondary coils TR ₁ -V of the transformer TR ₁ , as shown in FIG. 3. ) 2 bridge diode (D ₂₎ to the primary winding (TR ₂ -V), and ever connecting bridge diode (D ₃₎ to the secondary coil of the transformer _{(TR 3) (TR 3 -V} ), a diode bridge (D in ₁₎ a resistor (R _11), capacitor (C ₁₅₎ resistance (VR ₁₎ and becomes connected to the microprocessor (2) via a capacitor (C _16), also resisting to the same circuit, a bridge diode (D ₂₎ ( R ₁₂ ) is connected to the microprocessor (2) via a capacitor (C ₁₇ ) resistor (VR ₂ ) and a capacitor (C ₁₈ ), and a resistor (R ₁₃ ) capacitor (C ₁₉ ) and a resistor to the bridge diode (D ₃ ). It is connected to (RV), (SV), and (TV) terminals of microprocessor 2 via (VR ₃ ) and condenser (C ₂₀ ). It will not work, and the micro Processor (2), and ever display such short-circuit locations on the LCD display (3), also, it will be to drive the alarm device (4).

Such a voltage detection circuit (D) detects when the R phase, the S phase, and the T phase are short-circuited, as well as when the voltages higher or lower than the specified value input to the microprocessor (2) are applied. The voltage on T is displayed on the LCD display 3, and an alarm is activated.

In the above, the current detecting circuit E of the sensing circuit B includes the lines I _1H -I _3H drawn from the current transformers CT ₁ , CT ₂ , and CT ₃ , as shown in FIG. 4. Connect (I _1L -I _3L ) to each bridge diode (D ₄ ), (D ₅ ), (D ₆ ), create a pulsating voltage, and make it a resistor (R ₁₄ ), (R ₁₅ ), (R ₁₆₎ and capacitor _{(C 21), (C 23} ), (C after ₂₅₎ a via made of the average voltage semi-fixed resistor _{(VR 4), (VR 5} ), (VR 6) and then through the capacitor (C ₂₂₎ , (C ₂₄ ) and (C ₂₆ ) to connect to the (RA), (SA) and (TA) terminals of the microprocessor (2).

Therefore, when current flows due to loads in R phase, S phase, and T phase, voltage is induced in the current transformers CT ₁ , CT ₂ , and CT ₃ , and the bridge diode D ₄ receives the voltage. Create a ripple voltage at, (D ₅ ), (D ₆ ) and average it across resistors (R ₁₄ ), (R ₁₅ ), (R ₁₆ ) and capacitors (C ₂₁ ), (C ₂₃ ) and (C ₂₅ ) After making the voltage, divide the voltage from the semi-fixed resistors (VR ₄ ), (VR ₅ ), (VR ₆ ), and then use the capacitors (C ₂₂ ), (C ₂₄ ), and (C ₂₆ ) to stabilize the averaged voltage. The voltage is applied to the current terminals RA, SA, and TA of the microprocessor 2, and the current value is displayed on the LCD display 3.

If the R-phase, S-phase, T-phase short-circuit or abnormal current occurs, the microprocessor detects this and displays it on the LCD display 3 as a numerical value and activates the alarm device 4 at the same time.

The microprocessor 2 used in the present invention converts the analog signal of the voltage detection circuit D and the current detection circuit E into a digital signal and transmits the signal to the LCD display 3 for discriminating the signal. A program for converting an analog signal into a digital signal is built in. In addition, the microprocessor 2 has an arithmetic function from the time of short-circuit to recovery when the R. S. T phase is short-circuited.

In the LCD display 3 used in the present invention, the voltage of the R phase (potential difference of RN), the voltage of the S phase (potential difference of SN phase), and the voltage of the T phase (potential difference of TN) are displayed numerically. Phase and T phase currents are displayed numerically.

In the present invention configured as described above, the normal current values and voltage values of the R phase, the S phase, and the T phase are normally displayed on the LCD display window 3 by numbers. However, if any one of R phase, S phase and T phase is short-circuited, no voltage is applied to the corresponding transformer TR, so the microprocessor 2 detects this and displays the voltage dimension of the shorted phase as 0. At the same time, by operating the alarm device 4 to be repaired immediately, by the arithmetic function of the microprocessor (2) to accumulate the time from the failure until the completion of repair.

Even if only two phases of the R phase, S phase, and T phase are shorted and only one phase is alive, the power supply circuit C operates so that the two shorted phases are displayed numerically on the LCD display window, but all three phases are shorted. If the power supply circuit (C) does not work, the device itself stops working.

In addition, even when an abnormal current occurs in the R phase, the S phase, and the T phase, the microprocessor 2 detects this and displays the current value of the phase in which the abnormal current is generated on the LCD display window 3 as a number. By operating (4), the trouble can be repaired in a short time. The alarm device 4 may generate an alarm with a light, such as a flashing light, and may generate an alarm with a buzzer sound.

Normally, to check the state of electricity supplied to the customer, that is, voltage and current, it must be read by using a tester, but the present invention shows the current electric state by visually displaying the current voltage and current values by the LCD display window. In case of a short circuit failure or voltage and current out of the specified value, it is notified by an alarm and can be repaired immediately. It is a very useful design that can accurately calculate the charges for the use of electric power due to the integration to prevent the application of the electric charges, which frequently occurred in the user and supply time in the past.

The present invention is installed between the transformer for power supply (MOF) and the wattmeter (wattmeter) to display the current and the current state to the power meter, that is to the customer with the naked eye to supply the current without the aid of a separate tester Its first purpose is to make it possible to visually identify the state of electricity (voltage, current) being generated, and also to immediately detect when the RS T is disconnected or when an abnormal voltage is introduced. The second purpose is to display the current status and to activate the alarm at the same time, so that the alarm can be immediately responded. The third purpose of this is to enable the user to know the disconnection time of the electric power and to prevent the application of electric charges in advance. The inside of the display shows the voltage difference on the RS T on the display window, so if an abnormal voltage higher or lower than the specified value is introduced, it is detected early and the circuit is checked to prevent the electrical accident caused by the abnormal voltage. It is done.

Claims (2)

Instrument transformers (MOF), (A) of high-voltage receiving equipment consisting of transformers (TR ₁ ), (TR ₂ ), (TR ₃ ) and current transformers (CT ₁ ), (CT ₂ ), (CT ₃ ) It has a circuit for detecting current and voltage, and the secondary coils (TR ₁ -V), (TR ₂ -V), (TR ₃ ) of the respective instrument transformers (TR ₁ ), (TR ₂ ), (TR ₃ ) -V) and the secondary coil of the instrument transformer (TR ₁ ), (TR ₂ ), (TR ₃ ) and the capacitor (C ₁ -C ₃ ) and the resistor (R ₁ -R ₂ ) through the capacitor And wires drawn from the resistors C ₁ (R ₁ ), (C ₂ ) (R ₂ ), (C ₃ ) (R ₃ ) and current transformers (CT ₁ ), (CT ₂ ), (CT ₃ ) (I _1H -I _3H ), (I _1L -I _3L ) are connected to a sensing circuit (B) consisting of a power supply circuit (C), a voltage detecting circuit (D) and a current detecting circuit (E), and the sensing The circuit (B) is connected to a microprocessor (2), the microprocessor (2) is connected to an LCD display (3), an alarm device (4), a conventional power meter (5) transformer for power supply instrument Digital V / A LCD in (MOF) In the monitoring apparatus, the power supply circuit C of the sensing circuit B is connected to the rectifier diodes d ₁ , d ₂ , and resistor R ₄ from the R line through the capacitor C ₁ and the resistor R ₁ . ) Is connected to the rectifier diodes (d ₃ ), (d ₄ ) and resistor (R ₅ ) from the S line through the capacitor (C ₂ ) and the resistor (R ₂ ), and from the T line to the capacitor (C ₃ ) and via a resistor (R ₃₎ is connected with a rectifier diode _{(d 5), (d 6} ) and a resistor (R _6), and convert the pulsating voltage to a direct current through the capacitor (C _4, C _5), stabilizing the voltage the secondary coil of the regulator (RG) and a capacitor (C _6), and ever supplying a stabilized power supply via the (C _7), wherein the sensing circuit (B) a voltage detection circuit (D) is a transformer (TR ₁₎ of the ( TR ₁ -V to bridge diode (D ₁ ), secondary coil (TR ₂ -V) of transformer (TR ₂ ) to bridge diode (D ₂ ) and secondary coil (TR ₃ -V) of transformer (TR ₃ ) ) bridge diode (and ever connected to the D _3), the diode bridge (resistors (R _11), condenser (C ₁₅ to ₁ D) in ) Is connected to the microprocessor (2) via a resistor (VR ₁ ) and a capacitor (C ₁₆ ), a resistor (R ₁₂ ) capacitor (C ₁₇ ) resistor (VR ₂ ) and a capacitor (C) to the bridge diode (D ₂ ). ₁₈ to a microprocessor (2), and to a bridge diode (D ₃ ) via a resistor (R ₁₃ ) capacitor (C ₁₉ ) and a resistor (VR ₃ ) and a capacitor (C ₂₀ ) The current detection circuit E of the sensing circuit B is connected to the current lines I _1H -I _3H , I _1L drawn from the current transformers CT ₁ , CT ₂ , and CT ₃ . -I _3L ) is connected to each of the bridge diodes (D ₄ ), (D ₅ ), (D ₆ ), creating a pulsating voltage and responsive to each of the resistors (R ₁₄ ), (R ₁₅ ), (R ₁₆ ) and After the average voltage is made through the capacitors (C ₂₁ ), (C ₂₃ ) and (C ₂₅ ), through the semi-fixed resistors (VR ₄ ), (VR ₅ ) and (VR ₆ ), the capacitors (C ₂₂ ) and (C ₂₄ and instruments for electricity supply and demand, characterized in that each connection consists of a microprocessor (2) through the C ₂₆₎ Digital V / A LCD monitor device in the shift converter (MOF). The LCD display window (3) shows the voltage current of the R phase, the voltage current of the S phase, and the voltage current of the T phase in a normal time while the one of the R phase, the S phase, and the T phase is short-circuited. Digital V / A LCD monitoring device in power supply transformer (MOF), characterized in that the time from the short circuit to the recovery is displayed.