KR100703927B1 - Apparatus for monitoring obstacle of dual blocking diode - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a failure monitoring device for a blocking diode for a redundant power supply, and more particularly, to a monitoring device for a failure of two blocking diodes included in a redundant power supply used for stabilizing a power supply.

The constituent means of the fault monitoring device for the redundant power supply blocking diode of the present invention includes a direct current transformer for measuring a current flowing through each blocking diode, and an output signal of the direct current transformer and voltage signals at both ends of the blocking diode are converted into digital values. Displays the central processing unit (MPU) to determine whether the blocking diodes are normal by using the analog-digital converter, the current and voltage signals output from the analog-digital converter, and indicates the failure according to the command of the central processing unit. And a display device.

Redundant power supply, blocking diode

Description

Apparatus for monitoring obstacle of dual blocking diode

1 is a block diagram of a monitoring device of a blocking diode for a redundant power supply for explaining an embodiment of the present invention.

2 is a graph illustrating an operating point of the first and second blocking diodes according to an exemplary embodiment of the present invention.

3 is a graph showing the integrity region of a blocking diode according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

1: 1st power supply 2: 2nd power supply

3: first blocking diode 4: second blocking diode

5: load 6: first DC current transformer

7: second DC current transformer 8: analog-to-digital converter

9: central processing unit (MPU) 10: display unit

11: delivery device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a failure monitoring device for a blocking diode for a redundant power supply, and more particularly, to a monitoring device for a failure of two blocking diodes included in a redundant power supply used for stabilizing a power supply.

In a redundant power supply that uses a stable supply of DC power, a blocking diode is used to supply power to a load normally when one of the two supply powers is destroyed even if the other supply power is sound. use.

However, if one of the blocking diodes used in this case fails, the power supply delivered to the current load will not be redundant even if it is normal. Therefore, if the blocking diode is normally monitored and alarmed, the power supply may be unexpected. Unsuccessful interruptions will be avoided.

The present invention constantly measures the current flowing through the blocking diode and the voltage across the blocking diode, and compares it with the normal operating characteristic curve of the blocking diode, and monitors the failure of the blocking diode for the redundant power supply, which can prevent a power failure by alerting if there is an abnormality. Relates to a device.

The blocking diode for the redundant power supply is a diode which is installed to prevent the reverse flow of current when a problem such as a failure occurs in one supply power when two supply power supplies are used for stabilizing the power supply. The blocking diode may deteriorate due to mechanical and electrical stress depending on the installation environment, which causes the shutdown of critical equipment using redundant power supplies.

In general, the integrity test of a blocking diode for a redundant power supply is carried out by periodically disconnecting the circuit from the circuit and measuring the characteristics of the diode, which tends to depend on the human factors of the operator, It does not cope with.

In addition, there is a conventional technique that simply measures the voltage across the blocking diode and displays it as a lamp, but this also does not properly reflect the voltage-current characteristics of the diode's operating point, so that the degradation or failure of the blocking diode cannot be actually diagnosed. There is this.

The present invention was devised to solve the above problems of the prior art, and in order to solve the problem of the precautionary function of the failure monitoring method of the blocking diode, the voltage across the blocking diode and the current flowing through the blocking diode are measured. By detecting the operating point of the blocking diode and comparing it with the voltage-current characteristic curve of the normal diode, the failure monitoring of the blocking diode for the redundant power supply can improve the stability and reliability of the redundant power supply by constantly diagnosing and monitoring the failure. It is an object to provide a device.

In addition, by inputting the deterioration characteristics caused by the aging change of the blocking diode into the monitoring device and warning before the failure situation occurs, the blocking diode for the redundant power supply which can reduce the human and physical loss caused by the sudden power supply interruption. It is an object of the present invention to provide a failure monitoring apparatus.

In order to solve the above technical problem, the constituent means of the fault monitoring device of the blocking diode for a redundant power supply of the present invention includes a DC current transformer for measuring a current flowing through each blocking diode, an output signal of the DC current transformer, and the blocking diode. An analog-digital converter for converting voltage signals at both ends to a digital value, a central processing unit (MPU) for determining whether the blocking diodes are normal using current and voltage signals output from the analog-digital converter, and the central And a display device for displaying whether or not a failure occurs according to a command of the processing device.

In addition, the central processing unit is characterized in that it further comprises a transmission device for connecting to the external device.

The CPU may calculate an operating point of the blocking diode by using the current and voltage signals, and compare the result with a normal characteristic curve to diagnose and determine the failure of the blocking diode.

In addition, the DC current transformer is characterized in that the current transformer using a shunt resistor or a Hall element.

Hereinafter, with reference to the accompanying drawings will be described in detail the operation and preferred embodiment of the failure monitoring device of the blocking diode for a redundant power source consisting of the above configuration means.

1 is a block diagram of a failure monitoring apparatus of a redundant power supply system and a blocking diode for a redundant power supply applied to an embodiment of the present invention.

As shown in FIG. 1, a redundant power supply system according to a preferred embodiment of the present invention is redundant with a first power source 1 and a second power source 2 to supply power to a load 5, and the first The first blocking diode 3 and the second blocking diode 4 are connected to the power source 1 and the second power source 2 in series. In addition, the first blocking diode 3 and the second blocking diode 4 are connected to the load 5.

The failure monitoring apparatus of the blocking diodes for the redundant power supply for checking the failure of the blocking diodes 3 and 4 included in the redundant power supply system having the above structure flows to the first and second blocking diodes 3 and 4. A first DC current transformer 6 and a second DC current transformer 7 connected in series with the first and second blocking diodes 3 and 4, respectively, to measure current, and the first and second DC current transformers 6 And an analog-to-digital converter (8) for receiving the output signal of 7) and signals of the voltages at both ends of the first and second blocking diodes (3, 4) and converting them into digital signals, and the analog-to-digital converter (8). The CPU 9 includes a CPU 9 for determining whether the blocking diodes 3 and 4 are broken by using an output signal and a display device 10 for indicating whether the blocking diodes 3 are broken.

The first DC current transformer 6 and the second DC current transformer 7 are means for detecting a load current flowing through the first blocking diode 3 and the second blocking diode 4, respectively. Current can be detected.

The analog-to-digital converter 8 is a means for converting an analog voltage into a digital value that can be processed by the central processing unit (MPU) 9, and includes a first DC current transformer 6, a second DC current transformer 7, and It receives a signal corresponding to the voltage applied across the first and second blocking diodes (3, 4) and converts it into digital data and delivers it to the central processing unit (MPU) (9).

The central processing unit (MPU) 9 receives digital data corresponding to the current and voltage of the first blocking diode 3 and the second blocking diode 4 from the analog-digital converter 8, An algorithm for determining the health of the first blocking diode 3 and the second blocking diode 4 is performed.

The display device 10 causes the alarm means for notifying the result of the soundness determination of the central processing unit (MPU) 9 to a warning light and a warning sound.

Meanwhile, the transfer unit 11 may be further connected to the central processing unit 9 so as to be connected to an external device. Accordingly, the transmission device 11 performs a function of transmitting the soundness determination result of the central processing unit (MPU) 9 to an external device, and includes communication means using electrical or light.

Referring to Figure 1 will be described in more detail the operation of each component of the fault monitoring device for a blocking diode for a redundant power supply consisting of the above components.

The first DC current transformer 6 and the second DC current transformer 7 pass through a first blocking diode 3 and a second blocking diode 4 connected to the first power source 1 and the second power source 2, respectively. Measures the load current to be supplied.

The analog-to-digital converter 8 includes a circuit for converting a signal corresponding to the current of the first DC current transformer 6 and the current of the second DC current transformer 7 into a voltage signal, and the first blocking diode 3. Receives the anode voltage V1, the anode voltage V2 of the second blocking diode 4, and the cathode voltages V3 of the first and second blocking diodes 3, 4 and receives the voltage for analog-to-digital conversion. Include circuitry to convert to the appropriate size. That is, the five analog signals I1, I2, V1, V2, and V3 input to the analog-to-digital converter 8 are converted into voltage signals of appropriate magnitude, and these voltage signals are again converted into respective five digital data. Is converted to the central processing unit (MPU) 9.

The central processing unit (MPU) 9 performs the function of determining the health of the two blocking diodes 3 and 4 by using the five digital data. For this purpose, a microprocessor, a memory, a clock circuit, and communication Integrated circuits and digital input / output circuits.

The following describes a method in which the central processing unit (MPU) 9 determines the health of the two blocking diodes 3 and 4. When the input signals I1, I2, V1, V2, and V3 of the analog-to-digital converter are i1, i2, v1, v2, and v3, respectively, the forward opposite voltage of the first blocking diode 3 Is represented by (v1 v3), and the magnitude of the forward current is represented by i1. Similarly, the forward voltage across the second blocking diode 4 is represented by (v2 v3), and the magnitude of the forward current is represented by i2. Therefore, the voltage-current relationship between the first blocking diode 3 and the second blocking diode 4 can be obtained separately.

On the other hand, if the current supplied to the load 5 is I3, this current is shared by one side or one side of the first power source 1 and the second power source 2, and in either case, I3 = I1 + I2 is established. do. In FIG. 2, an example of an operating point of the blocking diodes 3 and 4 corresponding to the case where I1> I2> 0 is illustrated.

Now let's look at the operating point in terms of the individual blocking diodes (3 OR 4). In FIG. 3, the allowable range of the driving point is indicated by a dotted line. This allowable range is data stored in the non-volatile memory in the central processing unit (MPU 9 with reference to the data of the blocking diode 3 OR 4 actually used, and depending on the capacity and characteristics of the blocking diode 3 OR 4). Since the values vary, means should be provided for inputting this data to the central processing unit (MPU) 9 in the field application, including input by jumper switches, dip switches or communication.

In FIG. 3, since the driving point A and the driving point D are in the allowable area, the driving point A and the driving point D are determined to be healthy. A plurality of such permissible regions can be set as necessary, and for example, a method of setting the regions by separating them into minor failures and major failures is also possible.

On the other hand, in the case of an instantaneous allowance deviation, for example, a deviation of 10 [ms] or less, the decision algorithm of the central processing unit (MPU) 9 is a deviation from the operating point due to electrical noise or the like rather than a failure of the actual blocking diode. Install a low pass filter in the appropriate band.

The display device 10 performs a function of displaying a result of the soundness determination of the central processing unit (MPU) 9, and includes a lamp and a sound signal. The display device 10 is displayed for each of the two blocking diode states, and may be displayed in different colors for minor and major failures as necessary.

The transmission device 11 performs a function of transmitting the display contents of the display device 10 to an external device, and includes an electrical contact, wired / wireless communication, or communication means using light.

According to the fault monitoring apparatus of the blocking diode for a redundant power source of the present invention having the above-described configuration and operation, and a preferred embodiment, by constantly diagnosing and monitoring a fault of the blocking diode, there is an advantage of improving the stability and reliability of the redundant power supply. have.

In addition, the deterioration characteristics due to the aging change of the blocking diode are input to the central processing unit of the monitoring device, and warning and action is taken in advance before a failure situation occurs, thereby reducing the human and physical loss caused by sudden power supply interruption. have.

Claims (4)

In the fault monitoring device of a blocking diode for a redundant power supply, A direct current transformer for measuring a current flowing through each blocking diode; An analog-digital converter for converting an output signal of the DC current transformer and a voltage signal at both ends of the blocking diode into a digital value; A central processing unit (MPU) for determining whether each blocking diode is normal by using current and voltage signals output from the analog-digital converter; And a display device for displaying a failure according to a command of the central processing unit. The method according to claim 1, The central processing unit further comprises a transmission device for connecting to the external device fault monitoring device for a redundant power supply diode, characterized in that. The method according to claim 1 or 2, The central processing unit calculates an operating point of the blocking diode using the current and voltage signals, and compares the calculated operating point with a normal characteristic curve to diagnose and determine whether the blocking diode has failed. Failure monitoring device for blocking diode for power supply. The method according to claim 1, The DC current transformer is a fault monitoring device for a blocking diode for a redundant power supply, characterized in that the current transformer using a shunt resistor or a Hall element.

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