KR101829615B1 - Auxiliary Device for Inspecting Power Supply - Google Patents

Abstract

The present invention relates to a power supply check assist device capable of easily connecting a power supply and a check device to be calibrated, and capable of reducing the number of check devices used for calibration using a self-display and a switching device will be. The auxiliary power supply checking auxiliary device according to an embodiment of the present invention includes an input terminal portion to which a supply voltage output from a variable voltage unit is applied and a supply voltage A voltage terminal portion to which an output voltage supplied from a power supply is supplied and a current terminal portion to which an output current whose output voltage is converted through the shunt resistor is applied, a voltage terminal portion or a current An output terminal for outputting an output voltage or an output current applied to the terminal portion to the outside, and a switch portion for selectively outputting an electric signal of an output voltage or an output current from the output terminal portion.

Description

Auxiliary Device for Inspecting Power Supply [0002]

The present invention relates to an inspection assistant device for checking an internal circuit of a power supply. More particularly, the present invention relates to an inspection assistant device capable of reducing the number of multimeters used in the measurement of a power supply and easily connecting the inspection devices and the power supply electrically.

The contents described in this section merely provide background information on the embodiment of the present invention and do not constitute the prior art.

Modern aircraft used in recent years are equipped with a variety of electronic equipment to provide an environment in which aircraft can perform more missions, such as assisting airline operations. Electronic equipment mounted on the aircraft should be checked for normal operation by regular inspections to ensure safe operation of the aircraft.

An inspection system for checking electronic equipment is generally equipped with a power supply for supplying driving power for driving the inspection system. Since the inspection system must check electronic equipment sensitive to electrical signals, the power supplied by the power supply to the inspection system needs to be fine-tuned. Therefore, the power supply shall be classified as precision measuring equipment and calibrated every 9 ~ 60 months according to the equipment type.

The calibration of the power supply can be performed by measuring the voltage, current, etc. of the internal circuit of the power supply. In the past, a variable resistor, a variable voltage, a shunt resistor and three multimeters were required for measurement.

Since the calibration of the power supply must electrically connect six or more inspection devices, the electrical connection between the plurality of inspection devices may not be performed correctly due to the error or negligence of the inspector. Corrective actions after incorrect connections can cause equipment damage, and leakage currents due to incorrect connections can pose a serious threat to the safety of the inspector.

In order to solve such a problem, the present invention can easily carry out the connection between the power supply and the inspection apparatus to be calibrated, and it is possible to reduce the number of inspection apparatuses used for calibration by using the own display and the switching apparatus And an auxiliary device.

The auxiliary power supply checking auxiliary device according to an embodiment of the present invention includes an input terminal portion to which a supply voltage output from a variable voltage unit is applied and a supply voltage A voltage terminal portion to which an output voltage supplied from a power supply is supplied and a current terminal portion to which an output current whose output voltage is converted through the shunt resistor is applied, a voltage terminal portion or a current An output terminal for outputting an output voltage or an output current applied to the terminal portion to the outside, and a switch portion for selectively outputting an electric signal of an output voltage or an output current from the output terminal portion.

In addition, the switch unit selects either the first switch for selecting either the high signal of the output voltage or the high signal of the output current to the output terminal unit, and the low signal of the output voltage or the low signal of the output current And outputting it to the output terminal portion.

A voltage display that is turned on when both the high signal of the output voltage and the low signal of the output voltage are output from the output terminal portion and a current indicator that is turned on when both the high signal of the output current and the low signal of the output current are output from the output terminal portion . ≪ / RTI >

In addition, it may further comprise a voltage indicator, a current indicator, and a power source connected to the external power source to supply power to the display unit.

According to an embodiment of the present invention, it is possible to electrically connect the inspection device and the power supply necessary for calibration to minimize the error of the inspector, minimize the inaccurate connection and thereby reduce the risk of electric shock accidents due to leakage current, The possibility of breakage can be reduced.

In addition, a multimeter allows the user to grasp the internal circuit characteristics of the power supply, thereby enhancing the measurement convenience.

FIG. 1 is a circuit diagram showing a connection relationship of devices required for a conventional calibration operation.
2 is an overall perspective view of a power supply check assistance device in accordance with an embodiment of the present invention.
3 is a front view and a rear view of a power supply check assistance device according to an embodiment of the present invention.
4 is an internal circuit diagram of a power supply check assisting apparatus according to an embodiment of the present invention.
5 is a circuit diagram showing the connection relationship of the devices necessary for the improved calibration operation.

Hereinafter, some embodiments of the present invention will be described in detail based on exemplary drawings. It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference symbols as possible even if they are shown in different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 1 is a circuit diagram showing a connection relationship of devices required for a conventional calibration operation.

Calibration of the power supply 10 is performed by measuring an electrical signal output from the power supply 10. Through such a calibration operation, it is possible to determine whether the power supply 10 is operating normally or not, and it is possible to determine whether maintenance or repair of the power supply 10 is necessary.

A variable voltage generator VARIAC 20 is provided to supply a voltage to the power supply 10 and the variable voltage generator 20 may preferably be a variable voltage supply in the range of 105 to 125 V. [ The multimeter 70 receives a supply voltage supplied from the variable voltage generator 20 to the power supply 10 and displays a numerical value of the supply voltage in an analog or digital form.

The power supply 10 receives a supply voltage supplied from the variable voltage generator 20 and outputs an output voltage, and the output voltage of the power supply 10 can be adjusted by an output adjusting unit (not shown) provided on the surface. The power supply 10 may display a numerical value of the output voltage by a display (not shown) provided therein. The multimeter 70 receives the output voltage from the power supply 10 and displays the numerical value of the output voltage in an analog or digital form and can be expressed to a more accurate value than the numeric value indicated on the display of the power supply 10 . The inspector compares the output voltage with the value displayed on the display of the power supply 10 and the measured value on the multimeter 70 to determine whether the output voltage is normal. Whether the output voltage of the power supply 10 is normal may be normal when the difference is within a predetermined error range, and may be abnormal when the difference is outside the error range.

The variable resistor 30 provides a load to be supplied to the output of the power supply 10 and the shunt resistor 60 is a low resistance resistor for measuring the output current output from the power supply 10. [ . The multimeter 70 electrically connected to the shunt resistor 60 is connected to the shunt resistor 60 through the Ohm's law based on the voltage difference between both ends of the shunt resistor 60 and the resistance value of the internal low resistance of the shunt resistor 60 The value of the output current flowing in the resistor can be expressed in analog or digital form. Whether the output current of the power supply 10 is normal may be normal when the difference is within a predetermined error range, and may be abnormal when the difference is outside the error range.

To summarize the foregoing, the inspector supplies the supply voltage to the power supply 10 via the variable voltage generator 20 and measures the supply voltage to the multimeter 70 connected to the variable voltage generator 20. Further, the output control unit of the power supply 10 is operated to supply the output voltage to the variable resistor 30, and the value of the output voltage is measured by the multimeter 70 electrically connected to the output of the power supply 10 . The inspector electrically connects the shunt resistor 60 and the multimeter 70 to measure the output current flowing through the low resistance of the shunt resistor 60 to measure the output current.

The conventional calibration work includes the variable voltage generator 20, the multimeter 70 for measuring the supply voltage of the variable voltage generator 20, the multimeter 70 for measuring the output voltage of the power supply 10, A connection of six inspection devices (or standard devices) such as a resistor 30, a shunt resistor 60, and a multimeter 70 for measuring an output current flowing through the shunt resistor 60 was required.

FIG. 2 is an overall perspective view of a power supply check assisting apparatus according to an embodiment of the present invention, and FIG. 3 is a front view and a rear view of a power supply check assisting apparatus according to an embodiment of the present invention.

The inspection assistant device 100 is a device that includes a circuit board (not shown) in the case 40 and has circuit elements at the top of the circuit board to input and output an electric signal.

The input terminal unit 120 is an input channel for receiving a supply voltage output from the variable voltage generator 20. [ The input terminal unit 120 is electrically connected to the display unit 110 and the display unit 110 displays the supply voltage applied through the input terminal unit 120 to the outside. The display unit 110 may display the supply voltage with a scale of an analog meter, but more preferably, it may be a digital meter that displays in the form of a number. The display unit 110 provided as a digital meter can receive driving power for displaying a number through a power supply unit 180 to be described later.

The voltage terminal unit 130 is an input channel for receiving an output voltage output from the power supply unit 10 as a supply voltage is supplied to the power supply unit 10. [ The voltage terminal unit 130 is electrically connected to the output channel of the power supply unit 10 and receives the output voltage of the power supply unit 10 and transmits the output voltage to the output terminal unit 150 to be described later.

The current terminal unit 140 is an input channel to which the output voltage output from the power supply unit 10 receives the converted output current through the shunt resistor 60. [ Here, the output current converted through the shunt resistor 60 is calculated by Ohm's law based on the voltage difference across the low resistance of the shunt resistor 60 and the resistance value of the low resistance resistor. Current value. The current terminal portion 140 is electrically connected to the output channel of the shunt resistor 60 and receives the output current to transmit to the output terminal portion 150 to be described later.

The output terminal unit 150 is an output channel for externally outputting an output voltage or an output current applied to the voltage terminal unit 130 or the current terminal unit 140. The output terminal unit 150 is electrically connected to the voltage terminal unit 130 or the current terminal unit 140 and outputs an output voltage or an output current applied to the voltage terminal unit 130 or the current terminal unit 140, Channel. The external checking device connected to the output terminal unit 150 may be a multimeter 70, but a checking device such as an RMS voltmeter or an oscilloscope may be connected.

The switch unit 160 is provided to selectively output one of an output voltage or an output current from the output terminal unit 150. When the switch unit 160 is operated to selectively output any one of the output voltage and the output current, only one multimeter 70 can change the measurement mode to measure both the output voltage and the output current. have.

The switch unit 160 may include a first switch 161 and a second switch 163.

The first switch 161 selects either the high signal of the output voltage or the high signal of the output current and outputs the selected signal to the high channel of the output terminal unit 150. The second switch 163 outputs the low signal Or the low-level signal of the output current, and outputs the selected signal to the low channel of the output terminal unit 150. In order for a normal output voltage or output current to be output from the output terminal unit 150, both the high signal and the low signal of each output must be output from the output terminal unit 150. Both the first switch 161 and the second switch 163 must be operated upward to select the 'voltage' in order to output the output voltage from the output terminal unit 150. In order to output the output current, And the second switch 163 must be operated downward to select 'current'. If the switch unit 160 is provided with the first switch 161 and the second switch 163, both the first switch 161 and the second switch 163 must be operated in the same direction for normal output, The output by selection can be prevented.

The voltage indicator 171 is turned on when both the high signal of the output voltage and the low signal of the output voltage are output from the output terminal unit 150, indicating that the output voltage is normally outputable. The current indicator 173 is turned on when both the high signal of the output current and the low signal of the output current are output from the output terminal unit 150, indicating that the output current can be normally output.

The power unit 180 is connected to an external power source to supply power to the voltage indicator 171, the current indicator 173, and the display unit 110. The voltage indicator 171, the current indicator 173 and the light source provided inside the display unit 110 may be turned on by power supplied from an external power source. The voltage indicator 171, the current indicator 173, and the light source provided inside the display unit 110 may preferably be LEDs.

The power switch 190 is provided to cut off or supply the voltage indicator 171, the current indicator 173 and the power supplied to the display unit 110 from the power supply unit 180. The power switch 190 short-circuits or opens the circuit through on / off operation to supply or cut off power. The power switch 190 may include a light source that is turned on when electric power is supplied to immediately detect whether the electric power is supplied.

FIG. 4 is an internal circuit diagram of a power supply check assisting apparatus according to an embodiment of the present invention, and FIG. 5 is a circuit diagram showing a connection relationship of devices necessary for an improved calibration work.

An improved calibration operation including the inspection assist device based on the above-described components of the inspection assist device will be described as follows.

When the inspector connects the external power source to the power source unit 180 and operates the power switch 190 (short-circuited), the external power is supplied to the display unit 110, the voltage indicator light 171 and the current indicator light 173 Can be supplied. When the external power source supplies the AC voltage, the display unit 110 may be directly connected to the external power source, but the voltage indicator 171 and the current indicator 173 are converted into a DC voltage by the converter 50, There is a need.

The supply voltage supplied from the variable voltage generator 20 is supplied to the power supply 10 and the supply voltage of the variable voltage generator 20 is also applied to the inspection assistant 100 via the input terminal 120. [ The display unit 110 may display the numerical value of the supply voltage applied from the variable voltage generator 20. If the display unit 110 is a digital meter, It can also manifest.

The power supply 10 generates an output voltage based on the supply voltage supplied from the variable voltage generator 20 and the output voltage of the power supply 10 can be adjusted by the inspector to manipulate the output voltage. The output voltage of the power supply 10 is also applied to the inspection assistant 100 via the voltage terminal portion 130.

The variable resistor 30 may provide a load on the output of the power supply 10 and regulate the variable resistor 30 to regulate the magnitude of the output current to the output voltage of the power supply 10. The output current of the power supply 10 can be accurately measured by calculating the voltage difference between both ends of the low resistance element included in the shunt resistor 60 and the resistance value of the low resistance resistor. The output current of the power supply 10 is also applied to the assistive device 100 via the current terminal portion 140 electrically connected to the output of the shunt resistor 60.

The output voltage or output current of the power supply 10 includes a high signal and a low signal, respectively. When the high signal and the low signal of the output voltage or the high signal and the low signal of the output current are output to the output terminal unit 150, Or the output current can be accurately measured.

The first switch 161 selects either the high signal of the output voltage or the high signal of the output current to apply to the high channel of the output terminal unit 150. At the same time, the first switch 161 may select either the high signal of the output voltage or the high signal of the output current to apply to the voltage indicator 171 or the current indicator 173. The second switch 163 selects either the low signal of the output voltage or the low signal of the output current to apply to the low channel of the output terminal unit 150. At the same time, the second switch 163 selects either the low signal of the output voltage or the low signal of the output current to apply to the voltage indicator 171 or the current indicator 173. Accordingly, if the first switch 161 and the second switch 163 select both the high signal and the low signal of the electric signal of either the output voltage or the output current, the output voltage or output current from the output terminal unit 150 is normally output And the voltage indicator 171 or the current indicator 173 can be normally turned on.

The output voltage or output current output from the output terminal unit 150 may be measured by a multimeter 70 electrically connected to the output terminal unit 150. The inspector operates the first switch 161 and the second switch 163 to select the output signal of the output terminal section 150 as the output voltage or the output current and change the measurement mode of the multimeter 70 or use a calculation formula The output voltage or the output current can be accurately measured by only one multimeter 70.

An RMS voltmeter or an oscilloscope may be connected to the output terminal unit 150 to measure the degree of ripple noise of the power supply 10 output. The inspector may operate the first switch 161 and the second switch 163 to change the output signal to measure the degree of ripple noise of each output signal to perform an additional correction operation.

The foregoing description is merely illustrative of the technical idea of the present embodiment, and various modifications and changes may be made to those skilled in the art without departing from the essential characteristics of the embodiments. Therefore, the present embodiments are intended to be illustrative rather than limiting, and the scope of the technical idea of the present embodiment is not limited by these embodiments. The scope of protection of the present embodiment should be construed according to the following claims, and all technical ideas within the scope of equivalents thereof should be construed as being included in the scope of the present invention.

10: power supply 20: variable voltage generator
30: variable resistor 40: case
50: converter 60: shunt resistor
70: Multimeter 100: Inspection aid
110: display section 120: input terminal section
130: Voltage terminal part 140: Current terminal part
150: output terminal part 160: switch part
161: first switch 163: second switch
171: Voltage indicator 173: Current indicator
180: Power supply unit 190: Power switch

Claims (4)

1. An inspection assistance device for inspecting an internal circuit of a power supply,
An input terminal portion that is output from the variable voltage unit and is adapted to receive a supply voltage supplied to the power supply unit;
A display unit for externally displaying the supply voltage applied to the input terminal unit;
A voltage terminal unit to which the supply voltage is supplied to the power supply unit and to which an output voltage from the power supply unit is applied;
A current terminal portion to which an output current obtained by converting the output voltage through the shunt resistor is applied;
An output terminal unit for outputting the output voltage or the output current applied to the voltage terminal unit or the current terminal unit to the outside; And
And a switch unit for selectively outputting any one of the output voltage or the output current from the output terminal unit,
Wherein the switch unit comprises: a first switch for selecting either a high signal of the output voltage or a high signal of the output current to output to the output terminal unit;
A second switch for selecting any one of a low signal of the output voltage and a low signal of the output current to output to the output terminal portion;
A voltage indicator lighted when the high signal of the output voltage and the low signal of the output voltage are all output at the output terminal portion; And
And a current indicator which is lit when the high signal of the output current and the low signal of the output current are all output at the output terminal portion. delete delete The method according to claim 1,
The voltage indicator, the current indicator, and a power unit connected to an external power source to supply power to the display unit.

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