KR102409415B1 - Test apparatus and test method - Google Patents

Abstract

An embodiment of the present invention is a test apparatus for creating a test environment to test a test object, which is an electronic device mounted on an aircraft, in a first chamber having an internal space, and in the first chamber to adjust the pressure inside the first chamber A connected pump, a second chamber capable of accommodating the test object and having an internal space smaller than that of the first chamber, a connecting pipe installed to connect the first chamber and the second chamber, and communication between the first chamber and the second chamber It may include a valve installed in the connection pipe to control the.
Accordingly, according to embodiments of the present invention, the pressure of the chamber in which the test object is accommodated may be rapidly changed. That is, it is possible to adjust or simulate the pressure in the chamber close to the actual pressure change rate according to the altitude change rate of the fighter. Therefore, in determining whether the electronic device under test satisfies the specifications required by the fighter, its reliability can be improved.

Description

Test apparatus and test method {TEST APPARATUS AND TEST METHOD}

The present invention relates to a test apparatus and a test method, and to a test apparatus and a test method that can easily test whether a test object is driven normally according to a change in pressure.

Fighters used in air combat are equipped with various electronic devices. For example, in a fighter, a communication device for communicating with a control station on the ground, an acoustic device that can output or reproduce the current situation of the fighter so that the driver aboard the fighter can recognize it, and a radar imaging device that acquires an image of the target , an electronic device such as a camera for capturing images or images may be installed.

On the other hand, a fighter is a flying device, and the higher the altitude, the lower the internal pressure. At this time, the electronic device mounted on the fighter may be affected by the pressure, and may not operate due to the impact caused by the pressure change.

Therefore, before installing the electronic device in the fighter, it is necessary to conduct a test on the electronic device. That is, after exposing the electronic device to a pressure change environment according to the altitude of the fighter, it is necessary to conduct a test to determine whether the electronic device operates normally.

At this time, the test is conducted using a chamber that can control the pressure. Briefly describing this, first, the electronic device under test is loaded into the chamber. Then, the chamber is evacuated to reduce the pressure of the chamber to a target pressure. Next, it is tested whether the electronic device operates normally when the pressure in the chamber reaches the target pressure. At this time, if the electronic device operates normally, the corresponding electronic device is installed in the fighter, and if the electronic device does not operate normally, the corresponding electronic device is replaced with an electronic device of a different specification.

On the other hand, a fighter can change its altitude quickly at a rate of change of 1,016 m/s, and the faster the rate of change in altitude, the faster the rate of pressure reduction of the fighter. Therefore, in reducing the pressure inside the chamber, it is necessary to match or simulate the pressure reduction rate according to the rate of change in altitude of the fighter.

However, the chamber used as a conventional test apparatus has a large volume, so it is impossible to simulate the pressure inside the chamber to match the pressure change rate of the fighter.

Korean Patent Registration 10-2266496

The present invention provides a test apparatus and test method capable of exposing a test object to a pressure change environment.

The present invention provides a test apparatus and test method that can be tested by exposing an electronic device mounted on an aircraft to an environment of pressure change according to altitude.

The present invention provides a test apparatus and a test method that can be tested by exposing a test object to an environment of rapid pressure change.

An embodiment of the present invention is a test apparatus for creating a test environment in order to test a test object, which is an electronic device mounted on an aircraft, comprising: a first chamber having an internal space; a pump connected to the first chamber to adjust the pressure inside the first chamber; a second chamber capable of accommodating the test object and having an internal space of a smaller volume than that of the first chamber; a connection pipe installed to connect between the first chamber and the second chamber; and a valve installed on the connection pipe to control communication between the first chamber and the second chamber.

The volume of the second chamber may be 30% or less of the volume of the first chamber.

a first pressure sensor installed in the first chamber to measure the pressure of the first chamber; and a control unit configured to control the operation of at least one of the pump and the valve according to the pressure measured by the first pressure sensor.

A first target pressure is set in the control unit, the control unit controls the operation of the pump so that the pressure measured by the first pressure sensor becomes a first target pressure, and the control unit controls the pressure measured by the first pressure sensor When the first target pressure is reached, the operation of the pump may be stopped and the valve may be opened.

and a second pressure sensor installed in the second chamber to measure the pressure of the second chamber, wherein the control unit sets a second target pressure, and the control unit sets the pressure measured by the second pressure sensor to the second target pressure. When pressure is reached, an alarm can be generated.

A gas supply member connected to the first chamber may be included to supply gas into the first chamber.

An embodiment of the present invention is a test method for testing the driving state of the test object using an electronic device mounted on an aircraft as a test object, and evacuates the inside of the first chamber to adjust the inside of the first chamber to a first target pressure process; loading the test object into a second chamber provided separately from the first chamber; when the pressure in the first chamber reaches a first target pressure, communicating the first chamber and the second chamber to adjust the pressure in the second chamber; and when the pressure in the second chamber reaches a second target pressure, a process of confirming whether the test object accommodated in the second chamber is normally driven.

and setting the first target pressure, wherein the first target pressure is determined such that the pressure of the second chamber reaches a second target pressure within a preset reference time after the first chamber and the second chamber are communicated. pressure can be set.

The reference time may be 0.6 seconds or less, and the second target pressure may be 0.8 psia or less.

The first target pressure may be set such that after the first chamber and the second chamber communicate with each other, the pressure of the second chamber decreases by more than a preset reference pressure difference.

The reference pressure difference may be 0.5 psia or more.

According to embodiments of the present invention, the pressure of the chamber in which the test object is accommodated may be rapidly changed. That is, it is possible to adjust or simulate the pressure in the chamber close to the actual pressure change rate according to the altitude change rate of the fighter. Therefore, in determining whether the electronic device under test satisfies the specifications required by the fighter, its reliability can be improved.

1 is a block diagram conceptually showing a testing apparatus according to an embodiment of the present invention.
2 is a flowchart illustrating a test method of a test object using a test apparatus according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms, only these embodiments allow the disclosure of the present invention to be complete, and the scope of the invention to those of ordinary skill in the art completely It is provided to inform you. The drawings may be exaggerated in order to explain the embodiment of the present invention, and like reference numerals in the drawings refer to the same components.

The present invention relates to a test apparatus capable of exposing a test object, which is an object to be tested, to an environment in which pressure is changed. Here, the test object may be an electronic device mounted on a fighter aircraft rather than an aircraft. Accordingly, the present invention can be more specifically described as a test device that can be tested by exposing an electronic device under test to a pressure change environment according to the altitude of a flying aircraft or fighter.

In addition, the present invention provides a test apparatus capable of creating a test environment with the test conditions presented in MIL-STD-810. More specifically, the present invention provides a test apparatus capable of lowering the pressure of the chamber into which the test object is loaded to the target pressure within the reference time suggested in MIL-STD-810. As a more specific example, it relates to a test apparatus capable of lowering the pressure of a chamber into which a test object is loaded to a target pressure of 0.8 psia or less within a reference time of 0.6 seconds.

1 is a block diagram conceptually showing a testing apparatus according to an embodiment of the present invention.

1, in the test apparatus according to an embodiment of the present invention, a first chamber 100a having an internal space, a pressure adjusting unit 200 connected to the first chamber 100a, and a test object S are accommodated. and a second chamber 100b having an internal space having a smaller volume or volume compared to the first chamber 100a, and a connection pipe 300 connecting the first chamber 100a and the second chamber 100b. , and a valve 400 installed in the connection pipe 300 to control communication between the first chamber 100a and the second chamber 100b.

In addition, the test apparatus includes a first pressure sensor 500a for measuring the pressure in the first chamber 100a, a second pressure sensor 500b for measuring the pressure in the second chamber 100b, and first and second pressure sensors. The control unit 700 for controlling the operation of at least one of the pressure adjusting unit 200 and the valve 400 according to the pressure measured at each of 500a and 500b may be included.

In addition, the test apparatus may include a monitoring unit 600 that displays each of the pressures measured by the first and second pressure sensors 500a and 500b so that the operator can check them.

The test object (S) to be tested through the test device may be an electronic device installed in a fighter aircraft, more specifically, an aircraft. As a more specific example, the electronic device, which is the subject (S), is a communication device for communication between a fighter and a control center on the ground, and a headset mounted by a driver aboard the fighter. It may be a device. Here, the device capable of reproducing the current situation of the fighter by sound may be a device that outputs a voice or an alarm to inform when the current altitude of the fighter, the pressure around the fighter, whether a missile is fired, or a fire occurs in the engine. As another example, the electronic device, which is the test object S, may be one of a radar imaging device that acquires an image of a target, and a camera that captures an image or an image. Of course, the test object is not limited to the above-described examples, and various electronic devices installed in aircraft or fighters can be applied.

The test object S may be installed to be accommodated inside the second chamber 100b, and thus the test object S may be exposed to the pressure change environment of the second chamber 100b. In the embodiment, the pressure inside the second chamber 100b is changed to expose the test object S accommodated in the second chamber 100b to a pressure change environment. And test whether the test object (S) operates normally.

The first chamber 100a has an inner space, and the inner space is provided to have a larger volume than a second chamber 100b to be described later. At this time, the volume of the first chamber 100a is 5 to 10 times larger than that of the second chamber 100b, preferably 7 to 10 times larger, and more preferably 8 to 9.5 times larger. It may be provided to be twice as large. More specifically, the volume of the first chamber 100a may be, for example, 80,000 cm ² to 200,000 cm ² , preferably 100,000 cm 2 to 150,000 cm ² , and more preferably 135,000 cm ² to 145,000 cm ² It can be cm ² . To explain with a more specific example, the first chamber 100a may be a hexahedron having a quadrangular cross-section. Also, the first chamber 100a may have a hexahedral shape having a horizontal length of 51 cm (510 mm), a vertical length of 56 cm (560 mm), and a height of 50.5 cm (505 mm).

However, the shape of the first chamber 100a is not particularly limited, and may be provided in a circular shape, an oval shape, and various polygonal shapes. That is, as long as the volume of the internal space of the first chamber 100a can be 5 to 10 times larger than that of the second chamber 100b, it may be provided in any shape.

In this way, the provision of the volume of the first chamber 100a to be 5 times larger than that of the second chamber 100b is to rapidly reduce the pressure of the second chamber 100b in which the test object S is charged. to be. In other words, a fighter's pressure changes rapidly with its altitude change rate. In order to simulate the pressure change environment of such a fighter, the volume of the first chamber 100a, which is a means for regulating the pressure of the second chamber 100b, is provided to be at least 5 times greater than that of the second chamber 100b.

The pressure adjusting unit 200 is a device for adjusting the pressure inside the first chamber 100a. The pressure adjusting unit 200 may include a pump 210 for exhausting the gas inside the first chamber 100a. Also, the pressure adjusting unit 200 may include a gas supply member 220 capable of supplying a gas into the first chamber 100a.

The pump 210 exhausts the gas inside the first chamber 100a so that the pressure inside the first chamber 100a becomes less than atmospheric pressure. As the pump 210, any type of pump may be applied as long as it is a means capable of evacuating the inside of the first chamber 100a.

The gas supply member 220 may include a supply pipe 221 connected to the first chamber 100a and a valve 222 installed in the supply pipe 221 to control communication between the supply pipe 221 and the first chamber 100a. have.

Hereinafter, for convenience of explanation, a connecting pipe connecting the valve of the gas supply member 220 connected to the first chamber 100a to the first valve 222, the first chamber 100a, and the second chamber 100b ( The valve installed in 300) is called a second valve 400 .

The supply pipe 221 may have an internal space through which the gas may pass, and may have one end and the other end open. In this case, one end of the supply pipe 221 may be connected to the first chamber 100a so that the inside thereof communicates with the inside of the first chamber 100a.

In addition, the other end of the supply pipe 221 may be exposed to the atmosphere outside the first chamber 100a or may be connected to a separate gas storage unit. Here, an inert gas such as argon (Ar) or nitrogen (N ₂ ) or air (air) may be stored in the gas storage unit. Of course, the gas stored in the gas storage unit is not limited to the above-described example, and may be supplied into the first chamber 100a to increase the pressure inside the first chamber 100a, and various types of gases that do not damage the electronic device may be used. Gas may be used.

The first valve 222 is installed in the supply pipe 221 to control gas supply into the first chamber 100a. That is, when the first valve 222 is opened, the gas provided from the outside of the supply pipe 221 may pass through the supply pipe 221 to be supplied into the first chamber 100a. Accordingly, the pressure inside the first chamber 100a may increase. At this time, the gas supplied into the first chamber 100a through the first supply pipe 221 may be external air or a gas provided from a gas supply unit. That is, when the other end of the supply pipe 221 is provided to be exposed to the outside, air may flow into the other end of the supply pipe 221 and move, and then move into the first chamber 100a through one end. As another example, when the other end of the supply pipe 221 is connected to the gas storage unit, the gas stored in the gas storage unit flows into the other end of the supply pipe 221 and moves, and then passes through one end inside the first chamber 100a. can be moved to

The supply of gas into the first chamber 100a using the gas supply member 220 as described above is, after the test on one test object S is finished, the next test on the test object S. It may be carried out to prepare the environment. That is, when the test on one test object S is finished and the one test object S is taken out from the second chamber 100b, the gas is introduced into the first chamber 100a using the gas supply member 220 . to supply At this time, for example, the gas may be supplied so that the pressure inside the first chamber 100a becomes atmospheric pressure. Thereafter, for a test on the next test object S, the pump 210 is operated again to lower the pressure of the first chamber 100a.

The first pressure sensor 500a measures or senses the pressure inside the first chamber 100a. In addition, the pressure measured by the first pressure sensor 500a may be transmitted to the monitoring unit 600 and the control unit 700 . As the first pressure sensor 500a, any type of sensor may be used as long as it can measure the pressure inside the first chamber 100a.

The second chamber 100b has an internal space in which the test object S can be accommodated, and the internal space is provided to have a smaller volume than the first chamber 100a. In this case, the volume of the second chamber 100b may be 5% to 30% of the volume of the first chamber 100a. Preferably, the volume of the second chamber 100b may be 5% to 15% of the volume of the first chamber 100a, and more preferably 8% to 11%.

To explain with a more specific example, the second chamber 100b may be a hexahedron having a quadrangular cross-section. Also, the second chamber 100b may have a hexahedral shape having a horizontal length of 25 cm (250 mm), a vertical length of 25 cm (2500 mm), and a height of 25 cm (250 mm). However, the shape of the second chamber 100b is not particularly limited, and may be provided in a circular shape, an oval shape, and various polygonal shapes. That is, the second chamber 100b may be provided in any shape as long as the volume of its internal space is 30% or less smaller than that of the first chamber 100a.

On the other hand, when the volume of the internal space of the second chamber 100b is larger than that of the first chamber 100a or exceeds 30% of the volume of the first chamber 100a, the pressure of the second chamber 100b is changed. Therefore, the test conditions may not be satisfied. That is, when the pressure of the second chamber 100b is decreased by opening the second valve 400, the pressure change does not occur within the reference time, or the pressure in the second chamber 100b does not reach the target pressure within the reference time. Otherwise, the difference in pressure change changed within the reference time may be less than the reference pressure difference. Accordingly, the volume of the second chamber 100b is provided to be 30% or less of the volume of the first chamber 100a.

A hole through which the cable C can pass may be provided at one end of the second chamber 100b. In addition, a sealing member installed to surround the periphery of the hole and the cable C may be installed outside the second chamber 100b. Accordingly, the inside of the second chamber 100b may be blocked from the outside by the sealing member.

The cable C passes through a passage provided in the second chamber 100b and is installed such that at least a part thereof is inserted into the second chamber 100b. That is, the cable C may have one end connected to the test object S disposed inside the second chamber 100b, and the other end connected to a device installed outside the second chamber 100b.

The cable C applies power or power for driving to the electronic device, or applies a command signal for driving or performing a function to the electronic device, or receives a value output from the electronic device in the second chamber 100b. It may be transmitted to an external device. In addition, a plurality of cables C may be provided to be connected to an electronic device disposed inside the second chamber 100b.

The second pressure sensor 500b measures or senses the pressure inside the second chamber 100b. And the pressure measured by the second pressure sensor 500b may be transmitted to the monitoring unit 600 and the control unit 700 . As the second pressure sensor 500b, any type of sensor may be used as long as it can measure the pressure inside the second chamber 100b.

The connecting pipe 300 has an internal space through which the gas can move, and may have both ends in the extension direction, that is, one end and the other end open. The connection pipe 300 is installed to connect the first chamber 100a and the second chamber 100b. That is, one end of the connecting pipe 300 is connected to the first chamber 100a and the other end is connected to the second chamber 100b. At this time, one end of the connecting pipe 300 communicates with the inside of the first chamber 100a, and the other end is installed in communication with the second chamber 100b.

The second valve 400 is installed in the connection pipe 300 to control communication between the first chamber 100a and the second chamber 100b. The second valve 400 may be installed on the extension path of the connecting pipe 300 to control communication between the first chamber 100a and the second chamber 100b, and any type of valve may be used.

When the second valve 400 installed in the connection pipe 300 is closed, the first chamber 100a and the second chamber 100b do not communicate with each other by the closed second valve 400 . Accordingly, the gas in the first chamber 100a cannot move to the second chamber 100b, and the gas in the second chamber 100b cannot move to the first chamber 100a. Conversely, when the second valve 400 is opened, the first chamber 100a and the second chamber 100b communicate with each other. Accordingly, the gas in the first chamber 100a may move to the second chamber 100b or the gas in the second chamber 100b may move to the first chamber 100a. In this case, the movement direction of the gas may be determined according to the pressure difference between the first chamber 100a and the second chamber 100b. That is, gas may move from a chamber with a high pressure to a chamber with a low pressure.

In the embodiment, the pressure of the second chamber 100b is lowered by using the connection pipe 300 and the second valve 400 as described above. More specifically, first, the pump 210 of the pressure adjusting unit 200 is operated in a state in which the second valve 400 is closed to lower the pressure inside the first chamber 100a. At this time, the pump is operated so that the internal pressure of the first chamber 100a becomes a preset target pressure, and the inside of the second chamber 100b may be at a pressure higher than the target pressure of the first chamber 100a, for example, at atmospheric pressure. . When the first chamber 100a is lowered to the target pressure, the second valve 400 is opened. At this time, since the pressure of the second chamber 100b is higher than that of the first chamber 100a, the gas inside the second chamber 100b passes through the connection pipe 300 and moves to the first chamber 100a. According to the movement of the gas, the pressure of the second chamber 100b is lower than that before the second valve 400 is opened.

In this way, as the pressure inside the second chamber 100b is lowered, the test object S disposed inside the second chamber 100b is exposed to a pressure change environment. Thereafter, the test is performed on the test object (S) that has been exposed to the pressure change environment. Accordingly, it is possible to check the driving state of the test object S according to the pressure change, that is, the normal driving or the abnormal driving state.

In this way, without directly connecting the pump 210 to the second chamber 100b, lowering the pressure of the second chamber 100b by using the first chamber 100a having a large volume can quickly This is to lower the pressure of (100b).

More specifically, the electronics installed in the fighter must operate normally when the test conditions described in MIL-STD-810 are performed. For example, in MIL-STD-810, test conditions for pressure, pressure change time, etc. for performing a test on an object are presented. In this case, the pressure change time suggested by MIL-STD-810 may be, for example, 0.6 seconds or less. More specifically, MIL-STD-810 suggests a test condition in which the time required to decrease from the first pressure to the second pressure is 0.6 seconds or less. In addition, MIL-STD-810 suggests a condition for the magnitude of the pressure change for a time of 0.6 seconds or less, and the magnitude of the pressure change may be 0.5 psia or more. In addition, MIL-STD-810 suggests pressure conditions for testing electronic devices, and the pressure conditions may be 0.8 psia or less, preferably 0.5 psia or less. And, the test conditions as described above presented in MIL-STD-810 may be determined according to the altitude change rate of the fighter, the altitude at which the fighter flies, and the like.

Therefore, in setting the test conditions for testing the subject S, it is necessary to set the test conditions to satisfy the test conditions presented in the MIL-STD-810. That is, after opening the second valve 400 installed in the connection pipe 300 , the 'target pressure', which is the pressure condition when performing the test on the test object S, the pressure in the second chamber 100b is the target. A 'reference time', which is a target time taken to reach the pressure, may be set as a test condition. Also, a 'reference pressure difference', which is a difference between the pressure of the second chamber 100b before opening the second valve 400 and the target pressure, may be set as the test condition.

In this case, the target pressure may be set to 0.8 psia or less, preferably 0.5 psia or less, the reference time may be set to 0.6 seconds or less, and the reference pressure difference may be set to 0.5 psia or more.

The controller 700 controls the operation of at least one of the pump 210 and the second valve 400 according to the pressure measured by the first pressure sensor 500a. To this end, a first target pressure for the first chamber 100a is set in the controller 700 . Also, a second target pressure, which is a target pressure for the second chamber 100b, is set in the controller 700 . And when the pressure measured by the second pressure sensor 500b reaches the second target pressure, the controller 700 may generate an alarm.

Here, the first target pressure may be a pressure that allows the pressure of the second chamber 100b to become the second target pressure within a reference time when the second valve 400 is opened. The first target pressure may be determined according to at least one of a volume of each of the first and second chambers 100a and 100b, and a length and diameter of the connecting pipe 300 . Also, the first target pressure may be obtained through a plurality of experiments. In this case, the first target pressure input or set to the controller 700 may be, for example, 0.4 psia or less, preferably 0.3 or less, and more preferably 0.15 or less.

And, the control unit 700 controls the operation of the pump 210 according to the pressure measured by the first pressure sensor (500a). That is, the controller 700 controls the operation of the pump 210 so that the pressure measured by the first pressure sensor 500a becomes the first target pressure. Also, when the pressure measured by the first pressure sensor 500a reaches the first target pressure, the controller 700 stops the operation of the pump 210 .

In making the pressure of the first chamber 100a become the first target pressure, the controller 700 may control the operation of the pump 210 so that the pressure continues to decrease over time. In other words, the control unit 700 may control the operation of the pump 210 so that the pressure in the first chamber 100a is not maintained at a predetermined pressure for a predetermined time, and the pressure is continuously reduced over time. have. To explain this as an example, when the first target pressure is 0.1 psia, the controller controls the pump 210 until the pressure in the first chamber 100a measured by the first pressure sensor 500a decreases to 0.1 psia. control the operation of At this time, the control unit 700 controls the operation of the pump 210 so that the pressure is continuously reduced over time, and when the pressure measured by the first pressure sensor 500a reaches 0.1 psia, the operation of the pump 210 is to stop

Of course, the present invention is not limited thereto, and in making the pressure in the first chamber 100a become the first target pressure, the control unit 700 has a time period in which the pressure in the first chamber 100a is maintained at the predetermined pressure for a predetermined time. to control the operation of the pump 210 . In other words, the controller 700 may control the operation of the pump 210 so that the pressure of the first chamber 100a is decreased in a stepwise manner.

To describe this as an example, when the first target pressure is 0.3 psia, the control unit 700 pumps the pump until the pressure in the first chamber 100a measured by the first pressure sensor 500a reaches 0.3 psia. Controls the operation of 210 . In this case, the controller 700 may control the operation of the pump 210 so that the pressure of the first chamber 100a is decreased in a stepwise manner. For example, the control unit 700 first operates the pump 210 until the pressure of the first chamber 100a, which is atmospheric pressure, becomes 1.2 psia. Then, the pressure is maintained at 1.2 psia for a predetermined time. Next, the pump 210 is operated so that the pressure of the first chamber 100a is from 1.2 psia to 0.7 psia, and when the pressure is 0.7 psia, it is maintained for a predetermined time. Thereafter, the pump 210 is operated so that the pressure of the first chamber 100a is changed from 0.7 psia to 0.3 psia, which is the first target pressure. As such, the control unit 700 may control the operation of the pump 210 so that the pressure of the first chamber 100a is changed stepwise to atmospheric pressure (14.7 psia), 1.2 psia, 0.7 psia, or 0.3 psia.

Also, a second target pressure may be input or set to the controller 700 . In this case, the second target pressure is a target pressure of the second chamber 100b for creating a test environment of the object S, and as described above, may be 0.8 psia or less, preferably 0.5 psia or less.

And, when the pressure of the second chamber 100b measured by the second pressure sensor becomes the second target pressure, the controller 700 may generate an alarm. And when an alarm is generated, the operator can conduct a test on the test object (S).

2 is a flowchart illustrating a test method of a test object using a test apparatus according to an embodiment of the present invention.

Hereinafter, a test method according to an embodiment of the present invention will be described with reference to FIGS. 1 and 2 . In this case, it will be described as an example that the first target pressure is 0.1 psia and the second target pressure is 0.44 psia.

First, the pressure inside the first chamber 100a in the atmospheric pressure (14.7 psia) state is adjusted to be the first target pressure, that is, 0.1 psia (S10). To this end, the pump 210 is operated while measuring the pressure inside the first chamber 100a in real time with the first pressure sensor 500a. That is, the control unit 700 controls the operation of the pump 210 according to the pressure measured from the first pressure sensor 500a, and at this time, the operation of the pump 210 is adjusted so that the measured pressure becomes the first target pressure. .

And, while the pressure inside the first chamber 100a is adjusted in this way, the test object S is charged into the second chamber 100b (S20). The loading of the test object S into the second chamber 100b may be performed at any time before the second valve 400 is opened. That is, while the internal pressure of the first chamber 100a is adjusted to the first target pressure, before the pump 210 connected to the first chamber 100a is operated, the pressure of the first chamber 100a is set to the first target pressure. The test object S may be charged into the second chamber 100b at any one time point after the pressure is reached.

And, when the pressure measured by the first pressure sensor 500a reaches the first target pressure and the test object S is charged in the second chamber 100b, the control unit 700 controls the operation of the pump 210 stops and opens the second valve 400 (S30). Before opening the second valve 400 , the pressure of the second chamber 100b was higher than the first target pressure, for example, atmospheric pressure. Accordingly, when the second valve 400 is opened, the gas in the second chamber 100b moves to the first chamber 100a through the connection pipe 300 , and accordingly, the pressure in the second chamber 100b decreases. . At this time, the pressure of the second chamber 100b may reach the second target pressure of 0.44 psia within the reference time, that is, 0.6 seconds. That is, in the second chamber 100b, the pressure of 14.26 psia decreases within 0.6 seconds after the second valve 400 is opened to reach the second target pressure.

In this way, the pressure in the second chamber 100b is reduced so that a difference of 0.5 psia or more occurs within 0.6 seconds, which is the reference time, and the second target pressure, 0.44 psia, can be reached, the volume of the second chamber 100b This is because is less than 30% of the volume of the first chamber 100a, and the volume of the first chamber is 80,000 cm ² to 200,000 cm ² .

The pressure of the second chamber 100b may be measured by the second pressure sensor 500b , and the pressure measured by the second pressure sensor 500b may be transmitted to the monitoring unit 600 and the control unit 700 . . The control unit 700 generates an alarm when the pressure measured by the second pressure sensor 500b becomes the second target pressure.

When an alarm is generated in the control unit 700, the operator performs a test on the subject S (S40). To this end, at least one of power and a command signal for driving the electronic device is input using a cable (C) connected to the electronic device. Thereafter, it is determined whether the electronic device operates normally.

For example, the electronic device, which is the object under test (S) accommodated inside the second chamber 100b, when a fire occurs in the engine of a fighter or a missile is launched, whether a fire has occurred and whether a missile has been launched by voice or It may be an output device. In this case, the operator inputs, for example, a fire signal to the test object S inside the second chamber 100b using the cable C. Then, the operator checks whether a voice or an alarm notifying the occurrence of a fire is generated from the electronic device.

At this time, when a voice or an alarm notifying the occurrence of a fire is generated from the electronic device, it is determined that the electronic device operates normally. Through this, it can be confirmed that the electronic device can be normally driven in a pressure change environment such as the above-described test conditions. That is, it can be confirmed that the electronic device can be normally driven in a pressure change environment in which a rapid pressure change of 0.5 psia or more occurs within 0.6 seconds, and the electronic device can be normally driven under the second target pressure of 0.44 psia.

However, when a voice or an alarm notifying the occurrence of a fire is not generated from the electronic device, it is determined that the electronic device does not operate normally. Through this, it can be confirmed that the electronic device cannot be normally driven in a pressure change environment such as the above-described test conditions. That is, it can be confirmed that the electronic device cannot be normally driven in a pressure change environment in which a rapid pressure change of 0.5 psia or more occurs within 0.6 seconds, and the electronic device cannot be normally driven under the second target pressure of 0.44 psia.

As described above, in the embodiment, the volume of the second chamber 100b in which the test object S is accommodated is reduced, and the second chamber 100b is used by using the first chamber 100a having a larger volume than the second chamber 100b. ) to adjust the pressure. Accordingly, the pressure of the second chamber 100b may be rapidly changed. That is, the pressure of the second chamber 100b may be rapidly changed to match the pressure change according to the altitude of the fighter.

In other words, it is possible to adjust or simulate the pressure of the second chamber 100b close to the actual pressure change rate according to the altitude change rate of the fighter. Therefore, the test can be performed by exposing the test object (S) to a condition that is close to or conforms to the rate of change of pressure according to the altitude of the fighter. Accordingly, in determining whether the electronic device, which is the test object (S), satisfies the standards required by the fighter, its reliability can be improved.

100a: first chamber 100b: second chamber
210: pump 220: gas supply member
221: supply pipe 222: first valve
300: connection pipe 400: second valve
500a: first pressure sensor 500b: second pressure sensor

Claims (11)

As a test device that creates a test environment to test an object to be tested, which is an electronic device mounted on an aircraft,
a first chamber having an inner space;
a pump connected to the first chamber to adjust the pressure inside the first chamber;
a second chamber capable of accommodating the test object and having an internal space of a smaller volume than that of the first chamber;
a connection pipe installed to connect between the first chamber and the second chamber;
a valve installed on the connecting pipe to control communication between the first chamber and the second chamber;
a first pressure sensor installed in the first chamber to measure the pressure of the first chamber;
a second pressure sensor installed in the second chamber to measure the pressure of the second chamber; and
a control unit for controlling the operation of at least one of the pump and the valve according to the pressure measured by the first pressure sensor; including,
A first target pressure and a second target pressure are set in the control unit,
The first target pressure set in the control unit is set to a pressure at which the pressure of the second chamber reaches a second target pressure within a preset reference time after the first chamber and the second chamber are communicated. The method according to claim 1,
The volume of the second chamber is 30% or less of the volume of the first chamber. delete The method according to claim 1,
The control unit controls the operation of the pump so that the pressure measured by the first pressure sensor becomes a first target pressure,
When the pressure measured by the first pressure sensor reaches a first target pressure, the control unit stops the operation of the pump and opens the valve. 5. The method according to claim 4,
The control unit generates an alarm when the pressure measured by the second pressure sensor reaches a second target pressure. 6. The method according to any one of claims 1, 2, 4 and 5,
and a gas supply member connected to the first chamber to supply gas into the first chamber. A test method for testing the driving state of the test object by using an electronic device mounted on an aircraft as a test object,
setting a first target pressure;
adjusting the inside of the first chamber to a first target pressure by evacuating the inside of the first chamber;
loading the test object into a second chamber provided separately from the first chamber;
adjusting the pressure of the second chamber by communicating between the first chamber and the second chamber when the pressure of the first chamber reaches a first target pressure; and
When the pressure of the second chamber reaches a second target pressure, the process of confirming whether the test object accommodated in the second chamber is normally driven;
The first target pressure is set as a pressure at which the pressure of the second chamber reaches a second target pressure within a preset reference time after the first chamber and the second chamber are communicated. delete 8. The method of claim 7,
The reference time is 0.6 seconds or less, and the second target pressure is 0.8 psia or less. 10. The method of claim 9,
The first target pressure is set such that the pressure of the second chamber decreases by more than a preset reference pressure difference after the first chamber and the second chamber are communicated. 11. The method of claim 10,
The reference pressure difference is 0.5 psia or more.

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