KR100914571B1 - Gas-collecting system for firing test - Google Patents

Abstract

The present invention relates to a gun test gas collection system, and more particularly, to a gun test gas collection system for collecting gas generated during a gun test of an aircraft or a helicopter. To this end, the gun test gas collection system according to the present invention includes a firing apparatus for performing a shooting operation, a gas collecting apparatus for collecting gas generated from the firing apparatus, and a delay time after the shooting by the firing apparatus is finished. It comprises a drive means for operating the gas collection device for a predetermined time. Accordingly, the gun test gas collection system according to the present invention has the effect of effectively collecting the gas generated and disappeared immediately after the gun test in the aircraft or helicopter.

Description

Gun-test gas collection system {GAS-COLLECTING SYSTEM FOR FIRING TEST}

The present invention relates to a gun test gas collection system, and more particularly, to a gun test gas collection system for collecting gas generated during a gun test of an aircraft or a helicopter.

If the gas produced after shooting in an aircraft or helicopter contains flammable substances or explosive substances, the aircraft or helicopter may cause a fire or explosion. Therefore, it is necessary to collect the gas generated after shooting from an aircraft or helicopter to analyze what gas component is contained. However, no attempt has yet been made on how to perform a gun test during an aircraft or helicopter flight and collect gas that has occurred momentarily and disappears into the air.

In general, the method for collecting gas in a room with less internal or external environmental factors, the gas lighter than air is collected in the upper substitution method, the heavier gas than the air is collected in the downward substitution method, but the outside air, such as flying an aircraft or helicopter In situations where the flow is very fluid, gas generated after the gun cannot be collected in the above manner.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a gun test gas collection system that can effectively collect the gas generated and disappeared immediately after the gun test in an aircraft or helicopter.

In order to achieve the above object, the gun test gas collection system according to the present invention includes a shooting mode setting unit for setting a shooting type, a triggering switch for outputting a signal for initiating shooting, and a delay for setting a delay time after the shooting ends. A power driver for outputting a time setting unit, a first drive signal for operating the launch device and a second drive signal for operating the gas collecting device, and a signal for informing the start of firing to operate the power driver for a predetermined time; It characterized in that it comprises a control unit to make.

As described above, the present invention has an effect that can effectively collect the gas generated and disappeared immediately after the gun test in the aircraft or helicopter using a gun test gas collection system. In addition, by analyzing the collected gas it is possible to prevent the fire or explosion accident of the aircraft or helicopter that may be caused by the harmful gas components after shooting.

1 is a block diagram of a gun test gas collection system according to the present invention.

2 is a circuit diagram of a power driver according to the present invention.

3 is a combined configuration of the shooting mode setting unit and the LED driver according to the present invention.

Figure 4 is a flow chart showing a gun test gas collection operation according to the present invention.

5 is an output timing diagram of the gun test gas collection system according to the present invention.

Figure 6 is a signal waveform diagram shown in the oscilloscope when performing a gun test gas collection operation according to the present invention.

** Explanation of symbols on the main parts of the drawing **

10: fire mode setting unit 20: trigger switch

30: delay time setting unit 40: power driver

50: LED driver 60: clock generator

70: control unit 80: power supply unit

90: voltage adjusting unit 100: power switch

200: gas collection device 300: launch device

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 shows a schematic diagram of a gun test gas collection system according to the present invention.

As shown in FIG. 1, the gun test gas collection system includes a firing mode setting unit 10 for setting a firing mode, a trigger switch 20 for starting a firing operation, and a delay time after the firing end. Delay time setting unit 30, the power driver 40 for operating the gas collection device 200 and the launch device 300, the LED driver 50 for operating a light emitting diode (LED), the clock generation to generate a system clock The unit 60, the control unit 70 for operating the power driver 40, the power supply unit 80 for supplying power to the system, the voltage adjusting unit 90 for adjusting the voltage supplied from the power supply unit 80, the power supply unit A power switch 100 for starting the power supply by 80, a gas collecting device 200 for collecting the gas generated after shooting, and a launching device 300 for performing the shooting operation.

The shooting mode setting unit 10 is a part for setting the shooting type. In the exemplary embodiment of the present invention, a rotary switch is used as the fire mode setting unit 10. However, the present invention is not limited thereto, and various types of switches or buttons may be used. Rotary switches are switches that switch electrical contacts by physical rotation, and change the state of a circuit by switching contacts.

In the embodiment of the present invention, there are five types of shooting modes, so that the user can set a desired shooting mode. To implement five different fire modes, use a 1 pole 5 position rotary switch. The five different fire modes consist of OFF, 0.5s, 1.0s, 2.0s and burst modes. The user selects the desired shooting mode by rotating the wheel of the rotary switch. In the OFF mode, the shooting operation is disabled. In each of the 0.5s, 1.0s, and 2.0s modes, the shooting is performed until the corresponding time. In the burst mode, the shooting is performed as long as the trigger switch 20 is pressed. to be.

The trigger switch 20 outputs a signal informing the controller 70 to start firing. In the embodiment of the present invention, the trigger switch 20 may be configured as a push button, but is not limited thereto, and other types of switches may be used. When the trigger switch 20 is turned on, a signal for notifying the start of fire is input to the controller 70, and a lamp (not shown) indicating the start of fire may be turned on at the same time. For the sake of safety, if the time for which the trigger switch 20 is pressed is shorter than the time set in the fire mode setting unit 10, the fire is performed only while the trigger switch 20 is pressed, and for a long time only for the set time. .

The delay time setting unit 30 is a portion for setting a delay time (Delay time) to delay a predetermined time before the start of the gas collection operation by the gas collection device 200 after the shooting by the launch device 300. The delay time is calculated in consideration of the time that the gas generated after the shooting ends are diffused into the launch device 300.

In the exemplary embodiment of the present invention, a dip switch is used as the delay time setting unit 30. However, the present invention is not limited thereto, and other types of switches or buttons may be used. A dip switch is a switch composed of a plurality of switches that are turned on / off and may indicate one specific state by an on / off combination of each switch. By using a 4-bit dip switch (four on / off switches), 16 (= 2 ⁴ ) delay times can be set. In the embodiment of the present invention, 0.6 s, 0.8 s, 1.0 s, etc. may be used as the delay time. Can be.

The power driver 40 outputs a first drive signal for operating the launch device 300 and a second drive signal for operating the gas collection device 200, respectively. When the power driver 40 receives the first control signal from the RA0 terminal of the controller 70, the power driver 40 outputs the first driving signal through the first terminal OUT to operate the launching device 300, and the controller 70. When the second control signal is received from the RA1 terminal, the second driving signal is output through the second terminals OUT1, OUT2, OUT3, OUT4, and OUT5 to operate the gas collecting device 200. The second driving signal output from the second terminal is simultaneously output to the gas collecting device 200.

2 shows a circuit diagram of the power driver 40.

As shown in Fig. 2, Fig. 2A shows a circuit diagram of the launch device driving part, and Fig. 2B shows a circuit diagram of the gas collecting device driving part. In FIG. 2A, when the launch device driving part receives the voltage 28 VDC from the power supply unit 80 and the first control signal is input from the RA0 terminal of the control unit 70, the transistors Q3 and Q4 are turned on. The first driving signal is output through the first terminal (Burst Limiter Clock Out). In FIG. 2B, when the gas collecting device driving part receives the voltage 28 VDC from the power supply unit 80 and the second control signal is input from the RA1 terminal of the control unit 70, the transistors Q1 and Q2 are turned on. The second driving signal is output through the second terminal (Gas Sampler Clock Out1-Out5). Here, the RTN terminals (Burst Limiter Clock RTN, Gas Sampler Clock RTN) included in each of the first terminal and the second terminal serve as a ground because the driving signal is a DC voltage.

The LED driver 50 operates an LED indicating the fire type set by the fire mode setting unit 10. LEDs corresponding to each type of fire exist, and the LED driver 50 turns on any one LED to indicate the type of fire.

3 illustrates the connection configuration of the shooting mode setting unit 10, the LED driver 50, and the LED in detail.

As shown in FIG. 3, the LED driver 50 is composed of a network resistor 50, and a plurality of LEDs (0.5 SEC, 1.0 SEC, 2.0 SEC, BURST) indicating the type of fire on the network resistor 50 are provided. It is connected. The rotary switch 10 is connected to any one LED and is connected to any one of the terminals RB0, RB1, RB2, and RB3 of the controller 70 while switching electrical contacts according to the user's selection of the shooting mode.

The controller 70 performs a function of operating the power driver 40 when a signal for initiating fire is input from the trigger switch 20. The controller 70 first receives the delay time from the delay time setting unit 30 and the fire mode from the fire mode setting unit 10, and then receives a signal indicating the start of fire from the trigger switch 20. The signal is output to the power driver 40. The first control signal is output during the shooting time according to the shooting mode to drive the power driver 40. Subsequently, when the shooting time according to the shooting mode elapses, the controller 70 outputs the second control signal to the power driver 40 after a predetermined delay time elapses. The second control signal is output during the gas collection time to drive the power driver 40.

The gas collection device 200 is a device that collects the gas generated after shooting in the launch device 300. The solenoid valve is installed in the gas collecting device 200, and the inside thereof maintains a vacuum state. Solenoid valve is a valve that can control the opening and closing of the pipe electrically by using the principle that the conductive wire is made into a compact and uniform cylindrical shape and a current flows to form a relatively uniform magnetic field inside the cylindrical shape. In the exemplary embodiment of the present invention, five solenoid valves are attached to the gas collecting device 200. When the solenoid valves are simultaneously opened by receiving the second drive signal from the power driver 40 in parallel and simultaneously, As a result, the gas existing in the outside is sucked in, so that the gas collection can be performed.

The launch device 300 is a device for performing shooting. The firing apparatus 300 receives the first driving signal from the power driver 40 and performs firing. The firing apparatus 300 receives the first driving signal for a time set by the shooting mode setting unit 10 to perform shooting.

In addition, the clock generator 60 generates a system clock necessary for the controller 70. In the embodiment of the present invention, the clock generator 60 supplies a 4KHz clock. The power supply 80 supplies a voltage to the gun test gas collection system. When the power switch 100 is turned on, the voltage of the power supply unit 80 and the voltage stepped down by the voltage adjusting unit 90 are supplied to each part. The 28-volt (VDC) voltage of the power supply unit 80 is applied to the power driver 40, the 5-volt (VDC) voltage stepped down in the voltage adjusting unit 90 is applied to the control unit 70 and the LED driver 50, Allow each part to work.

Figure 4 is a flow chart showing the gun test gas collection operation according to the present invention.

4, the gas collection operation in the gun test gas collection system will be described in detail.

First, the user sets the shooting type (0.5s, 1.0s, 2.0s, burst) in the shooting mode setting unit 10, and the delay time (0.6s, 0.8s, 1.0s) in the delay time setting unit 30. Set (S10). Next, when the trigger switch 20 is turned on (S20), a first control signal is output through the RA0 terminal of the controller 70 and input to the power driver 40. The first control signal remains on for a time according to the type of fire. The power driver 40 outputs the first driving signal to the launching device 300 while the first control signal is in the on state. When the first driving signal is input, the firing apparatus 300 starts shooting and continues shooting for a time when the first driving signal is input (S30). It is determined whether the shooting is terminated according to whether the first driving signal is input (S40), and when the input of the first driving signal is stopped, shooting is terminated, and a delay time is counted at the end of shooting to determine whether the delay time has elapsed ( S50). When the delay time elapses, the controller 70 outputs the second control signal to the power driver 40 through RA1. The second control signal remains on during the gas collection operation. The power driver 40 outputs the second driving signal to the gas collection device 200 while the second control signal is in the on state. When the second driving signal is input, the gas collecting device 200 collects the gas generated by the launching device 300 by simultaneously opening the plurality of solenoid valves (S60).

5 is an output timing diagram of the gun test gas collection system according to the present invention.

In FIG. 5, (a) is a timing diagram of a trigger switch, (b) is a timing diagram of a first drive signal (shooting drive clock), and (c) is a timing diagram of a second drive signal (gas valve drive clock). to be.

When the trigger switch 20 is turned on, the first drive signal is turned on after a predetermined time 64us has elapsed. The fire driving clock is turned on after a predetermined time elapses after the trigger switch is turned on because it takes time for the first control signal from the control unit 70 to be input to the power driver 40. When the firing driving clock is turned on for a predetermined time (0.5s, 1.0s, 2.0) and turns off, after a predetermined delay time (0.6s, 0.8s, 1.0s) elapses, the second driving signal is turned on. The gas valve driving clock is turned off after the gas collection operation is performed while the gas valve driving clock is on for a predetermined time (1,0s).

Figure 6 shows the signal waveform shown in the oscilloscope (Oscilloscope) when performing a gun test gas collection operation according to the present invention. The signal waveform of FIG. 6 is an oscilloscope when the gun test gas collection system is operated after connecting the launch device 300 to channel 1 (CH1) of the oscilloscope, connecting the gas collection device 200 to channel 2 (CH2), and the like. The waveform that appears in.

As can be seen from the waveforms of the channel 1 (CH1) and the channel 2 (CH2), the shooting is performed in the firing device 300 for a predetermined time (①), and after a certain delay time (②), It can be seen that gas collection is being performed in the gas collecting device 200 during ③).

Claims (13)

A shooting mode setting unit for setting the shooting type; A trigger switch that outputs a signal informing of the shooting start; A delay time setting unit for setting a delay time after the shooting ends; A power driver for outputting a first drive signal for operating the launch device and a second drive signal for operating the gas collection device, respectively; And a control unit for operating the power driver for a predetermined time when a signal for initiating the shooting is input. The method of claim 1, And the shooting mode setting unit sets a mode in which shooting is performed until the triggering switch is turned off. The method of claim 1, The shooting mode setting unit, the gun test gas collection system, characterized in that for setting a mode in which shooting is performed for a predetermined time. The method of claim 1, The shooting mode setting unit is a gun test gas collection system, characterized in that consisting of a rotary switch. The method of claim 1, The delay time setting unit is a gun test gas collection system, characterized in that consisting of a dip switch. The method of claim 1, And the power driver outputs a signal for opening the plurality of valves installed in the gas collecting device in parallel. The method of claim 1, And the control unit outputs a first control signal to the power driver for a predetermined time to operate the launching device for a predetermined time when a signal for initiating the shooting is input. The method of claim 1, And the control unit outputs a second control signal to the power driver for a predetermined time to operate the gas collection device for a predetermined time after the delay time has elapsed. The method of claim 1, A gun test gas collection system, characterized in that it further comprises a display for indicating the shooting type. A launch device that performs a shooting operation, A gas collection device for collecting gas generated in the launch device; Comprising a driving means for operating the gas collection device for a predetermined time after the delay time elapsed when the shooting by the launch device, And the driving means operates the gas collecting device to open the valve of the gas collecting device and suck the surrounding gas. The method of claim 10, And a delay time setting means for arbitrarily setting the delay time. delete In the gun test gas collection method of the gun test gas collection system provided with a shooting mode setting unit, delay time setting unit, trigger switch, control unit, power driver, launch device, gas collection device, (a) receiving a fire type from the fire mode setting unit and receiving a delay time from the delay time setting unit; (b) outputting a first control signal from the controller to the power driver when the trigger switch is turned on; (c) outputting a first drive signal to the launch device while the first control signal is on in the power driver; (d) initiating shooting when the first driving signal is input from the launching device and continuing shooting for a time when the first driving signal is input; (e) ending the shooting when the input of the first driving signal is stopped by the launching device, and determining whether the delay time has elapsed by counting the delay time at the end of the shooting; (f) outputting a second control signal from the controller to the power driver when the delay time elapses; (g) outputting a second drive signal to a gas collection device while the second control signal is on in the power driver; And (h) when the second driving signal is input from the gas collecting device, simultaneously opening a plurality of solenoid valves to collect gas generated in the launching device; Gun test gas collection method characterized in that it comprises a.