KR200489907Y1 - Flame influence test apparatus for a seeker dome - Google Patents

Abstract

According to one embodiment of the present invention, a searcher dome flame impact test apparatus includes: a vertical support portion supported from the ground and extending in a direction perpendicular to the place name; A horizontal support extending in a direction horizontal to the ground and connected to the vertical support and movable in a vertical direction in which the vertical support extends; And at least one glass holder connected to the horizontal support and movable in a horizontal direction in which the horizontal support extends.

Description

Exploratory Dome Flame Impact Test Device {FLAME INFLUENCE TEST APPARATUS FOR A SEEKER DOME}

The following description relates to a searcher dome flame impact test apparatus.

1A to 1C are diagrams illustrating a process in which a missile is launched from a launch pad.

As shown in FIG. 1A, the distance between the missiles 2 is formed to be considerably narrow in the launch pad 3 where two or more missiles 2 are mounted.

At this time, when one of the missiles 2 is fired, passing through the front end of the missile 2, the rear end of the missile 2, the remaining guide missile 2 is a propulsion engine of the missile 2 fired as shown in FIG. Will be affected by the propulsion flame (21) generated from.

In addition, as shown in FIG. 1C, since the length of the propelling flame 21 is long even when the missile 2 completely leaves the launch pad, the front part of the remaining missile 2 is continuously affected by the propelling flame 21. In addition, the diameter of the propelling flame 21 adjacent to the remaining guided missile 2 may be the largest when the fired guided missile 2 deviates from the remaining guided missile 2 at regular intervals.

In most front missiles 2, a seeker is assembled. In particular, in the case of optical searchers, the seeker dome makes it impossible for the seeker to track a target because it is broken by flame pressure or soot and other foreign matter on the dome surface.

Guided missile (2) in which the propulsion flame (21) of the missile (2) leaving the launcher (3) from the launcher (3) equipped with two or more missiles (2) remains on the launcher (3) over time and distance. The extent to which the explorer's dome is different.

In order to verify the impact of the searcher dome due to the flame movement of the missile (2), a launch test should be carried out. , Aircraft, launch pads, etc.).

Since these launch tests are inefficient in terms of time and cost, there is a need for a test apparatus that can adequately simulate the effects of the propulsion engine's flames on the missile launch of missiles.

The background art described above is possessed or acquired by the inventors in the derivation process of the present invention, and is not necessarily a publicly known technology disclosed to the general public before the application of the present invention.

It is an object of one embodiment to provide a searcher dome flame impact test apparatus.

According to an embodiment, a searcher dome flame impact test apparatus includes: a vertical support part supported from a ground and extending in a direction perpendicular to the ground; A horizontal support extending in a direction horizontal to the ground and connected to the vertical support and movable in a vertical direction in which the vertical support extends; And at least one glass holder connected to the horizontal support and movable in a horizontal direction in which the horizontal support extends. The method of claim 1,

The glass holder may include: a glass plate protruding in a vertical direction from the horizontal support part, moving along the horizontal support part, and having one surface facing the direction in which the horizontal support part extends; A guide rail formed of two members each extending in an upward direction from both edges of one surface of the glass plate, the guide rail having grooves formed in an upward and downward direction on opposite surfaces thereof; And a shielding member which is movable in the vertical direction in a state of being fitted into the groove of the guide rail, and may shield one surface of the glass plate.

The glass holder may further include a pin puller installed outside the guide rail and having a pin insertable into the guide rail, wherein the pin puller inserts the pin into the guide rail. When the shielding member is prevented from falling from the upper side to the downward direction, and the pin puller retreats the pin, the shielding member may fall to shield a part of the glass plate.

According to an embodiment, a searcher dome flame impact test apparatus includes: a flame spraying apparatus spraying a flame in a direction parallel to a longitudinal direction of the horizontal support portion at a position adjacent to the glass holder; And a control unit configured to measure a flame spraying time of the flame spraying device, and to control the pin puller to adjust the movement of the pin, wherein the control unit is configured to control the pin puller from the time when the flame spraying device starts spraying. After the first setting time, the pin inserted into the guide rail may be retracted through the pin puller.

The glass holder has two, and may be spaced apart by a predetermined interval in the extending direction of the horizontal support.

The control unit recovers the fins of the glass holder spaced farther from the flame injector among the two glass holders after the second set time has elapsed from the time when the flame spraying device starts the flame injection. After the set time has elapsed, the fins of the glass holder disposed adjacent to the flame spraying device may be recovered, and the first set time may be shorter than the second set time.

The vertical support unit, the support is supported from the ground; And a vertical frame extending in the horizontal direction from the pedestal, wherein the horizontal support portion includes a vertical coupling portion that can move along the vertical frame and can be fixed to each other through screwing; And a horizontal frame fixed to the vertical coupling part and extending in a horizontal direction with respect to the ground, wherein the glass holder can move along the horizontal frame and can be fixed to each other through screwing. ; And a support for supporting the glass plate by protruding in a lateral direction horizontal to the ground from the horizontal coupling part.

According to the tester dome flame impact test apparatus according to an embodiment, since the flame impact of the searcher dome of the missile can be measured by a simple and simple configuration, it is efficient in terms of time and cost.

According to the searcher dome flame impact test apparatus according to an embodiment, the spacing of the glass holder is adjustable, it is possible to test the propulsion engine having various flame lengths.

According to the tester dome flame impact test apparatus according to an embodiment, as the shielding time of the shield member for shielding the glass plate can be adjusted, the missile is different in flame for a specific time before the missile is launched and completely exits the zone of the launch pad. It can simulate the effect on the system.

Figure 1a is a view showing a general guided missile is mounted on the launch pad.
FIG. 1B is a diagram showing the size and position of a flame generated from the fired missile after the missile is fired from the launch pad.
FIG. 1C is a diagram showing the size and position of the flames of the missile after the missile has flown away from the launch pad.
2 is a perspective view of a searcher dome flame impact test apparatus according to an embodiment.
3 is a front view of the searcher dome flame impact test apparatus according to an embodiment.
4 is a side view of the searcher dome flame impact test apparatus according to an embodiment.
5 is a plan view of a searcher dome flame impact test apparatus according to an embodiment.
6A is a perspective view illustrating a state before the glass plate of the glass holder according to the embodiment is shielded.
6B is a perspective view illustrating a shielded glass plate of the glass holder according to one embodiment.
7 is a block diagram of a searcher dome flame impact test apparatus according to an embodiment.

Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings. In adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are assigned to the same components as much as possible even though they are shown in different drawings. In addition, in describing the embodiment, when it is determined that the detailed description of the related well-known configuration or function interferes with the understanding of the embodiment, the detailed description thereof will be omitted.

In addition, in describing the components of the embodiment, terms such as first, second, A, B, (a), and (b) may be used. These terms are only for distinguishing the components from other components, and the nature, order or order of the components are not limited by the terms. If a component is described as being "connected", "coupled" or "connected" to another component, that component may be directly connected or connected to that other component, but between components It will be understood that may be "connected", "coupled" or "connected".

Components included in any one embodiment and components including common functions will be described using the same names in other embodiments. Unless stated to the contrary, the description in any one embodiment may be applied to other embodiments, and detailed descriptions thereof will be omitted in the overlapping range.

FIG. 2 is a perspective view of a searcher dome flame impact test apparatus according to an embodiment, FIG. 3 is a front view of the searcher dome flame impact test apparatus according to one embodiment, and FIG. 4 illustrates a searcher dome flame according to an embodiment. 5 is a side view of the impact test apparatus, FIG. 5 is a plan view of a searcher dome flame impact test apparatus according to one embodiment, and FIG. 6A is a perspective view showing a state before the glass plate of the glass holder according to the embodiment is shielded, 6B is a perspective view illustrating a shielded glass plate of a glass holder according to an embodiment, and FIG. 7 is a block diagram of a searcher dome flame impact test apparatus according to an embodiment.

2 to 7, the searcher dome flame impact test apparatus 1 according to an embodiment of the propulsion unit is formed from the propulsion engine of the missile 2 as the missile 2 is launched from the launch pad 3. The effect of flame 21 on the searcher dome of the remaining missile can be tested.

For example, the searcher dome flame impact test apparatus 1 is parallel to each other in a state adjacent to the flame injector 4 which injects the injection flame 41 for simulating the propelling flame 21 of the missile 2. Can be arranged.

For example, the flame injection device 4 may be a propulsion engine actually used for the missile 2, but may be a separate flame injection device capable of generating a flame similar to the propulsion engine of the missile 2.

For example, the searcher dome flame impact test apparatus 1 may include a vertical support 11, a horizontal support 12, a glass holder 13, a controller 14, and an input 15.

The vertical support part 11 may be a member supported from the ground and extending in a direction perpendicular to the ground.

For example, the vertical support 11 may include a pedestal 111, a horizontal adjustment screw 112, and a vertical frame 113.

The pedestal 111 may be a member disposed in parallel with the ground and supported from the ground. For example, the pedestal 111 may be composed of a frame of the "H" shape disposed parallel to the ground.

The horizontal adjustment screw 112 may be a screw installed at the end of the pedestal 111 facing the ground. For example, the horizontal adjustment screw 112 may be installed so that the horizontal surface of the wide diameter of the portion of the screw protrudes in the lower direction, that is, the direction toward the ground of the pedestal 111.

For example, the horizontal adjustment screw 112 may be installed at each edge of the pedestal 111, and as the rotation about the pedestal 111, the vertical height can be adjusted, each of the horizontal adjustment screw 112 By adjusting, the horizontal state of the pedestal 111 can be adjusted.

According to the horizontal adjustment screw 112, the searcher dome flame influence test apparatus 1 can be adjusted so that it may be arrange | positioned horizontally with the direction of the propulsion flame 21 of the injector 4.

The vertical frame 113 may be a frame protruding from the pedestal 111 in a direction perpendicular to the ground. For example, the vertical frame 113 may be formed of a plurality of frames spaced apart from the pedestal 111 at regular intervals, and the direction in which the plurality of vertical frames 113 are spaced apart from each other during the flame impact test is flame spraying. It may be parallel to the direction of the propelling flame 21 formed in the device 4.

For example, the vertical frame 113 may include a plurality of vertical position adjusting holes 1131.

The plurality of vertical positioning holes 1131 may be a plurality of holes formed spaced apart at regular intervals according to the length of the vertical frame 113. For example, the plurality of vertical positioning holes 1131 may be in contact with the vertical coupling holes 1211 of the vertical coupling portion 121 to be described later and may be fixed to each other through fastening members such as screws.

The horizontal support part 12 extends in a direction parallel to the ground and is connected to the vertical support part 11, and may be moved in a vertical direction in which the vertical support part 11 extends.

For example, the horizontal support part 12 may include a vertical coupling part 121 and a horizontal frame 122.

The vertical coupling portion 121 is connected to the vertical frame 113 and may move with respect to the vertical frame 113. For example, the vertical coupling portion 121 may be formed to surround the circumference of the vertical frame 113.

For example, the vertical coupling portion 121 may include a vertical coupling hole 1211. For example, the vertical coupling hole 1211 may be formed in the same direction as the direction in which the vertical positioning hole 1131 is formed in the vertical frame 113.

For example, when the vertical frame 113 is formed of a plurality of vertically arranged frames, the vertical coupling portion 121 may also be configured in plural, and may be connected to each of the plurality of vertical frames 113.

According to the vertical positioning hole 1131 and the vertical coupling hole 1211, the vertical coupling part 121 is connected to the vertical frame 113 so that the vertical coupling hole 1211 communicates with one of the plurality of vertical positioning holes 1131. After being moved along, it may be fixed through a fastening member such as a pin, bolt or screw, so that the horizontal support 12 may be adjusted in a direction perpendicular to the ground with respect to the vertical support 11.

The horizontal frame 122 may be a frame extending in a direction parallel to the ground with respect to the vertical coupling portion 121. For example, the horizontal frame 122 may be formed to extend from the vertical coupling portion 121 in a direction in which the flame spraying device 4 is disposed, that is, in a front direction (positive x-axis direction).

For example, the horizontal frame 122 may be formed of two parallel frames extending from the vertical coupling portion 121.

For example, the horizontal frame 122 may include a plurality of horizontal position adjusting holes 1221.

For example, the plurality of horizontal positioning holes 1221 may be a plurality of holes formed spaced apart at regular intervals along the length direction of the horizontal frame 122.

For example, the plurality of horizontal positioning holes 1221 may be fixed to each other through fastening members such as pins, bolts, or screws by contacting the horizontal coupling holes 1331 of the horizontal coupling portion 131, which will be described later. As a result, the glass holder 13 may adjust the fastening position in a direction horizontal to the ground with respect to the horizontal support part 12.

The glass holder 13 can be equipped with the glass for simulating a searcher dome. For example, to perform a searcher dome flame impact test, a flame spray device 4 may be disposed adjacent to the glass holder 13 to spray the spray flame 41.

For example, after the injection of the flame spraying device 4 is finished, the experimenter can determine whether the glass is broken, soot and foreign matter remaining in the glass, and measure the flame influence of the searcher dome.

For example, the glass holder 13 may be connected to the horizontal frame 122 and moved in the horizontal direction. For example, two glass holders 13 may be installed in a state spaced apart along the longitudinal direction of the horizontal frame 122. In this case, the glass holder 13 installed in the front (positive x-axis direction) may be referred to as the front glass holder 13a, and the glass holder 13 provided in the rear may be referred to as the rear glass holder 13b.

For example, the glass holder 13 may include a horizontal coupling portion 131, a support 132, a glass plate 133, a guide rail 134, a shield member 137, and a pin puller 135.

The horizontal coupling part 131 is connected to the horizontal frame 122 and may move with respect to the horizontal frame 122. For example, the horizontal coupling portion 131 may be formed to surround a portion of the circumference of the horizontal frame 122.

For example, the horizontal coupling part 131 may include a horizontal coupling hole 1331. For example, the horizontal coupling hole 1331 may be formed in the same direction as the direction in which the horizontal positioning hole 1221 is formed in the horizontal frame 122. For example, the horizontal positioning hole 1221 and the horizontal coupling hole 1331 may be formed above the horizontal frame 122 and the horizontal coupling part 131, respectively.

For example, when the horizontal frame 122 is formed of two frames spaced up and down, the horizontal coupler 131 may also be configured to be two and coupled to each horizontal frame 122.

The support 132 may protrude laterally from the horizontal coupling portion 131 to support the glass plate 133. For example, the support 132 may protrude in a direction parallel to the ground on the side of the horizontal coupling portion 131.

For example, the support 132 may protrude from the horizontal coupling portion 131 spaced apart vertically.

The glass plate 133 may include glass or a plate with glass attached thereto to the support 132. For example, the glass plate 133 may be supported by the support 132, and may be disposed to face the front side (positive x-axis direction).

For example, the glass plate 133 may be supported by the upper and lower sides of the glass plate 133 by two support members 132 spaced up and down, respectively. For example, a portion of the support 132 may have a shape inclined obliquely to the rear of the glass plate 133.

The guide rail 134 is a member formed along the edge in front of the glass plate 133, and can guide the vertical movement of the shielding member 137 to be described later. For example, the guide rail 134 may be directly supported through the support 132.

For example, the guide rail 134 may be formed of two mutually opposite members formed along the left and right edges of the glass plate 133, and may be formed to extend upwardly above the height of the upper end of the glass plate 133. have. For example, grooves into which the shielding member 137 may be fitted may be formed along the up and down directions on the surfaces of the two members facing each other.

For example, the guide rail 134 is formed by protruding one side of the lower end of the guide rail 134 onto a path through which the shield member 137 moves in order to prevent the shield member 137 from falling downward. Can be.

For example, a hole in which the pin 136 of the pin puller 135 to be described later may be formed at one side of the guide rail 134.

The shielding member 137 may be moved in the vertical direction by the guide rail 134. For example, the shielding member 137 may be moved up and down in a state of being fitted into a groove formed in the guide rail 134.

For example, when the shielding member 137 is maximally moved along the guide rail 134 in the upward direction, the shielding member 137 does not shield the glass plate 133, and the shielding member 137 is the guide rail 134. When the maximum movement in the downward direction along the), the shielding member 137 shields the front of the glass plate 133.

The pin puller 135 is installed at one side of the guide rail 134, and can insert and retrieve the pin 136 provided in the guide rail 134 into a path through which the shielding member 137 moves. For example, the pin puller 135 may be driven remotely through the control unit 14 to be described later, the movement of the pin 136 through its own drive source using electric, hydraulic pressure and the like.

For example, the pin puller 135 of the glass holder 13 installed at the front may be referred to as the first pin puller 135a, and the pin puller 135 of the glass holder 13 installed at the rear may be the second pin puller. It may be referred to as 135b.

For example, when the pin 136 of the pin puller 135 is inserted through the guide rail 134 while the shielding member 137 is spaced upwardly with respect to the glass plate 133, the shielding member 137 is shielded as shown in FIG. 6A. The member 137 may be supported by the pin 136 of the pin puller 135 and may not fall downward, and the glass plate 133 may be exposed to the front.

Subsequently, when the pin 136 of the pin puller 135 retreats from the guide rail 134, the shielding member 137 may drop downward to shield the glass plate 133.

Referring to FIG. 6A, the flame spray device 4 may be disposed adjacent to the glass holder 13 in a state parallel to the horizontal frame 122 to perform a flame impact test of the searcher dome. For example, the flame spraying device 4 may be disposed at the same height as the glass holder 13, and may be spaced apart in the horizontal direction.

For example, the injection direction of the injection flame 41 generated in the flame injection device 4 may be opposite to the direction in which the horizontal frame 122 extends (negative x-axis direction).

For example, when there are two glass holders 13, the position of the front glass holder 13a may be placed on the same line in the front and rear directions as the part where the injection flame 41 of the flame injector 4 starts, The position of the rear glass holder 13b may lie on the same line in the front-rear direction as the portion with the largest diameter of the injection flame 41.

According to the above structure, since the part where the injection flame 41 starts among the parts of the injection flame 41 formed in the flame injection apparatus 4 can be placed adjacent to the position of the front glass holder 13a, FIG. 1B As such, in the state where the rear end of the missile 2 to be fired passes through the front end of the missile 2, ie, the searcher dome, the portion where the propelling flame 21 of the missile 2 starts, that is, the propelling flame. The effect of the portion where the temperature of 21 is formed highest on the searcher dome can be simulated through the front glass holder 13a.

On the other hand, the position in the front-back direction (position along the x-axis direction) of the rear glass holder 13b is as much as the position in the front-back direction (position along the x-axis direction) and the "set interval" of the inlet part of the flame spraying apparatus 4 It may be arranged to be spaced apart.

Here, in the injection flame 41 generated in the "set interval" flame injection device 4, the distance from the portion where the injection flame 41 starts to the stop portion where the diameter of the injection flame 41 is formed the largest have.

For example, the shape and intensity of the injection flame 41 may vary depending on the type of the flame injection apparatus 4 used for the test. In particular, the shear portion and the injection portion where the flame starts among the portions of the injection flame 41 are sprayed. Since the spacing between the stopping portions where the diameter of the flame 41 is formed to be the largest can be different, the setting interval between the front glass holder 13a and the rear glass holder 13b is defined as the propulsion flame of the flame spraying device 4. 21) can be adjusted according to the shape.

According to the above structure, of the part of the injection flame 41 formed in the flame injection apparatus 4, the interruption part with the largest diameter of the injection flame 41 can be located adjacent to the position of the rear glass holder 13b. Therefore, as shown in FIG. 1C, in the state where the missile guided missile 2 is deviated from the launch pad 3 by a predetermined interval or more, the middle portion of the propelled flame 21 of the guided missile 2 having the largest diameter of the flame, In other words, the rear glass holder 13b shows the effect of the interruption of the propulsion flame 21 closest to the searcher dome of the missile 2 with the propulsion flame 21 of the missile 2 remaining on the searcher dome. Can be simulated through

The controller 14 may control a test process of the searcher dome flame impact test apparatus 1.

For example, the control unit 14 can adjust the shielding timing of the shielding member 137 by driving the pin puller 135 during the flame impact test of the searcher dome.

For example, the control unit 14 measures the time point at which the injection of the injection flame 41 of the flame injection device 4 starts, and after the "first set time" elapses from the time at which the injection of the flame starts, The pin 136 inserted into the guide rail 134 may be recovered through the pin puller 135.

Here, when the actual missile 2 is fired, the first set time may be a time when the searcher dome of the remaining missile 2 is exposed from the influence of the propulsion flame 21 formed in the missile 2.

According to the above structure, as shown in FIGS. 1A to 1C, as the missile 2 is fired and leaves the launch pad 3 at a high speed, the searcher dome of the remaining missile 2 is propelled by the first set time. We can simulate situation exposed to (21)

On the other hand, when the glass holder 13 is comprised from the front glass holder 13a and the rear glass holder 13b which are spaced apart by the set interval, the control part 14 will respond to the "first set time from the time when flame spraying started. After this, the pin 136 inserted into the guide rail 134 of the front glass holder 13a through the first pin puller 135a can be recovered, and the second set time After this, the pin 136 inserted into the guide rail 134 of the rear glass holder 13b can be recovered through the second pin puller 135b.

Here, when the actual missile 2 is fired, the second set time means that the diameter of the flame is the largest among the portions of the propelling flame 21 in which the searcher dome of the remaining missile 2 is formed in the missile 2. It may be the time exposed to the part.

For example, when the missile 2 is fired from the launch pad 3, the speed of the missile 2 is accelerated gradually out of the launch pad 3, so that, in fact, of the portion of the propulsion flame 21 where the searcher dome is fired. The time of exposure to the largest diameter stop may be shorter than the time of exposure to the beginning of the propulsion flame 21. Accordingly, the second set time may be shorter than the first set time.

According to the above structure, as shown in Figs. 1A to 1C, it may be possible to measure only the influence that the searcher dome is affected only by the interruption portion having the largest diameter among the portions of the propulsion flame 21.

The input unit 15 may be an interface that generates a control signal of the pin puller 135 from a user's manipulation and transmits the control signal to the controller 14.

For example, through the input unit 15, the user may lower the shield member 137 by controlling the pin puller 135 at a desired time point during the test.

Although embodiments have been described with reference to the accompanying drawings as described above, various modifications and variations are possible to those skilled in the art from the above description. For example, the described techniques may be performed in a different order than the described method, and / or components of the described structure, apparatus, etc. may be combined or combined in a different form than the described method, or may be combined with other components or equivalents. Appropriate results can be achieved even if they are replaced or substituted.

Therefore, other implementations, other embodiments, and equivalents to the claims are within the scope of the following claims.

Claims (7)

A vertical support supported from the ground and extending in a direction perpendicular to the ground;
A horizontal support extending in a direction horizontal to the ground and connected to the vertical support and movable in a vertical direction in which the vertical support extends; And
At least one glass holder connected to the horizontal support and movable in a horizontal direction in which the horizontal support extends,
The glass holder
A glass plate protruding from the horizontal support in a vertical direction and moving along the horizontal support, and having one surface facing the direction in which the horizontal support extends;
A guide rail formed of two members each extending in an upward direction from both edges of one surface of the glass plate, the guide rail having grooves formed in an upward and downward direction on opposite surfaces thereof; And
Searcher dome flame impact test apparatus including a shielding member that can move in the vertical direction in the state of being fitted into the groove of the guide rail, and can shield one surface of the glass plate.
delete The method of claim 1,
The glass holder,
A pin puller installed outside the guide rail and having a pin insertable into the guide rail;
The pin puller inserts the pin into the guide rail to prevent the shielding member from falling from the upper side to the lower side. When the pin puller retreats the pin, the shielding member falls to remove part of the glass plate. Searcher dome flame impact test apparatus, characterized in that the shielding.
The method of claim 3, wherein
A flame spraying apparatus for spraying a flame in a direction parallel to the longitudinal direction of the horizontal support portion at a position adjacent to the glass holder; And
A control unit for measuring the flame injection timing of the flame injection device, and controls the movement of the pin by controlling the pin puller,
And the control unit retracts the pin inserted into the guide rail through the pin puller after the first set time has elapsed from the time when the flame spraying device starts flame spraying.
The method of claim 4, wherein
The glass cradle is two, the searcher dome flame impact tester is spaced apart by a predetermined interval in the extended direction of the horizontal support.
The method of claim 5,
The control unit recovers the fins of the glass holder spaced farther from the flame injector among the two glass holders after the second set time has elapsed from the time when the flame spraying device starts the flame injection. After the set time has elapsed, the pins of the glass holder disposed adjacent to the flame spraying device are recovered,
And said first set time is shorter than said second set time.
The method of claim 1,
The vertical support portion,
A pedestal supported from the ground; And
A vertical frame extending in the horizontal direction from the pedestal,
The horizontal support portion,
A vertical coupling part movable along the vertical frame and fixed to each other by screwing; And
A horizontal frame fixed to the vertical coupling part and extending in a direction parallel to the ground;
The glass holder,
A horizontal coupling part movable along the horizontal frame and fixed to each other by screwing; And
Searching dome flame impact test apparatus further comprising a support for supporting the glass plate protruding laterally horizontal to the ground from the horizontal coupling portion.

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