KR101912541B1 - Apparatus for explosive atmosphere test - Google Patents

Abstract

According to the present invention, an apparatus for an explosive atmosphere test can perform Procedure I, II defined in the rules of the US armed forces (MIL-STD-810 w/change 1 method 511.6), and can test large-sized military supplies. Moreover, an explosive shock is not transmitted to a support frame and a hydraulic cylinder for lifting to provide great durability, and when a chamber is vertically moved, the apparatus is not shaken.

Description

[0001] Apparatus for explosive atmosphere test [

The present invention relates to an explosive atmospheric test apparatus and more specifically to a procedure I and II test specified in the Military Standard (MIL-STD-810 w / change 1 method 511.6) , The explosive impact is not transmitted to the support frame and the hydraulic cylinders for ascending and descending, and therefore the durability is high.

In general, munitions (eg electronic equipment) and components used in military aircraft must pass the Procedure I and II tests specified in the US Army's regulations (MIL-STD-810 w / change 1 method 511.6).

Procedure I is to test whether the munitions in the explosive atmosphere can be operated without causing an explosion. Procedure II tests whether the explosion or combustion reaction in the munitions received inside the case is blocked and propagated to the outside of the case. .

The explosive atmospheric testing device is intended to perform these Procedures I and II. MIL-STD-810 w / change 1 method 511.6 specifies the test conditions (temperature, pressure, time, etc.) of Procedures I and II as sentences, but the structure of the test apparatus that can implement it is not mentioned.

1 shows an example of a conventional explosive atmospheric test apparatus, which is disclosed in US 2,659,235 and the like. The explosive atmosphere testing apparatus 1 includes a body 2, a lid 3 and 5 for sealing both ends of the body 2, a device for supplying gas into the body 2, An apparatus for igniting the gas, and the like.

Inside the body portion 2, an airtight space is formed in which the test sample can be placed. The cover 3 is fixed to the body 2 by means of bolts 4 and the cover 5 is pivotally coupled to the body 2 by the hinge 6 in a horizontal direction. Therefore, the body portion 2 can be opened and closed by rotating the lid 5.

However, there is a problem that the explosive atmosphere testing apparatus 1 is not suitable for testing a large munitions product because the lid 5 is rotated in the horizontal direction to open and close. That is, in order to test large munitions, the body portion 2 and the lid 5 must be large. If the lid 5 is large, a heavy load is applied to the hinge member 6,

In addition, since the impact due to the explosion is directly transmitted to the hinge member 6 and the bolt 4, the durability is problematic when repeated tests are performed.

The present invention has been proposed to solve the above problems and provides an explosive atmospheric test apparatus capable of performing Procedure I and II tests prescribed in the US Army Regulations (MIL-STD-810 w / change 1 method 511.6) .

It is another object of the present invention to provide an explosive atmospheric test apparatus capable of performing Procedure I and II tests on large munitions.

Another object of the present invention is to provide an explosive atmosphere test apparatus having high durability because an explosion impact is not transmitted to a support frame and a hydraulic cylinder for ascending and descending.

It is still another object of the present invention to provide an explosive atmosphere test apparatus which is not shaken during the ascending and descending of a chamber.

The explosive atmosphere testing apparatus 100 according to a preferred embodiment of the present invention includes a chamber 10 having a side wall and a ceiling sealed and a lower portion opened; A bottom frame 30 provided below the chamber 10; And a vertical hydraulic cylinder 40 for vertically moving the chamber 10 up and down relative to the floor frame 30. [

The chamber 10 is brought into close contact with the bottom frame 30 to form a closed space S and the test piece T is installed in the space S or the test piece T in the space S, The chamber 10 is lifted and opened.

During the explosion test, the vertical hydraulic cylinder 40 and the support frame 60 are spaced apart from the chamber 10, so that the impact due to the explosion is not transmitted to the vertical lift hydraulic cylinder 40, .

The upper surface of the chamber 10 may be provided with an upper fastening hole 11 at a predetermined interval. A support member 41 is connected to the upper end of the vertical lift hydraulic cylinder 40 and a fastening rod 42 inserted into the upper fastening hole 11 may be installed in the support member 41.

Descending steel hydraulic cylinder 40 ascends and descends in a state where the connecting rod 42 is inserted into the upper fastening hole 11 so that the supporting member 41 moves up and down the chamber 10, And is spaced apart from the upper fastening hole (11).

The support frames 60 may be provided on both sides of the chamber 10, respectively. The support members 41 are supported by the support frames 60 on both sides in accordance with the expansion and contraction of the lifting and lowering hydraulic cylinders 40 And is slidable up and down.

It is preferable that the wires 50 and 51 are provided so as to connect the supporting members 41 on both sides so as to help the supporting members 41 on both sides to ascend and descend simultaneously and to prevent the chamber 10 from shaking in ascending and descending.

On the other hand, it is preferable that the upper portion of the connecting rod 42 is tapered so that the diameter becomes smaller toward the upper side. When the lower end of the chamber 10 is in close contact with the bottom frame 30 and the inner space S is sealed, the tapered portion is inserted into the upper fastening hole 11 and spaced apart from the upper fastening hole 11 The explosion test is performed in a state where the connecting rod 42 and the upper fastening hole 11 are spaced apart from each other.

The chamber 10 preferably has an outer diameter D of 900 mm to 1300 mm and a height H of 900 mm to 1300 mm and a wall thickness of 8 mm to 12 mm and is made of stainless steel and has a weight of 1200 Kg to 2200 Kg.

A plurality of guide rods 33 may be vertically installed on the bottom plate 31 to guide up and down movement of the chamber 10. At the lower end of the chamber 10, a lower fastening hole 19 is provided. By inserting the guide rod 33 into the lower fastening hole 19, the chamber 10 can be positioned in the correct position of the bottom plate 31.

The bottom frame 30 includes a bottom plate 31 which is brought into close contact with the lower end of the chamber 10; A support portion 35 for supporting the bottom plate 31 below the bottom plate 31; A plurality of buffer members 37 provided between the bottom plate 31 and the support unit 35 to buffer an explosion impact transmitted from the bottom plate 31; And an opening / closing part 36 provided on the bottom plate 31.

The opening and closing part 36 includes a plurality of opening and closing cylinders 36a rotatably mounted on the lower surface of the bottom plate 31; And a pivoting member 36c provided at the tip of the opening / closing cylinder 36a so as to be rotatable about a hinge point 36b provided on the lower surface of the bottom plate 31. [

When the opening and closing cylinder 36a is expanded, the pivoting member 36c is rotated in the forward direction to bring the lower end of the chamber 10 into close contact with the bottom plate 31. When the opening and closing cylinder 36a is contracted, And is turned in the reverse direction to release the adhesion.

A plurality of water pressure flanges 12 may be installed in the chamber 10. [

The sea pressure flange 12 includes an insertion tube 12a inserted into the ceiling of the chamber 10; A lower flange 12b horizontally installed at the upper end of the insertion tube 12a; A plurality of linear bushes 12c vertically installed on the lower flange 12b; A moving lid 12d installed to cover the insertion tube 12a and the lower flange 12b and installed so as to be able to slide up and down along the linear bush 12c; And an upper fixing plate 12e fixed to the upper end of the linear bush 12c.

When the pressure in the chamber 10 exceeds a predetermined pressure due to the explosion, the moving lid 12d moves upward to open the insertion tube 12a, and the upper fixing plate 12e moves up the moving lid 12d Limit.

In the present invention, the explosion test may be performed using n-hexane gas.

The explosive atmospheric test apparatus 100 according to the present invention may further include a sampling chamber 90 provided outside the chamber 10. The chamber 10 and the sampling chamber 90 may be connected to each other by an n-hexane supply pipe 91.

A vacuum pump 29a and a compressor 29b may be connected in parallel to the chamber 10 and the sampling chamber 90 so that the internal pressures of the chamber 10 and the sampling chamber 90 can be controlled in the same manner.

The bottom plate (30) is provided with a table (21) on which the test sample (T) is placed. The n-hexane gas is injected into the chamber 10 through the bottom plate 31 and then flows into the fan 22a through the bottom plate 31. The fan 22a is rotated by the motor 22, .

A heat ray 23a for controlling the temperature of the internal space S is provided on the inner surface of the side wall of the chamber 10 and a sea pressure flange 12 and a sight window 13 are installed on the ceiling of the chamber 10, The camera 24a can be installed on the upper side of the viewing window 13 so that the inside of the chamber 10 can be photographed through the window 13.

The explosive atmosphere test apparatus according to the present invention has the following effects.

First, the Procedure I and II tests specified in the US Army Regulations (MIL-STD-810 w / change 1 method 511.6) may be performed.

Second, the Procedure I and II tests can be performed on large munitions.

Third, the impact due to the explosion is not transmitted to the support frame and the hydraulic cylinders for ascending and descending, and therefore the durability is high.

1 is a front view showing an explosive atmosphere test apparatus according to the prior art;
FIG. 2 is a perspective view showing an explosive atmosphere testing apparatus according to a preferred embodiment of the present invention, showing a state in which a chamber is lowered. FIG.
3 is a view showing a state in which the chamber is raised;
4 is a schematic view showing the connection of the chamber and the peripheral device.
5 is a perspective view showing the chamber.
6 is a perspective view showing the structure of a waterproof flange;
7 is a longitudinal sectional view of a waterproof flange;
8 is a perspective view showing a chamber, a hydraulic cylinder for ascending and descending, a support member, and a wire.
9 is a view showing a structure of a fastening rod and an upper fastening hole.
10 is a perspective view showing a floor frame provided in the explosive atmosphere testing apparatus of FIG. 2;
11 is a view showing a fastening structure of a bottom frame and a chamber;
12 is a view showing an opening / closing part provided at a lower portion of the floor frame.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined. Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely examples of the present invention, and are not intended to represent all of the technical ideas of the present invention. Therefore, various equivalents It should be understood that variations can be made.

FIG. 2 is a perspective view showing an explosive atmosphere testing apparatus according to a preferred embodiment of the present invention, and FIG. 3 shows a state in which the chamber is raised. 4 is a view showing a connection relationship between the chamber and the peripheral device.

As shown in the figure, the explosive atmosphere testing apparatus 100 includes a chamber 10, a support frame 60 provided in the lateral direction of the chamber 10, a vertical hydraulic cylinder 40 provided in the support frame 60, A support member 41 for moving up and down the chamber 10 while being raised and lowered by a vertical hydraulic cylinder 40 and a bottom frame 30 provided below the chamber 10.

The chamber 10 has a cylindrical structure in which the side wall and the ceiling are sealed and the bottom is opened. 3 to 4, when the chamber 10 is lowered and brought into close contact with the bottom plate 31, the internal space S of the chamber 10 is sealed.

The chamber 10 can be changed in size depending on the size of the sample T. Preferably, the chamber 10 has an outer diameter D of 900 mm to 1300 mm, a height H of 900 mm to 1300 mm, a wall thickness of 8 mm to 12 mm, made of stainless steel, and a weight of 1200 Kg to 2200 Kg. When the weight of the chamber 10 is within the above range, it is advantageous that the chamber 10 itself can absorb explosion impact to some extent and have durability against explosion.

And, the lower end of the chamber 10 has an outwardly horizontally extending portion 18.

5, the chamber 10 includes a plurality of viewing windows 13 provided on the side wall and the ceiling, a plurality of pressure-sensing flanges 12 for relieving the explosion pressure, a connecting rod 42 An upper fastening hole 11 to be fastened and a lower fastening hole 19 for engagement with the bottom plate 31. [

The viewing window 13 is for viewing the inner space through the glass part and may be installed at a predetermined angle on the side wall and may be installed on the ceiling.

A plurality of waterproof flanges 12 are installed on the ceiling of the chamber 10. The seawater pressure flange 12 is for dissipating the explosion pressure and discharges the air and the combustion oxide in the internal space S expanded by the explosion to the outside.

6 to 7, the sea-pressure flange 12 includes an insertion tube 12a inserted in the ceiling, a lower flange 12b horizontally installed at the upper end of the insertion tube 12a, a lower flange 12b A moving lid 12d provided so as to cover the insertion tube 12a and the lower flange 12b and slidable upward and downward along the linear bush 12c, And an upper fixing plate 12e fixed to the upper end of the linear bush 12c.

When the pressure of the internal space S exceeds a predetermined pressure due to the explosion, the moving lid 12d is moved upward so that the insertion tube 12a is opened so that the air in the internal space S, And when the discharge is performed to some extent, the moving lid 12d is moved downward to cover the insertion tube 12a. At this time, the upper fixing plate 12e serves to limit the rising of the moving lid 12d.

On the other hand, the upper fastening hole 11 and the lower fastening hole 19 will be described with reference to the supporting member 41 and the bottom frame 30.

A camera 24a and a lighting device 24b are provided on the upper side of the chamber 10 and a heat ray 23a (heater) is provided on the inner side surface of the side wall of the chamber 10 at predetermined intervals.

The lighting device 24b illuminates the internal space S through the viewing window 13 of the ceiling. The camera 24a shoots the explosion state of the internal space S through the viewing window 13, and then transmits the image to a storage device (not shown in the figure).

The heat line 23a regulates the temperature of the internal space S. Preferably, the heat line 23a can control the temperature of the internal space S from room temperature to 100 占 폚.

A wire 25b for igniting the igniter 25a and an electric wire 26 for measuring the temperature of the internal space S are connected to the electric wire 23a for supplying electricity to the heat wire 23a, Passes through the side wall of the chamber 10 and is connected to the heat line 23a, the igniter 25a and the thermometer (not shown in the figure), respectively.

The support frames 60 are installed on both sides of the chamber 10 and support the hydraulic cylinders 40 for ascending and descending. As shown in Figs. 2 to 3 and the like, the support frame 60 can be formed by joining steel members of an H-section to each other.

The hydraulic cylinders 40 for ascending and descending are installed on the support frames 60 on both sides, and are supported by the support frame 60. 8 to 9, a support member 41 is provided at the upper end of the vertical lift hydraulic cylinder 40, and the support member 41 is installed so as to be slidable up and down along the support frame 60.

Therefore, when the lifting and lowering hydraulic cylinder 40 is extended or retracted, the support member 41 is guided by the support frame 60 and moved up and down along the support frame 60.

The supporting member 41 includes a pedestal 43, a connecting rod 42 vertically installed on the pedestal 43, and a guide roll 44 for allowing the supporting member 41 to slide along the supporting frame 60 do.

The fastening rod 42 can be inserted into the upper fastening hole 11 and fastened. When the ascending / descending hydraulic cylinder 40 is elevated, the clamping rod 42 is inserted into the upper clamping hole 11 and fastened. When the ascending and descending hydraulic cylinder 40 continues to rise, ) Lifts the chamber (10), so that the chamber (10) rises. When the ascending / descending hydraulic cylinder 40 descends and the chamber 10 descends and the lower end of the chamber 10 touches the bottom plate 31, when the ascending and descending hydraulic cylinder 40 continues to descend, And the engagement is released.

It is preferable that the fastening bar 42 has a shape tapering upward toward the upper side. In this case, the clamping rod 42 is lowered so that the lower end of the chamber 10 contacts the bottom plate 31 to close the chamber 10, so that the chamber 10 is supported only by the bottom plate 31 The upper portion of the fastening bar 42 can be kept inserted into the upper fastening hole 11 as shown in FIG. 9 even if the fastening rod 42 and the upper fastening hole 11 are disengaged from each other, It is advantageous for future operation.

On the other hand, the support members 41 on both sides can be connected to each other by the wires 50 (51). The wire 50 is provided so as to connect the upper end of the right support member 41 (right side in Fig. 8) and the lower end of the left support member 41 (left side in Fig. 8), and the wire 51 is connected to the left support member 41 And the lower end of the right and left support members 41 are connected to each other.

Since the wires 50 and 51 connect the support members 41 on the left and right sides via the pulley 46, the support members 41 on the left and right sides It is raised or lowered. In addition, it is possible to prevent the chamber 10 from swaying from side to side during ascending / descending.

The bottom frame 30 includes a bottom plate 31, a support 35 for supporting the bottom plate 31, a cushioning member 37 for absorbing an impact caused by the explosion, a chamber 10 and a bottom plate 31 (Not shown).

As shown in FIG. 10, the bottom plate 31 is formed as a circular plate so as to seal the lower portion of the chamber 10.

At the edge of the bottom plate 31, guide bars 33 are provided at predetermined angular intervals. When the chamber 10 is lowered, the guide rod 33 is inserted into the lower fastening hole 19 so that the chamber 10 can be seated in the correct position. It is preferable that the upper portion of the guide rod 33 is tapered upward so that the guide rod 33 can be easily inserted into the lower fastening hole 19 even if there is a slight error in the position of the chamber 10. [

An O-ring 32 for sealing may be provided at a portion corresponding to the lower horizontal portion 18 of the chamber 10. That is, the O-ring 32 is brought into close contact with the lower horizontal portion 18 of the chamber 10 to increase the airtightness of the inner space S.

A table 21 may be provided on the top surface of the bottom plate 31. The test piece T is placed on the table 21. A fan (22a) is installed between the table (21) and the bottom plate (31). The fan 22a is rotated by the motor 22. The n-hexane gas used for the explosion is supplied to the inner space S through the nozzle 27a provided on the bottom plate 31. [

Therefore, the n-hexane gas supplied to the inner space S through the nozzle 27a is diffused into the inner space S by the fan 22a. On the other hand, the n-hexane gas is exploded by the igniter 25a. The n-hexane gas remaining after the explosion is exhausted to the outside by the exhaust pipe 27b and then completely burned by the burner 27c, so that pollution of the surrounding environment can be prevented.

A vacuum pump 29a and a compressor 29b are connected to the inner space S through a bottom plate 31. [ The vacuum pump 29a and the compressor 29b are for adjusting the internal space S to have the same pressure as the test object altitude. The vacuum pump 29a discharges the air in the internal space S to the outside, ) Supplies air to the internal space (S).

The support portion 35 supports the bottom plate 31 and the buffer member 37 is installed between the bottom plate 31 and the support portion 35. The buffer member 37 is for absorbing an impact caused by explosion, and an elastic spring or the like may be used.

The opening and closing part 36 includes a cylinder 36a for opening and closing and a tilting member 36c.

A plurality of opening and closing cylinders 26a are rotatably mounted on the bottom surface of the bottom plate 31. [ The pivoting member 36c is rotatably installed at the tip of the opening / closing cylinder 36a. The swinging member 36c is rotated about the hinge point 36b provided on the lower surface of the bottom plate 31 in accordance with the expansion and contraction of the opening and closing cylinder 36a, And the plate 31 is engaged or disengaged. Specifically, when the opening / closing cylinder 36a is inflated, the pivoting member 36c is rotated in the normal direction so that the lower end horizontal portion 18 of the chamber 10 is tightly engaged with the bottom plate 31, The pivoting member 36c is rotated in the reverse direction to release the engagement.

Meanwhile, the explosive atmosphere testing apparatus 100 according to the present invention may further include a sampling chamber 90. The sampling chamber 90 is for testing whether or not the atmospheric condition of the chamber 10 is suitable for ignition. For example, if the igniter 25a of the chamber 10 has ignited but no explosion has occurred, And whether or not the explosion occurred due to failure of another device. The sampling chamber 90 may be installed inside the chamber 10, but may be provided outside the chamber 10. When the sampling chamber 90 is installed outside the chamber 10, the sampling chamber 90 is not affected by the explosion of the chamber 10, which is advantageous in that the service life is prolonged.

The sampling chamber 90 includes a detonation flange 12, an igniter 25a and a thermometer (not shown in the figure).

The sampling chamber 90 is connected to the chamber 10 by an n-hexane supply pipe 91. Specifically, the n-Hexane gas supplied to the inner space S through the nozzle 27a is diffused in the inner space S and then supplied to the sampling chamber 90 by the n-hexane supply pipe 91. Therefore, the chamber 10 and the sampling chamber 90 have the same atmospheric condition.

After the explosion, air and combustion oxides are discharged through an exhaust pipe 93 connected to the bottom, burned by a burner 27c, and then discharged into the atmosphere.

The vacuum pump 29a and the compressor 29b are connected in parallel to the chamber 10 and the sampling chamber 90 so that the parallel connection is effective to make the internal pressure of the chamber 10 and the sampling chamber 90 equal.

1, 100: explosive atmosphere test apparatus 2:
3, 5: Cover 4: Bolt
6: Hinge member
10: chamber 11: upper fastening hole
12: Sea pressure flange 12a: Insertion pipe
12b: Lower flange 12c: Linear Bushing
12d: moving lid 12e: upper fixing plate
13: perspective
18: lower horizontal part of the chamber 19: lower fastening hole
21: Table 22: Motor
22a: Fan 23a:
23b: wire connected to the hot wire 24a: camera
24b: Lighting device 25a: Igniter
25b: wire connected to the igniter 26: wire connected to the thermometer
27a: Nozzle
27b, 93: exhaust pipe 27c: burner
29a: Vacuum pump 29b: Compressor
30: bottom frame 31: bottom plate
32: O-ring 33: guide rod
35: support part 36: opening /
36a: cylinder for opening and closing 36b: hinge point
36c:
37: buffer member 40: hydraulic cylinder for ascending and descending steel
41: support member 42:
43: pedestal 44: guide roll
46: pulley 50, 51: wire
60: Support frame 90: Sampling chamber
91: n-Hexane supply pipe
H: height of chamber D: diameter of chamber

Claims (10)

A chamber 10 in which the side wall and the ceiling are sealed and the lower side is opened;
A bottom frame 30 provided below the chamber 10; And
And a vertical hydraulic cylinder (40) for vertically moving the chamber (10) up and down relative to the bottom frame (30)
The chamber 10 is brought into close contact with the bottom frame 30 to form a closed space S and the test piece T is installed in the space S or the test piece T in the space S, The chamber 10 is lifted to open,
During the explosion test, the hydraulic cylinders 40 for ascending and descending are separated from the chamber 10, so that the shocks caused by the explosions are not transmitted to the ascending / descending hydraulic cylinders 40,
The upper surface of the chamber 10 is provided with an upper fastening hole 11 at a predetermined interval,
A supporting member 41 is connected to the upper end of the vertical hydraulic cylinder 40. A connecting rod 42 inserted into the upper coupling hole 11 is provided in the supporting member 41,
Descending steel hydraulic cylinder 40 ascends and descends in a state where the connecting rod 42 is inserted into the upper fastening hole 11 so that the supporting member 41 moves up and down the chamber 10, And is spaced apart from the upper fastening hole (11). delete The method according to claim 1,
The support frame 60 is provided on both sides of the chamber 10 and the lift cylinder hydraulic cylinder 40 is installed on each of the support frames 60 on both sides of the support frame 41. The support member 41 is connected to the hydraulic cylinder 40 Is installed so as to be able to slide up and down along the support frames (60) on both sides in accordance with expansion and contraction,
The wires 50 and 51 are provided so as to connect the support members 41 on both sides so as to help the support members 41 on both sides to ascend and descend simultaneously and to prevent the chamber 10 from shaking during ascending and descending. Explosive Atmospheric Test System. The method of claim 3,
The upper portion of the connecting rod 42 is tapered so that its diameter becomes smaller toward the upper side,
When the lower end of the chamber 10 is in close contact with the bottom frame 30 and the space S is sealed, the tapered portion is inserted into the upper fastening hole 11 and spaced apart from the upper fastening hole 11 So that the explosion test is performed in a state where the connecting rod (42) and the upper fastening hole (11) are spaced apart from each other. 5. The method of claim 4,
The chamber 10 has an outer diameter D of 900 mm to 1300 mm and a height H of 900 mm to 1300 mm and a wall thickness of 8 mm to 12 mm and is made of stainless steel and has a weight of 1200 Kg to 2200 Kg,
A plurality of guide rods 33 are installed vertically in the bottom frame 30 to guide the up and down movement of the chamber 10,
The lower end of the chamber 10 is provided with a lower fastening hole 19 and the chamber 10 is positioned at a predetermined position of the floor frame 30 by inserting the guide rod 33 into the lower fastening hole 19 ≪ / RTI > A chamber 10 in which the side wall and the ceiling are sealed and the lower side is opened;
A bottom frame 30 provided below the chamber 10; And
And a vertical hydraulic cylinder (40) for vertically moving the chamber (10) up and down relative to the bottom frame (30)
The chamber 10 is brought into close contact with the bottom frame 30 to form a closed space S and the test piece T is installed in the space S or the test piece T in the space S, The chamber 10 is lifted to open,
During the explosion test, the hydraulic cylinders 40 for ascending and descending are separated from the chamber 10, so that the shocks caused by the explosions are not transmitted to the ascending / descending hydraulic cylinders 40,
The bottom frame (30)
A bottom plate (31) brought into close contact with a lower end of the chamber (10);
A support portion 35 for supporting the bottom plate 31 below the bottom plate 31;
A plurality of buffer members 37 provided between the bottom plate 31 and the support unit 35 to buffer an explosion impact transmitted from the bottom plate 31; And
And an opening / closing part (36) provided on the bottom plate (31)
The opening /
A plurality of opening and closing cylinders 36a rotatably provided on the lower surface of the bottom plate 31;
And a pivoting member 36c provided at the tip of the opening / closing cylinder 36a so as to be rotatable about a hinge point 36b provided on the lower surface of the bottom plate 31,
When the opening and closing cylinder 36a is expanded, the pivoting member 36c is rotated in the forward direction to bring the lower end of the chamber 10 into close contact with the bottom plate 31. When the opening and closing cylinder 36a is contracted, So as to rotate in the opposite direction to release the close contact. A chamber 10 in which the side wall and the ceiling are sealed and the lower side is opened;
A bottom frame 30 provided below the chamber 10; And
And a vertical hydraulic cylinder (40) for vertically moving the chamber (10) up and down relative to the bottom frame (30)
The chamber 10 is brought into close contact with the bottom frame 30 to form a closed space S and the test piece T is installed in the space S or the test piece T in the space S, The chamber 10 is lifted to open,
During the explosion test, the hydraulic cylinders 40 for ascending and descending are separated from the chamber 10, so that the shocks caused by the explosions are not transmitted to the ascending / descending hydraulic cylinders 40,
The chamber 10 is provided with a plurality of waterproofing flanges 12,
The sea pressure flange (12)
An insertion tube 12a inserted into the ceiling of the chamber 10;
A lower flange 12b horizontally installed at the upper end of the insertion tube 12a;
A plurality of linear bushes 12c vertically installed on the lower flange 12b;
A moving lid 12d installed to cover the insertion tube 12a and the lower flange 12b and installed so as to be able to slide up and down along the linear bush 12c; And
And an upper fixing plate 12e fixed to the upper end of the linear bush 12c,
When the pressure in the chamber 10 exceeds a predetermined pressure due to the explosion, the moving lid 12d moves upward to open the insertion tube 12a, and the upper fixing plate 12e moves up the moving lid 12d Wherein the atmospheric air is atmospheric air. 8. The method of claim 7,
The explosion test is performed using n-hexane gas,
A sampling chamber 90 is provided outside the chamber 10 and the chamber 10 and the sampling chamber 90 are connected to each other by an n-hexane supply pipe 91,
Characterized in that a vacuum pump (29a) and a compressor (29b) are connected in parallel to the chamber (10) and the sampling chamber (90) such that the internal pressure of the chamber (10) and the sampling chamber (90) Atmospheric test equipment. 8. The method of claim 7,
A table 21 on which the test sample T is placed is provided on the floor frame 30,
The n-hexane gas is injected into the chamber 10 through the bottom plate 31 of the bottom frame 30 after the fan 22a is rotated by the motor 22 on the lower side of the table 21 Is diffused by the fan (22a). 10. The method of claim 9,
A heat ray 23a for controlling the temperature of the internal space S is provided on the inner surface of the side wall of the chamber 10 and a sea pressure flange 12 and a sight window 13 are installed on the ceiling of the chamber 10, Wherein the camera (24a) is installed above the viewing window (13) so that the inside of the chamber (10) can be photographed through the window (13).

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