KR101031247B1 - bonding test device - Google Patents

Abstract

The present invention relates to a bonding test apparatus, and a pair of frames installed perpendicular to the bottom surface, rotatably installed on the top of the pair of frames and the bonding is carried out to generate air bubbles during adhesive application and adhesive curing The rotating table which can visually check the micro air generation process with the naked eye, the rotating shaft which protrudes from both ends of the rotating table to allow the rotating table to be rotated, and the rotating table can be fixed to maintain the attitude of the rotating rotating table. Posture fixation means. Therefore, according to the present invention, the air bubbles and the air generated during the application of the adhesive using the ABM device in the real-time monitoring of the micro-air generated during the curing of the adhesive in the electronic field to check the bonding quality problems with the naked eye to contribute to the optimization of the bonding quality There is.

ABM device, glue, adhesive, angle, adjustment

Description

Bonding test device

The present invention relates to a bonding test apparatus, and more particularly, has an electronic fine angle adjustment function for monitoring the bubble generation process of the adhesive according to the use of the ABM (Auto Bonding Machine) device when the cargo hold insulation construction of the LNG carrier It relates to a bonding test apparatus.

In general, liquefied natural gas (LNG) refers to a colorless transparent cryogenic liquid whose natural gas, which contains methane as its main component, is cooled to -163 ° C and its volume is reduced to one hundredth.

As such liquefied natural gas is used as an energy resource, an efficient transportation method that can transport a large amount from the production base to the destination of the demand site has been considered to use this gas as energy. LNG carriers have been developed to transport gas by sea.

By the way, the LNG carrier should be provided with a cargo hold (Cargo) that can store and store the liquefied natural gas liquefied in the cryogenic state, there was a lot of difficulties due to the very demanding conditions for such cargo hold.

That is, since LNG has a vapor pressure higher than atmospheric pressure and has a boiling temperature of about -162 ℃, in order to safely store and store such LNG, the cargo hold for storing the LNG is a material that can withstand ultra low temperatures, for example, For example, it must be made of aluminum steel, stainless steel, 35% nickel steel, etc., and must be designed with a unique insulation structure that is resistant to other thermal stresses and heat shrinkage and prevents heat intrusion.

Referring to the cargo hold insulation structure of a conventional LNG carrier with reference to the accompanying drawings as follows.

1 is a cross-sectional view showing a cargo hold insulation structure of a liquefied natural gas carrier according to the prior art. As shown, the bottom insulation panel 10 is fixed to the inner side of the hull 1 of the LNG carrier by an epoxy mastic 13 and a stud bolt 14. It is attached and fixed via 10a).

At this time, a rigid triplex 22 is interposed between the lower insulation panel 10 and the top insulation panel 20 to be bonded to each other. Meanwhile, when attaching the lower insulation panel 10 to the cargo hold wall, the lower insulation panel 10 may be inserted into a gap 40 formed between glass wool flat joints 18. ) Have a gap.

Then, the top bridge panel 28 is attached between the upper insulation panels 20, wherein the pleated triplex is used as the epoxy glue or the PU glue 24 on the rigid triplex 22 that is conventionally attached. 26: Supple triplex) is attached and the top bridge panel 28 is attached using epoxy glue or PU glue 24 thereon.

In addition, the upper insulation panel 20 and the upper portion of the top bridge panel 28 have the same plane, and a corrugated membrane 30 is attached to the same plane through the anchor strip 32. Cargo wall is complete. Here, the method of assembling the inner surface of the hull 1 and the lower insulation panel 10 of the LNG carrier further includes attaching the stud bolts 14 to the inner wall of the hull 1 by resistance welding, and insulating the lower insulation. The panel 10 is pre-formed with holes into which the stud bolts 14 can be inserted. Therefore, the assembly is completed by fastening the nut 14a to the stud bolt 14 and inserting the cylindrical foam plug 15 into the hole formed in the lower insulation panel 10.

On the other hand, since the epoxy glue or PU glue 24 used as an adhesive in the cargo hold structure of the liquefied natural gas carrier according to the prior art has a characteristic that is hardened over time in the state of mixing and heating the main material and the curing agent Application is carried out using a flexible heating pad or an ABM (Auto Bonding Machine) device.

Prior to the construction of this secondary barrier, the quality test process for adhesives is required. For this purpose, the quality of glue was tested after constructing a virtual hull or removing the triplex in the actual hull.

However, such a conventional test can not visually see the air bubbles and the formation of micro-air contained in the adhesive when the adhesive is applied, always remove the triplex after the curing of the adhesive proceeds to check the quality, so that There was a problem that can not solve the problem.

Therefore, in the present invention, it is to provide a bonding test apparatus that can visually check the bonding quality problems by monitoring the air bubbles during the application of the adhesive using the ABM device and the micro-air generated during the curing of the adhesive in real time in the electric field. For that purpose.

In order to achieve the above object, the present invention provides a bonding test apparatus comprising a pair of frames vertically installed on a bottom surface, and a transparent panel and a transparent panel installed on a flat and transparent material so as to apply an adhesive on an upper surface thereof. Consists of a pair of guide plates installed along the edge of the longitudinal direction on the upper surface to guide the movement path of the ABM device for applying the adhesive, rotatably installed on the top of the pair of frames and bonding is carried out when the adhesive is applied Rotating table that can visually check the process of generating fine air generated by air bubbles and adhesive curing in the electric field, Rotating shaft which protrudes from both ends of the rotating table to allow the rotating table to rotate, and rotated by fixing the rotating shaft Bonding test including posture fixation means to maintain posture of table Provide a device.

And preferably, the pair of frames, through the anchor bolt and the anchor plate is possible to adjust the right angle and height from the bottom surface.

In addition, preferably, the rotary table has a plurality of reinforcing reinforcing plates installed on each outer surface of the pair of guide plates at a distance from each other, and a reinforcing connection portion for connecting each other is installed at the lower end of each reinforcing plate facing each other. This prevents warping.

In addition, the posture fixing means is provided to include a rotary shaft therein, the rotary shaft guide for guiding the rotation of the rotary shaft, the flange formed on the rotary shaft through the position along the rotary shaft guide, the rotational posture state of the rotary shaft including the flange is maintained Characterized in that it consists of a grip lever that can be fixed by fastening the flange and the rotating shaft guide.

As described above, according to the bonding test apparatus of the present invention, the air bubbles during the application of the adhesive using the ABM apparatus and the micro-air generated during curing of the adhesive are monitored in real time in an electronic world to visually check the bonding quality problem. There is an effect that can contribute to the optimization of the bonding quality.

Hereinafter, the operating principle of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, when it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intentions or customs of the user, the operator, and the like. Therefore, the definition should be based on the contents throughout this specification.

2 is a plan view of a bonding test apparatus according to an embodiment of the present invention, FIG. 3 is a front view of a bonding test apparatus according to an embodiment of the present invention, and FIG. 4 is a side view of a bonding test apparatus according to an embodiment of the present invention. 5A to 5C are diagrams illustrating a state of use of the bonding test apparatus according to the present invention.

The bonding test apparatus illustrated in FIGS. 2 to 4 includes a pair of frames 100, a rotary table 110 rotatably mounted on the pair of frames 100, and a rotary table 110 to which adhesive is applied, and a rotary table ( 110 is largely composed of a posture fixing means to enable the rotation and rotation posture fixed.

Here, the pair of frames 100 are vertically spaced apart from the bottom surface by a proper distance on the same line, and are provided at each end of the plurality of anchor bolts 102 and the pair of frames 100 installed on the bottom surface. Angle and height can be adjusted through the anchor plate 104 is installed.

The rotary table 110 installed in a rectangular shape to connect the upper end of the pair of frames 100 enables the position posture in the rotated and rotated state to be generated when the air bubbles and the adhesive are hardened when the adhesive is applied. It is to be able to visually check the minute air generation process in the electric field (multi-direction).

On the lower side of the rotary table 110, the transparent panel 111 made of a transparent material as a portion to which the adhesive is substantially applied can be visually confirmed. Fixing frames 112 perpendicular to both sides of the transparent panel 111 are installed.

And a pair of guide plates 113 facing each other along the edge of the longitudinal direction is provided on the upper surface of the transparent panel 111, ABM device for applying the adhesive (shown in Figs. 5a to 5c: 150) It will guide the movement path of.

Since the rotary table 110 including the transparent panel 111 and the guide plate 113 is relatively long in the longitudinal direction, the reinforcing plate 114 and the reinforcing connection 115 are installed to prevent distortion.

The reinforcing plate 114 is fixed to each outer surface of the pair of guide plate 113 by a predetermined distance and fixedly installed through a screw or the like. 115 is installed to prevent distortion of the rotary table (110).

On the other hand, the rotary table 110 is integrally provided with a rotating shaft 120 protruding from both sides thereof and penetrating through the fixed frame 112 to the top of the pair of frames 100, and coupled to the rotating shaft 120. Posture fixing means is installed to maintain the posture of the rotated rotary table 110.

In the posture fixing means, the rotating shaft guide 130 including the rotating shaft 120 is installed at the upper end of the frame 100 and the fixing frame 112, and the rotating shaft 120 is fixed to the fixing frame 112. It is rotated inside the rotation shaft guide 130.

An integral flange 122 is formed on the rotary shaft 120 penetrated along the rotary shaft guide 130, and the fastening hole of the flange 122 is maintained to maintain the rotational posture of the rotary shaft 120 including the flange 122. (Not shown) and a grip lever 140 is inserted into a fastening hole (not shown) formed inside the rotation shaft guide 130 to fix the flange 122 to the rotation shaft guide 130.

Knurling (knurling) may be formed on the grip side of the grip lever 140, the screw thread is formed on the insertion side has a configuration that is fastened.

The operation of the bonding test apparatus having such a structure is performed as follows.

First, the height of the pair of frames 100 is adjusted through the anchor bolt 102 and the anchor plate 104.

Then, the grip lever 140 is screwed to the flange 122 of the rotary shaft 120 and the rotary shaft guide 130 so that the rotary table 110 is horizontal with the pair of frames 100 at a right angle.

Then, the ABM device 150 is installed on the pair of guide plates 113, and then bonding for testing is performed through the ABM device 150 moving along the guide plate 113.

Bonding is applied to the transparent panel 111 of the rotary table 110, it is possible to visually check the state of the adhesive applied from the outside through the transparent panel 111.

When the naked eye is confirmed, it is possible to check in an electric field (multi-direction). For this purpose, the grip lever 140 is removed from the rotary shaft guide 130 so that the rotation table 110 of the rotary shaft 120 can be rotated.

That is, as shown in FIG. 5A by rotating the rotary table 110 180 degrees, the grip lever 140 is inserted into the flange 122 of the rotary shaft 120 and the rotary shaft guide 130 to be fastened, thereby fixing the posture. The transparent panel 111 is viewed from above to check the bubble generation process according to the application.

In FIG. 5B, the rotary table 110 is rotated by 90 °, and the grip lever 140 is inserted into the flange 122 of the rotary shaft 120 and the rotary shaft guide 130 to be fastened, thereby fixing the posture fixed transparent panel ( 111 is viewed from the side to confirm the bubble generation process according to the application.

In addition, in FIG. 5C, the rotary table 110 is rotated by 45 °, and the grip lever 140 is inserted into the flange 122 of the rotary shaft 120 and the rotary shaft guide 130 to be fastened to secure the posture. The panel 111 is viewed from the inclined side direction to check the bubble generation process according to the application.

On the other hand, in the application check operation through the rotation of the rotary table 110 as described above, 180 ° degree is the angle for overhead work in the actual work, 90 ° degree horizontal (horizontal) work, 45 ° degree corner work To, according to the application situation that can occur in each working situation.

Therefore, the air bubbles and the process of generating the micro air contained in the adhesive can not be seen by the naked eye in the past when the adhesive is conventionally applied, and thus the quality is confirmed by removing the triplex after the curing of the adhesive has progressed. When the air generation process generated during the process could not be confirmed, the problem of fundamental bubble generation could not be solved, but the micro air generation process generated during curing of the air bubbles and the adhesive during the application of the adhesive through the bonding test apparatus of the present invention Real-time monitoring at age enables visual confirmation of bonding quality issues.

As described above, the bonding test apparatus according to the present invention is only one preferred embodiment, and the present invention is not limited to the above-described embodiments, and the present invention is not limited to the scope of the present invention. Without departing from the scope of the present invention, those skilled in the art will have the technical spirit of the present invention to the extent that various modifications can be made.

1 is a cross-sectional view showing the cargo hold structure of the LNG carrier according to the prior art,

2 is a plan view of a bonding test apparatus according to an embodiment of the present invention,

3 is a front view of a bonding test apparatus according to an embodiment of the present invention,

4 is a side view of a bonding test apparatus according to an embodiment of the present invention,

5A to 5C are diagrams illustrating the use of the bonding test apparatus according to the present invention.

<Description of the symbols for the main parts of the drawings>

100: frame 102: anchor bolt

104: anchor plate 110: rotating table

111: transparent panel 112: fixed frame

113: guide plate 114: reinforcement plate

115: reinforcement connection portion 120: rotation axis

122: flange 130: rotation shaft guide

140: grip lever

Claims (5)

As a bonding test device, A pair of frames installed perpendicular to the floor, With a pair of guide plates to guide the movement path of the ABM device for applying the adhesive to the transparent panel is installed on the top surface of the transparent panel is installed in a flat and transparent material along the longitudinal edge of the transparent panel A rotating table configured to be rotatably installed on top of the pair of frames, the bonding being carried out to visually check the air bubbles during the application of the adhesive and the generation of fine air generated during curing of the adhesive; A rotary shaft protruding from both ends of the rotary table to enable rotation of the rotary table; Posture fixing means for maintaining the posture of the rotary table fixed to the rotating shaft Bonding test device comprising a. The method of claim 1, The pair of frames, Bonding test device capable of adjusting the angle and height from the bottom surface through the anchor bolt and anchor plate. delete The method of claim 1, Each outer side surface of the pair of guide plates is provided with a plurality of fixing reinforcing plates spaced apart from each other, Bonding test device to the bottom of each of the facing reinforcement plate is further provided to connect the reinforcement connecting to prevent the twisting of the rotary table. The method of claim 1, The posture fixing means, A rotating shaft guide installed to include the rotating shaft therein and guiding rotation of the rotating shaft; A flange formed on the rotating shaft penetratingly positioned along the rotating shaft guide; Bonding test device comprising a grip lever that can be fixed by fastening the flange and the rotary shaft guide so that the rotational position of the rotary shaft including the flange is maintained.

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