KR101318858B1 - Method of head up display wedge maintenance for fa-50 fighter - Google Patents

Abstract

The present invention reduces the need for excessive airborne refitting of conventional wedges, thereby preventing delays in fighter operations and optimizing the fighter's armed performance and flight safety environment to ensure that pilots effectively and accurately perform missions. It is an object to provide a method for optimizing maintainability.
In order to achieve the above object, the FA-50 fighter HUD wedge maintainability optimization design method according to the present invention, (a) a hinge fixing structure around the hinge to the fighter structure, and about 25 ° lowered about the hinge (B) When loosening the bolts of the SMFD, the mounting angle of the SMFD is lowered by approximately 25 ° and visually checked for the mounting state of the HUD wedge. The method may include securing a space for performing the HUD wedge adjustment operation, and (c) performing a wedge adjustment operation using a tool in the secured space.

Description

How to maintain a FA-50 Fighter HWD Wedge {METHOD OF HEAD UP DISPLAY WEDGE MAINTENANCE FOR FA-50 FIGHTER}

The present invention relates to a FA-50 fighter HUD (head up display equipment) wedge maintenance method, in particular for the optimization of arming performance and flight safety through the optimization of M / H during ground check of the HUD wedge 50 fighter HUD wedge maintenance.

In general, FA-50 fighters perform a variety of missions in the military. In addition, the pre-operation plan for the flight of the FA-50 fighters must implement all systems on the ground quickly and effectively before the operation of the FA-50 fighters. In other words, based on the FA-50 fighter's maneuverability characteristics, all equipment and weapons systems can be configured according to each setting so that the FA-50 fighter can perform its missions after the pilot has boarded the FA-50 fighter. Effective performance must be maximized, as well as completion of assigned missions.

For the special purpose of the FA-50 fighter, the maintenance of the HUD wedge must be effective. Wedges are mounted on the left and right sides of the HUD, respectively, and are linked to the fighter's armed performance and flight safety through on-the-fly inspection of the fighter's operation (e.g., there is no gap between the HUD and the fighter structure). Basic functions are categorized by (1) armed performance check (Boresight setpoint check) and (2) hard landing check.

The HUD wedge is made of hard rubber material and is installed to protect the HUD when the fighter vibrates. The rubber material should be adjusted through occasional checks during operation of the fighter.

If a gap occurs in any one of the left and right wedges, the HUD may be inclined to one side. This may be a phenomenon in which the HUD symbol is distorted. Deterioration (wrong target position) and deterioration of fighter flight safety may occur.

Thus, HUD wedge checks are performed sequentially before the flight mission is performed. However, since the HUD wedge is covered by the instrument panel and the SMFD (auxiliary multifunction display), the inspection must be carried out after each piece of equipment has been removed and the inspection must be carried out after the removal of the equipment. do.

1 (a) is a view showing the front seat of the control room of the FA-50 fighter according to an embodiment of the present invention, Figure 1 (b) is a HUD and wedge to perform an operation check according to an embodiment of the present invention, And a beam structure.

In order to perform the HUD wedge check, as shown in FIG. 1A, a windshield 1, a glareshield 2, a HUD 3 and a CMFD (color multiful-function) are performed. After detaching the display 4, the wedge bolt 7 is released, so that there is no gap between the HUD 3 and the wedge 5, as shown in FIG. 1 (b), and also the fighter beam structure 6 ) So that there is no gap between the wedge 5 and the wedge bolt 7 is tightened again. After that, each detached piece of equipment must be refitted to the fighter and then an operational check of each piece of equipment must be performed.

2 is a diagram in which the distance between the pilot's DEP 9 and the MFD 8 and the wedge 5 are hidden by the MFD 8 according to an embodiment of the invention.

However, as shown in FIG. 2, the FA-50 fighter is designed based on the TA-50 fighter, so that the existing HUD wedge maintenance method is the same as the TA-50 fighter. Based on the pilot's DEP (design eye point) (9), the development of the TA-50 fighter, based on the pilot's perspective (9), compared to other fighters (e.g. F-16). (8) is located close to the pilot (for example, the distance between the pilot's DEP 9 and the MFD 8 is approximately 29.64 inches), so when checking the HUD wedge of the cockpit front seat, It takes M / H (man / hour) [17.5 M / h].

Table 1 shows the installation of the windshield (1), instrument panel (2), HUD (3), and MFD (8) for the wedge adjustment of the wedge (5) during flight (in operation). , It takes about 17 + 50 M / H.

That is, as an occasional check item regarding the mounting state of the HUD wedge, when the mounting state of the wedge 5 is poor (that is, when a gap is generated), it is necessary to perform remounting (no gap) and excessive There is a problem that deterioration of armed performance and flight safety during the operation delay and emergency sortie of the fighter due to the airborne (M / H) requirements.

Therefore, the technical problem to be achieved by the present invention is to reduce the need for excessive airborne when replacing the conventional wedge, to prevent the delay of the operation of the fighter, and to optimize the armed performance and flight safety environment of the fighter pilots effectively and accurately It provides a way to optimize the maintainability of the HUD wedges to perform the mission.

In order to solve the above problems, the FA-50 fighter HUD wedge maintainability optimization design method according to the present invention, (a) a hinge fixing structure around the hinge to the fighter structure, and about 25 ° lowered about the hinge (B) When loosening the bolts of the SMFD, the mounting angle of the SMFD is lowered by approximately 25 ° and visually checked for the mounting state of the HUD wedge. The method may include securing a space for performing the HUD wedge adjustment operation, and (c) performing a wedge adjustment operation using a tool in the secured space.

In addition, the FA-50 fighter HUD wedge serviceability optimization design method according to the present invention, in the step (b), when the bolts of the SMFD, two bolts in the lower side of the SMFD and the side of the SMFD And removing two bolts and two bolts on the top of the SMFD, and removing the bolts which fasten six SMFDs in total.

According to the present invention, the HUD is prevented from delaying the operation of the conventional wedge by reducing excessive airborne requirements, and by optimizing the fighter's armament performance and flight safety environment, the pilot performs the mission effectively and accurately. It can provide a way to optimize wedge maintainability.

1 (a) is a view showing the front seat of the control room of the FA-50 fighter according to an embodiment of the present invention, Figure 1 (b) is a HUD and wedge to perform an operation check according to an embodiment of the present invention, And a diagram showing a beam structure.
Figure 2 is a view of the distance and wedge between the pilot's DEP and MFD in the MFD according to an embodiment of the present invention.
3 is a view of applying a hinge to the SMFD mounting structure according to an embodiment of the present invention.
4 (a) to 4 (c) show a method of unscrewing the bolts for detaching the SMFD according to an embodiment of the present invention.
5 (a) and 5 (b) are views showing that the SMFD is lowered and positioned in the pedestal structure when the hinge according to the embodiment of the present invention is applied.
6 is a view showing the wedge mounting state and the adjustment operation according to an embodiment of the present invention.

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

3 is a view to which the hinge 10 is applied by using the structure of the fighter according to the embodiment of the present invention.

3 is a view of applying the hinge 10 to the SMFD (11) mounting structure according to an embodiment of the present invention. 3, the hinge fixing structure 10a around the hinge 10 and a structure 10b that can be lowered by about 25 ° about the hinge 10 are arranged on the same line. After applying (10), loosening the bolts of the SMFD 11 lowers the mounting angle of the SMFD 11 by approximately 25 ° and visually confirms the mounting state of the HUD wedge 5 to adjust the wedge 5. Free space is available to perform work (ie maintenance). In FIG. 3, in the planar direction, UP represents the top and FWD represents the front. In addition, since the bolt is loosened after applying the hinge 10 to the SMFD 11 structure, as shown on the right side of FIG. 3, the angle of the SMFD 11 is lowered by approximately 25 °, which is shown in the circle of dotted line. As shown, the wedge 5 is visually confirmed.

Next, FIGS. 4A to 4C are diagrams showing a method of unscrewing bolts for detaching the SMFD 11.

Looking at the space direction shown in Figure 4 (a), UP represents the upper part of the fighter, FWD represents the front of the fighter, OTBD represents the outside of the fighter board. In addition, looking at the spatial direction shown in (b) of Figure 4, UP represents the top of the fighter, OTBD represents the outside of the fighter board, AFT represents the rear of the fighter. In addition, looking at the plane direction shown in (c) of Figure 4, UP represents the upper portion of the fighter, OTBD represents the outside of the fighter board. First, as shown in Fig. 4A, two bolts 12a under the SMFD 11 are removed. Next, as shown in Fig. 4B, after removing the two bolts 12b on the side of the SMFD 11, finally, as shown in Fig. 4C, The two bolts 12c on the top of the SMFD 11 are removed to remove the bolts that hold the six SMFDs 11 in total.

Therefore, as shown in (a) to (c) of FIG. 4, when six bolts are fastened to the SMFD 11, the SMFD 11 is centered on the hinge 10. ) Will drop approximately 25 °.

Next, FIGS. 5A and 5B are views showing that the SMFD 11 is lowered and positioned on the pedestal structure 13 when the hinge 10 according to the embodiment of the present invention is applied.

Referring to the planar directions shown in FIGS. 5A and 5B, UP represents the upper part of the fighter and FWD represents the front of the fighter.

Referring to FIGS. 5A and 5B, when a mechanic removes six bolts fastened to the SMFD 11, the SMFD 11 is lowered by about 25 ° about the hinge 10. To be located in the pedestal structure 13 of the SMFD 11. That is, since the SMFD 11 lowered by about 25 degrees is safely positioned on the pedestal structure 13, the mechanic can easily perform maintenance without worrying about the SMFD 11 lowered by about 25 degrees. Can be. On the other hand, in this figure, for ease of description, only the left side SMFD has been described, the same method is applied to the right side SMFD of the front seat.

Next, Figure 6 is a view showing the wedge 5 mounting state and adjustment operation according to an embodiment of the present invention.

Looking at the spatial direction shown in Figure 6, UP represents the top of the fighter, FWD represents the front of the fighter, OTBD represents the outside of the fighter board. Referring to FIG. 6, when the SMFD 11 is lowered by approximately 25 ° about the hinge 10, the wedge 5 may be visually checked by the mechanic. The wedge 5 state (inside the dotted circle) is about 6 inches wide and 3.76 inches long by the mechanic can visually check. Therefore, after checking the state of the wedge 5 visually, the mechanic easily performs adjustment work using a tool (for example, a spanner).

Therefore, as described above, by removing only six bolts fastened to the SMFD 11 using the hinge 10, the state of the wedge 5 is visually confirmed, and the tool is used to determine the wedge 5. By performing the adjustment work, the 17.5 M / H time required for the previous work can be significantly reduced to 1 M / H.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary and will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. will be. Therefore, the true technical protection scope of the present invention will be defined by the claims.

1: windscreen
2: instrument panel
3: HUD
4: CMFD
5: wedge
6: aircraft beam structure
7: wedge bolt
8: MFD
9: DEP
10: hinge
10a: hinge fixing structure
10b: structure
11: SMFD
12a, 12b, 12c: wedge bolt
13: pedestal structure

Claims (2)

(a) fastening a hinge fixing structure around a hinge to a fighter structure and a structure that can be lowered by 25 ° about the hinge by applying the hinge on the same line;
(b) when the bolts of the SMFD are unscrewed, the mounting angle of the SMFD is lowered by 25 ° to visually check the mounting state of the HUD wedge, thereby securing a space for performing the HUD wedge adjustment operation;
and (c) adjusting the wedge using a tool in the space provided. The method of claim 1,
In the step (b)
When the bolts of the SMFD are loosened, two bolts at the bottom of the SMFD, two bolts at the side of the SMFD, and two bolts at the top of the SMFD are removed to fasten the six SMFDs. How to service a FA-50 fighter HUD wedge comprising removing a bolt.

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