JP2022144142A - Lighting fixture for aircraft - Google Patents

Abstract

To provide a lighting fixture for aircraft which secures an emission state of light in a wide range without causing increase in the number of components and complication of the structure.SOLUTION: A lighting fixture 1 for aircraft includes: a lighting fixture outer casing 4 having a lamp housing 2 and a cover 3 in which a lamp chamber 5 is formed by being combined; a substrate mounting member 13 which is arranged in the lamp chamber 5 and on which a substrate mounting part 15 is provided; a plurality of light source substrates 19 on which light sources 20 are mounted and which are arranged side by side in the circumferential direction or mounted being separated on the substrate mounting part 15; and an inner lens 34 having a cover part 36 for covering the plurality of light source substrates 19 from the outside. At the cover part 36, a control lens part 38 is provided positioned opposing to the plurality of light sources 20 for controlling the light emitted from the light sources 20. Thereby, since the light emitted from the plurality of light sources 20 is controlled by the control lens part 38 of the inner lens 34, an emission state of the light in a wide range can be secured without causing increase in the number of components and complication of the structure.SELECTED DRAWING: Figure 5

Description

TECHNICAL FIELD The present invention relates to a technical field of an aircraft lighting fixture that is attached to an aircraft body or the like for use.

2. Description of the Related Art Some aircraft lamps have a light source arranged inside a lamp housing composed of a cover and a lamp housing (see, for example, Patent Documents 1, 2, and 3).

There are various types of such aircraft lighting fixtures according to their intended use. Exterior lighting includes, for example, anti-collision lights that prevent collisions between aircraft, aircraft lights that indicate the flight attitude and direction of the aircraft, There are landing lights that illuminate the runway during takeoff and landing, and logo lights that illuminate the logos of airlines, etc. written on the aircraft.

Japanese Patent Application Laid-Open No. 2010-33840 Japanese Unexamined Patent Application Publication No. 2010-33841 JP 2020-119636 A

Since the aircraft lighting device as described above requires high visibility from other aircraft operators and the like, it is desirable that the light source be configured to emit light over a wide range.

Therefore, for example, it is possible to secure the light emission state over a wide range by increasing the number of light sources and the number of control members for controlling light, or by arranging a plurality of light sources in the circumferential direction. However, if the number of component parts increases, there is a risk that the manufacturing cost will increase due to the increase in the number of parts and the complexity of the structure.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to ensure that light is emitted over a wide range without increasing the number of parts or complicating the structure.

First, an aircraft lighting device according to the present invention includes a lamp housing having a lamp chamber formed therein by being joined together, a lighting device outer casing having a cover, and a board mounting portion disposed in the lamp chamber. A substrate mounting member, a plurality of light source substrates mounted with light sources and mounted on the substrate mounting portion in a circumferential direction or spaced apart from each other, and an inner lens having a covering portion covering the plurality of light source substrates from the outside. and a control lens portion is provided in the cover portion so as to face the plurality of light sources and control the light emitted from the light sources.

Thereby, the light emitted from the plurality of light sources is controlled by the control lens section of the inner lens.

Secondly, in the aircraft lighting device according to the present invention, a plurality of the light sources are mounted on the light source substrate in a predetermined arrangement direction, and a plurality of the control lens portions are provided side by side in the predetermined arrangement direction. desirable.

Accordingly, since each control lens unit is positioned to face the plurality of light sources, light emitted from the plurality of light sources is controlled by one lens control unit.

Thirdly, in the aircraft lighting device according to the present invention described above, it is desirable that the board mounting portion is formed in a cylindrical shape.

As a result, a plurality of light source substrates are attached to the tubular substrate attachment portion in a circumferential direction or spaced apart from each other, so that light can be emitted from the light source over the entire circumference.

Fourthly, in the aircraft lighting device according to the present invention, the inner lens is provided with a closing portion that closes one end of the cover portion in the axial direction, and the board mounting member is provided with a closing portion that closes one end of the cover portion in the axial direction. It is preferable that a mounting plate portion that closes one end is provided, and the closing portion is mounted to the mounting plate portion in a state in which the substrate mounting portion is positioned inside the cover portion.

Accordingly, by attaching the closing portion to the mounting plate portion, positioning of the light source substrate with respect to the inner lens and coupling between the inner lens and the substrate mounting member are performed.

Fifthly, the aircraft lighting device according to the present invention is provided with a control board for controlling turning on/off of the light source, a board mounting base on which the control board is mounted and arranged in the lamp chamber, Preferably, the control board is positioned inside the board mounting member.

As a result, the control board mounted on the board mounting base is positioned inside the board mounting member, and the light source board mounted on the board mounting member is positioned inside the inner lens.

According to the present invention, the light emitted from a plurality of light sources is controlled by the control lens portion of the inner lens, so that the light can be emitted over a wide range without increasing the number of parts or complicating the structure. can do.

1 is a perspective view of an aircraft; FIG. 1 is a perspective view of an aircraft lighting device; FIG. FIG. 3 is a perspective view showing the aircraft lamp as viewed from a direction different from that in FIG. 2; 1 is an exploded perspective view of an aircraft lighting device; FIG. 1 is a cross-sectional view of an aircraft lighting device; FIG. FIG. 4 is a perspective view showing part of the board mounting member and part of the flexible printed wiring board; FIG. 4 is a partially exploded perspective view showing an aircraft lighting device having another structure; FIG. 11 is a perspective view showing another structure of the aircraft lighting device with the inner lens attached to the lamp housing.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments for implementing the aircraft lighting device of the present invention will be described below with reference to the accompanying drawings.

An aircraft lighting device has a light source disposed inside a lighting device outer housing, and the lighting device outer housing has a lamp housing and a cover. The cover is the upper side, the lamp housing is the lower side, and the front, rear, up, down, left, and right directions are indicated.

Note that the front, rear, up, down, left, and right directions shown below are for convenience of explanation, and the implementation of the present invention is not limited to these directions.

An example in which the aircraft lighting device of the present invention is applied to an anti-collision light, which is exterior lighting, is shown below, but the scope of application of the present invention is not limited to the anti-collision light, and other exterior lighting fixtures used in aircraft. It may be applied to lighting.

The aircraft lighting device 1 is used, for example, as an anti-collision light, which is external lighting, and is attached to the upper or lower portion of the fuselage 101 of the aircraft 100, for example, the fuselage 102 (see FIG. 1). Note that the aircraft lighting device 1 may be attached to each of the wings, for example, both sides of the vertical stabilizer 103 .

When the aircraft lighting device 1 is attached to the body 102, the body 102 is formed with an arrangement concave portion (not shown). A part of the aircraft lighting device 1 is arranged in the arrangement recess and the other part is exposed from the body 102 .

The aircraft lighting device 1 includes a lamp housing 2 that opens upward and a cover 3 that opens downward, and the upper end of the lamp housing 2 and the lower end of the cover 3 are coupled (see FIGS. ). The aircraft lighting device 1 has a portion below the coupling portion of the lamp housing 2 and the cover 3 arranged in a placement recess of the body 102 , and the other portion is exposed from the body 102 . A lamp housing 4 is formed by the lamp housing 2 and the cover 3 , and a space inside the lamp housing 4 is formed as a lamp chamber 5 .

Each part of the lamp housing 2 is integrally formed of a metal material with high heat dissipation, such as aluminum. The lamp housing 2 has a cylindrical peripheral surface portion 6 whose axial direction is oriented vertically and a flange portion 7 projecting outward from the upper end portion of the peripheral surface portion 6 . Inner protrusions 6a, 6a, . An inner peripheral portion of the flange portion 7 is formed as a concave receiving portion 7a that is open upward and inward.

Each part of the cover 3 is integrally formed of a transparent resin material. The cover 3 has a cap-shaped cover portion 8 that opens downward and a pressed portion 9 that protrudes outward from the lower end portion of the cover portion 8 .

The lamp housing 2 and the cover 3 are pressed from above by an annular lens retainer 10 made of a metal material at the pressed portion 9 of the cover 3 and pressed from below by the inner peripheral portion of the flange portion 7 of the lamp housing 2 . , and the lens retainer 10 is fixed to the flange portion 7 by screws or the like.

As described above, the cover 3 is in a state where the pressed portion 9 is pressed by the lens retainer 10 and the flange portion 7 from the upper side and the lower side and sandwiched between the lens retainer 10 and the flange portion 7. is prevented from coming off, and a stable arrangement state of the cover 3 is ensured.

When the lens retainer 10 is fixed to the flange portion 7, an annular first gasket 11 is interposed therebetween. The lamp housing 2 and the cover 3 are fixed to the body 102 or the like by screwing or the like at the connecting portion between the lens retainer 10 and the flange portion 7 . 12 are interposed.

The first gasket 11 provides waterproofness to the lamp chamber 5 , and the second gasket 12 serves to prevent the aircraft lamp 1 from rattling with respect to the body 102 and to provide waterproofness to the arrangement recess formed in the body 102 .

A substrate mounting member 13 is disposed in the lamp chamber 5, and the substrate mounting member 13 is mounted to the lamp housing 2 by screwing or the like. Each part of the substrate mounting member 13 is integrally formed of a metal material with high heat dissipation, such as aluminum. The board mounting member 13 is made of a metal material with high heat dissipation, and thus functions as a heat sink.

The substrate mounting member 13 includes a substantially annular annular portion 14 whose axial direction is oriented vertically, a substantially cylindrical substrate mounting portion 15 whose lower end portion is continuous with the inner peripheral portion of the annular portion 14, and an outer peripheral portion. A substantially disc-shaped mounting plate portion 16 that is continuous with the upper end portion of the substrate mounting portion 15; connecting protrusions 17 that protrude downward from the outer peripheral portion of the annular portion 14 and are spaced apart in the circumferential direction; . . .

The board mounting member 13 is formed in a downwardly open shape, has an opening 13a at its lower end, and has an internal space formed as an arrangement space 13b.

A wiring board insertion hole 14a is formed vertically through the annular portion 14 (see FIG. 6).

The outer peripheral surface of the board mounting portion 15 is, for example, equally divided into nine, and the nine divided surfaces are formed as flat board mounting surfaces 15a, 15a, . . . (see FIGS. 4 and 5). .

Positioning pins 16a, 16a protruding upward are provided on the outer peripheral portion of the mounting plate portion 16, and the positioning pins 16a, 16a are provided at substantially opposite positions with the center portion of the mounting plate portion 16 interposed therebetween.

Light source substrates 19, 19, . . . are attached to the substrate mounting surfaces 15a, 15a, . It is The first heat dissipation sheet 18 and the light source substrate 19 are formed, for example, in a vertically long rectangular shape, and on the outer surface of the light source substrate 19, for example, three light sources 20, 20, 20 are mounted separately in the longitudinal direction. there is As the light source 20, for example, a light emitting diode (LED) is used.

As described above, the light source boards 19, 19, . . . are attached to the board mounting surfaces 15a, 15a, . 13 may be mounted circumferentially side by side or spaced apart. Therefore, it becomes possible to emit light from the light sources 20, 20, . .

A flexible printed wiring board 21 is connected to the light source boards 19, 19, . . . (see FIGS. 4 to 6). The flexible printed wiring board 21 includes an attached portion 21a extending in a predetermined direction, connecting portions 21b, 21b, . A relay portion 21c protrudes from the mounting portion 21a in the direction opposite to the direction in which the connection portion 21b protrudes. The connection portions 21b, 21b, .

The flexible printed wiring board 21 has the relay portion 21c inserted from above into the wiring board insertion hole 14a formed in the annular portion 14 of the board mounting member 13, and the attached portion 21a is the lower end of the board mounting portion 15 of the board mounting member 13. . . are attached to the lower end portions of the light source substrates 19, 19, . . . by soldering or the like. However, the attached portion 21a may be attached to the substrate attachment portion 15 without using an adhesive.

The substrate mounting portion 15 and the mounting plate portion 16 of the substrate mounting member 13 are inserted into the peripheral surface portion 6 of the lamp housing 2 from below, and the annular portion 14 is mounted to the inner protrusions 6a, 6a, . 4 and 5). At this time, an annular second heat radiation sheet 22 is interposed between the annular portion 14 and the inner protrusions 6a, 6a, . is mounted via a heat radiation sheet 22 of When the board mounting member 13 is mounted on the lamp housing 2 , the substantially upper half portion of the board mounting portion 15 and the mounting plate portion 16 protrude upward from the lamp housing 2 .

As described above, in the aircraft lamp 1, the light source board 19 is attached to the board mounting surface 15a of the board mounting member 13 via the first heat radiation sheet 18, and the annular portion 14 is formed by the inner projections 6a, 6a, . . . through the second heat radiation sheet 22 . Therefore, the heat generated in the light source substrate 19 and the light source 20 when the light source 20 is driven is transmitted from the first heat radiation sheet 18 to the substrate mounting member 13, is transmitted from the substrate mounting member 13 to the lamp housing 2, and is transmitted from the lamp housing 2 to the outside. Since the light is emitted, the temperature rise of the light source substrate 19 and the light source 20 is suppressed, and the light source 20 can be kept in a good on/off state.

A board mounting base 23 is arranged in the lamp chamber 5, and the board mounting base 23 is mounted on the board mounting member 13 by screwing or the like from the opening 13a side. Each part of the board mounting base 23 is integrally formed of a metal material with high heat dissipation, such as aluminum. The board mounting base 23 has a substantially disc-shaped base portion 24 facing in the vertical direction and a member mounting portion 25 projecting upward from the base portion 24 . The board mounting base 23 also functions as a heat sink by being made of a metal material with high heat dissipation.

A connector 26 is attached to the base portion 24. A portion of the connector 26 is inserted through the base portion 24 and a lower portion protrudes downward from the base portion 24 (see FIGS. 3 to 5). A cable connected to a power supply circuit (not shown) disposed inside the fuselage 101 with the aircraft lighting device 1 attached to the fuselage 102 is connected to a portion of the connector 26 protruding downward from the base portion 24 . . The base portion 24 is formed with a screw hole 24a penetrating vertically.

The member mounting portion 25 is formed in a vertically long, substantially rectangular, substantially flat plate shape and positioned between the connector 26 and the screw hole 24a (see FIGS. 4 and 5). The member mounting portion 25 is formed with mounting surfaces 25a, 25a each having the widest area facing in the horizontal direction.

A control board 27 is attached to the board mounting base 23 . Electronic components (not shown) are mounted on the control board 27 . The control board 27 has a function of controlling turning on/off of the light sources 20, 20, . . . mounted on the light source boards 19, 19, . A first substrate 28 and a second substrate 29 are connected by wiring. The control board 27 has a first board 28 attached to one mounting surface 25a and a second board 29 mounted to the other mounting surface 25a. The control board 27 has a first board 28 connected to the relay portion 21 c of the flexible printed wiring board 21 , and a second board 29 connected to the connector 26 via a connection line 30 .

In the aircraft lighting fixture 1, current is supplied from the power supply circuit to the second board 29 via the connector 26 and the connection line 30, and from the second board 29 to the flexible printed wiring board 21 via the first board 28. are supplied to the light sources 20, 20, . . . from the light source substrates 19, 19, . At this time, the first substrate 28 and the second substrate 29 control the turning on and off of the light sources 20, 20, . In the aircraft lighting device 1, for example, lighting/lighting control is performed such that all the light sources 20, 20, . . .

As described above, in the aircraft lighting device 1 , the control board 27 has the first board 28 and the second board 29 , and the member mounting portion 25 has the first board 28 and the second board 29 on both sides. installed.

Therefore, since the control board 27 is divided into the first board 28 and the second board 29 and both of them are mounted on the member mounting portion 25, the arrangement space of the control board 27 is reduced, and the size of the aircraft lamp 1 is reduced. can be planned.

Further, in the aircraft lighting device 1, a flexible printed wiring board 21 is provided for connecting the control board 27 and the plurality of light source boards 19, 19, . . . and a plurality of connection portions 21b, 21b, .

Therefore, since the plurality of light source boards 19, 19, . . . The plurality of light source boards 19, 19, . . . and the control board 27 can be easily connected while securing space.

In addition, since it is not necessary to connect the plurality of light source boards 19, 19, . be able to.

Further, since a plurality of connection wires for connecting the plurality of light source boards 19, 19, . can be done.

An O-ring 31 made of rubber or the like is attached to the outer peripheral portion of the base portion 24 of the board mounting base 23 .

The substrate mounting base 23 is inserted into the peripheral surface 6 of the lamp housing 2 from below, and the upper surface of the base portion 24 abuts against the lower surfaces of the connecting protrusions 17, 17, . At this time, the cushion 32 is arranged between the upper surface of the member mounting portion 25 of the board mounting base 23 and the lower surface of the mounting plate portion 16 of the board mounting member 13 , and the member mounting portion 25 is attached to the mounting plate portion 16 via the cushion 32 . be pushed. Therefore, the cushion 32 can prevent the board mounting base 23 from rattling with respect to the board mounting member 13 .

When the substrate mounting base 23 is inserted into the peripheral surface portion 6 of the lamp housing 2 from below, the O-ring 31 attached to the base portion 24 is in close contact with the inner peripheral surface of the peripheral surface portion 6 . Accordingly, waterproofness is achieved for the arrangement space 13b, which is the internal space of the board mounting member 13. As shown in FIG.

The base portion 24 of the board mounting base 23 is mounted on the coupling protrusions 17, 17, . . . by screws or the like. When the board mounting base 23 is mounted on the board mounting member 13 , the control board 27 is positioned in the arrangement space 13 b of the board mounting member 13 .

As described above, the first substrate 28 and the second substrate 29 are attached to the mounting surfaces 25a, 25a of the member mounting portion 25, but they may be attached to the mounting surfaces 25a, 25a via heat radiation sheets. By attaching the first substrate 28 and the second substrate 29 to the attachment surfaces 25a, 25a via the heat dissipation sheet, the heat generated when the first substrate 28 and the second substrate 29 are driven is transferred to the first substrate. 28 and the second board 29 to the board mounting base 23, from the board mounting base 23 to the lamp housing 2 through the board mounting member 13, and emitted from the lamp housing 2 to the outside. Therefore, the temperature rise of the first substrate 28 and the second substrate 29 is suppressed, and the good driving conditions of the first substrate 28 and the second substrate 29 can be secured.

As described above, since the substrate mounting member 13 and the substrate mounting base 23 are both formed of a metal material as heat sinks, heat generated in the light source substrate 19 is transmitted to the substrate mounting member 13 formed as a heat sink and controlled. The heat generated in the substrate 27 is transferred to the substrate mounting base 23 formed as a heat sink to enable heat dissipation. Therefore, the temperature rise of the light source 20 mounted on the light source board 19 and the electronic parts mounted on the control board 27 is suppressed, and a stable driving state of the light source 20 and the electronic parts can be ensured.

When the board mounting base 23 is mounted on the board mounting member 13 , the control member 33 having a threaded portion is screwed into the screw hole 24 a formed in the base portion 24 . The control member 33 contains a functional material that is permeable to air but impermeable to moisture. Therefore, during the flight of the aircraft 100 or the like, the control member 33 causes the air to flow inside and outside the aircraft lighting fixture 1, thereby suppressing fluctuations in the internal pressure. In addition, by providing the control member 33, moisture is prevented from entering the inside of the aircraft lamp 1 through the screw hole 24a, and each part arranged in the lamp chamber 5 is protected.

An inner lens 34 is arranged in the lamp chamber 5, and the inner lens 34 is attached to the substrate attachment member 13 by screws or the like. Each part of the inner lens 34 is integrally formed of a transparent resin material.

The inner lens 34 includes a substantially disk-shaped closing portion 35 facing in the vertical direction, a cover portion 36 whose upper end is continuous with the outer peripheral portion of the closing portion 35, and a lower end portion of the cover portion 36 that protrudes outward. and a projecting portion 37 .

Positioning holes 35a, 35a penetrating vertically are formed in the closing portion 35, and the positioning holes 35a, 35a are formed at substantially opposite sides with the central portion of the closing portion 35 interposed therebetween.

The cover portion 36 is formed in a substantially cylindrical shape that is one size larger than the board mounting portion 15 of the board mounting member 13 and has a length in the axial direction shorter than that of the board mounting portion 15 in the axial direction. Control lens portions 38 , 38 , 38 are continuously provided in the upper and lower portions of the cover portion 36 . The control lens portion 38 is formed in a substantially annular shape, and has a substantially semicircular vertical cross-sectional shape that is outwardly convex.

The inner lens 34 is positioned on the substrate mounting member 13 by inserting the positioning pins 16a, 16a into the positioning holes 35a, 35a of the closing portion 35, respectively. A screw hole (not shown) is formed in the mounting plate portion 16 of the board mounting member 13, and a screw insertion hole (not shown) is formed in the closing portion 35 of the inner lens 34. As described above, the inner lens 34 is attached to the board. In the state where it is positioned on the mounting member 13 , the closing portion 35 is mounted on the mounting plate portion 16 by screwing a mounting screw (not shown) inserted through the screw insertion hole into the screw hole.

When the inner lens 34 is attached to the substrate attachment member 13, control lens portions 38, 38, . 38 is located (see FIG. 5). That is, the upper control lens unit 38 is positioned facing the light sources 20, 20, . A lower control lens part 38 is positioned to face the lower light sources 20, 20, . . . .

Therefore, the light emitted from the light sources 20, 20, . , 20, . . . are controlled by the control lens portion 38 in the middle stage, pass through the cover 3, and are irradiated to the outside, and are emitted from the light sources 20, 20, . The emitted light is controlled by the lower control lens portion 38, passes through the cover 3, and is irradiated to the outside.

As described above, when the inner lens 34 is attached to the board mounting member 13, the projecting portion 37 is engaged with the receiving portion 7a of the flange portion 7 of the lamp housing 2, and the inner lens 34 is mounted in the lamp chamber 5. Stable placement is ensured.

As described above, in the aircraft lighting fixture 1, the board mounting base 23 is mounted on the board mounting member 13 from the opening 13a side, and the control board 27 is mounted in the state where the board mounting base 23 is mounted on the board mounting member 13. It is located in the arrangement space 13b.

Therefore, the board mounting member 13 and the board mounting base 23 are arranged in the lamp chamber 5 formed by combining the lamp housing 2 and the cover 3, and the arrangement space is formed in a state where the board mounting base 23 is mounted on the board mounting member 13. A control board 27 is positioned at 13b. As a result, the control board 27 is positioned in the arrangement space 13b, which is the inner space of the light chamber 5, which has a double-spaced structure. Even if water unintentionally intrudes into the lamp chamber 5 due to a large change in temperature, the control board 27 does not easily adhere to the water. Adhesion of moisture can be prevented. In the aircraft lamp 1, between the positioning hole 35a of the inner lens 34 and the positioning pin 16a of the substrate mounting member 13, between the projecting portion 37 of the inner lens 34 and the receiving portion 7a of the lamp housing 2, the control A silicon agent or the like is filled between the mounting member 33 and the threaded hole 24a of the substrate mounting base 23 to make the arrangement space 13b waterproof.

Further, when the aircraft lighting device 1 is attached to the body 102 or the like, both the first substrate 28 and the second substrate 29 of the control substrate 27 are positioned in a direction other than the vertical direction (vertical direction), for example, the horizontal direction. is turned to face. Therefore, in the unlikely event that water vapor present inside the aircraft lighting device 1 becomes water droplets and adheres to the first substrate 28 or the second substrate 29 due to changes in air pressure or temperature during flight of the aircraft 100, Also, water droplets run down from the first substrate 28 and the second substrate 29 to prevent moisture from adhering to the first substrate 28 and the second substrate 29, thereby ensuring a stable driving state of the control substrate 27. can be done.

Further, in the aircraft lamp 1, the board mounting portion 15 of the board mounting member 13 is formed in a tubular shape.

Therefore, since the light source substrates 19, 19, . . . , high visibility of the aircraft lighting device 1 is ensured, and the functionality of the aircraft lighting device 1 can be improved.

Furthermore, the inner lens 34 is provided with a closing portion 35 that closes one end of the cover portion 36 in the axial direction, and the board mounting member 13 is provided with the mounting plate portion 16 that blocks one end of the board mounting portion 15 in the axial direction, The closing portion 35 is attached to the mounting plate portion 16 in a state where the board mounting portion 15 is positioned inside the cover portion 36 .

Accordingly, by attaching the closing portion 35 to the mounting plate portion 16, positioning of the light source substrate 19 with respect to the inner lens 34 and coupling between the inner lens 34 and the substrate mounting member 13 are performed. It can be done easily with high accuracy.

In addition, a board mounting base 23 is provided to which a control board 27 is mounted and arranged in the lamp chamber 5 , and the control board 27 is positioned inside the board mounting member 13 .

Therefore, since the control board 27 attached to the board mounting base 23 is positioned inside the board mounting member 13 and the light source board 19 attached to the board mounting member 13 is positioned inside the inner lens 34, the inner lens The light source board 19 and the control board 27 are positioned inside 34, so that space efficiency can be improved and the size of the aircraft lamp 1 can be reduced.

Next, an aircraft lighting device 51 having a structure different from that of the aircraft lighting device 1 described above will be described (see FIGS. 7 and 8).

The aircraft lighting device 51 has a lamp housing 52 opened upward and a cover 53 opened downward, and the upper end of the lamp housing 52 and the lower end of the cover 53 are coupled. The aircraft lighting device 51 has, for example, a portion below the connecting portion of the lamp housing 52 and the cover 53 arranged in an arrangement recess of the body 102 , and the rest of the portion is exposed from the body 102 . The lamp housing 52 and the cover 53 constitute a lamp housing 54 , and the space inside the lamp housing 54 is formed as a lamp chamber 55 .

Each part of the lamp housing 52 is integrally formed of a metal material with high heat dissipation, such as aluminum. The lamp housing 52 has a bottom surface portion 56 facing in the vertical direction, a tubular peripheral surface portion 57 projecting upward from the outer peripheral portion of the bottom surface portion 56, and a flange portion 58 projecting outward from the upper end portion of the peripheral surface portion 57. have. The lamp housing 52 is provided with mounting bosses 59 , 59 , 59 projecting upward from the bottom surface portion 56 .

Each part of the cover 53 is integrally formed of a transparent resin material. The cover 53 has a cap-like cover portion 60 that opens downward and a flange-like protrusion 61 that protrudes outward from the lower end portion of the cover portion 60 .

The lamp housing 52 and the cover 53 are attached to the lower surface of the inner peripheral portion of an annular lens retainer 62 in which the flange-like protrusion 61 of the cover 53 is formed of a metal material, and the lens retainer 62 is screwed to the flange portion 58 or the like. Connected by being fixed.

When the lens retainer 62 is fixed to the flange portion 58, an annular first gasket 63 is interposed therebetween. The lamp housing 52 and the cover 53 are fixed to the body 102 or the like by screwing or the like at the connecting portion between the lens retainer 62 and the flange portion 58 . 64 are interposed.

The first gasket 63 makes the lamp chamber 55 waterproof, and the second gasket 64 prevents the aircraft lamp 51 from rattling with respect to the body 102 and waterproofs the arrangement recess formed in the body 102 .

A board mounting member 65 is arranged in the lamp chamber 55, and the board mounting member 65 is mounted on the mounting bosses 59, 59, 59 of the lamp housing 52 by screwing or the like. The board mounting member 65 is made of a metal material with high heat dissipation, such as aluminum, and each part is integrally formed. The board mounting member 65 also functions as a heat sink by being made of a metal material with high heat dissipation.

The board mounting member 65 has a substantially semicircular board mounting portion 66 that protrudes upward, and mounted surface portions 67, 67 projecting in opposite directions from both ends of the board mounting portion 66 in the circumferential direction. there is

The board mounting portion 66 is composed of a plurality of, for example, five continuous flat plate portions between the mounting surface portions 67, 67, and the outer surface of each flat plate portion of the board mounting portion 66 is a flat board mounting surface 66a. , 66a, . . .

The light source substrates 68, 68, . . . are attached to the substrate attachment surfaces 66a, 66a, . The first heat radiation sheet and the light source substrate 68 are formed, for example, in a rectangular shape, and on the outer surface of the light source substrate 68, for example, three light sources 69, 69, 69 are mounted separately in the longitudinal direction. As the light source 69, for example, a light emitting diode (LED) is used.

As described above, the light source boards 68, 68, . . . are attached to the board mounting surfaces 66a, 66a, . 65 may be circumferentially side-by-side or spaced apart. Therefore, it becomes possible to emit light from the light sources 69, 69, .

For example, electric wires (not shown) are connected to the light source substrates 68, 68, . Incidentally, in the aircraft lighting device 51 as well as in the aircraft lighting device 1, flexible printed wiring boards may be connected to the light source substrates 68, 68, .

The substrate mounting member 65 has its mounting surface portions 67, 67 mounted to the mounting bosses 59, 59, 59 by screwing or the like. At this time, a second heat radiation sheet (not shown) is interposed between the mounting surface portions 67, 67 and the mounting bosses 59, 59, 59, and the mounting surface portions 67, 67 contact the mounting bosses 59, 59, 59 for the second heat radiation. It is attached via a sheet.

As described above, in the aircraft lighting fixture 51, the light source board 68 is attached to the board mounting surface 66a of the board mounting member 65 via the first heat dissipation sheet, and the mounting surface portions 67, 67 are mounted on the mounting bosses 59, 59, 59 via a second heat radiation sheet. Therefore, the heat generated in the light source board 68 and the light source 69 when the light source 69 is driven is transmitted from the first heat dissipation sheet to the board mounting member 65, is transmitted from the board mounting member 65 to the lamp housing 52, and is released from the lamp housing 52 to the outside. Therefore, the temperature rise of the light source substrate 68 and the light source 69 is suppressed, and the good on/off state of the light source 69 can be ensured.

A connector 70 is attached to the peripheral surface portion 57 of the lamp housing 52 , and a portion of the connector 70 is inserted through the peripheral surface portion 57 and the other portion protrudes outward from the peripheral surface portion 57 . The portion protruding outward from the peripheral surface portion 57 of the connector 70 is connected to a control unit having a control board disposed inside the fuselage 101 in a state where the aircraft lighting device 51 is attached to the fuselage 102. Connected to the power circuit. A power supply circuit may be formed integrally with the control unit.

In the aircraft lighting device 51, current is supplied from the power supply circuit to the light source boards 68, 68, . supplied to . At this time, the control unit controls turning on/off of the light sources 69, 69, . . . In the aircraft lighting device 51, for example, on/off control is performed such that all the light sources 69, 69, . . .

As described above, in the aircraft lighting device 51, since the control unit is arranged inside the fuselage 101, a space for arranging the control unit inside the aircraft lighting device 51 is not required. miniaturization can be achieved.

As described above, the substrate mounting member 65 is made of a metal material and formed as a heat sink, so that the heat generated in the light source substrate 68 is transmitted to the substrate mounting member 65 formed as a heat sink, enabling heat dissipation. Therefore, the temperature rise of the light source 69 mounted on the light source substrate 68 is suppressed, and the stable driving state of the light source 69 can be ensured.

Incidentally, in the aircraft lamp 51 as well, the lamp housing 52 may be screwed with a control member containing a functional material that is permeable to air but impermeable to moisture, as in the case of the aircraft lamp 1 . By providing the control member, air is caused to flow inside and outside the aircraft lighting fixture 51 by the control member during the flight of the aircraft 100, and variations in internal pressure are suppressed. In addition, by providing the control member, moisture is prevented from entering the interior of the aircraft lamp 51, and each part arranged in the lamp chamber 55 is protected.

An inner lens 71 is arranged in the lamp chamber 55, and the inner lens 71 is attached to the substrate attachment member 65 by screws or the like. Each part of the inner lens 71 is integrally formed of a transparent resin material.

The inner lens 71 has an upwardly convex substantially semicircular arc surface-shaped cover portion 72 and mounting projections 73, 73 projecting in opposite directions from both ends of the cover portion 72 in the longitudinal direction.

The diameter of the cover portion 72 is one size larger than that of the board mounting portion 66 of the board mounting member 65 . The cover portion 72 is provided with control lens portions 74, 74, 74 arranged in the width direction. The control lens portion 74 extends in the circumferential direction and is formed in a substantially semicircular arc shape, and has a substantially semicircular vertical cross-sectional shape that is outwardly convex.

The inner lens 71 is attached to the mounting bosses 59 and 59 of the lamp housing 52 by, for example, screwing them together, with the mounting protrusions 73 and 73 overlapping the mounting surface portions 67 and 67 of the board mounting member 65 from above, respectively. 59, 59.

When the inner lens 71 is attached to the substrate attachment member 65, control lens portions 74, 74, . 74 is located. That is, the control lens portion 74 on one end side in the width direction of the cover portion 72 is positioned facing the light sources 69, 69, . , light source substrates 68, 68, . Positioned on the other end side in the longitudinal direction of the substrates 68, 68, . .

Therefore, the light emitted from the light sources 69, 69, . The light emitted from the light sources 69, 69, . The light emitted from .

As described above, in the aircraft lighting device 1 and the aircraft lighting device 51, the board mounting members 13 and 65 provided with the board mounting portions 15 and 66, and the board mounting portions 15 and 66 on which the light sources 20 and 69 are mounted. provided with a plurality of light source substrates 19 and 68 mounted side by side in the circumferential direction or separated from each other, and inner lenses 34 and 71 having cover portions 36 and 72 that cover the plurality of light source substrates 19 and 68 from the outside, Control lens portions 38 and 74 are provided on the cover portions 36 and 72 so as to face the light sources 20 and 69 of the plurality of light source substrates 19 and 68 and control the light emitted from the light sources 20 and 69 .

Therefore, since the light emitted from the plurality of light sources 20, 69 is controlled by the control lens portions 38, 74 of the inner lenses 34, 71, the light can be spread over a wide range without increasing the number of parts or complicating the structure. can be ensured.

A plurality of light sources 20 and 69 are mounted on the light source substrates 19 and 68 in a predetermined arrangement direction, and a plurality of control lens portions 38 and 74 are arranged in a predetermined arrangement direction.

. . , 69, 69, 69, 69, . The light emitted from . can be done by

DESCRIPTION OF SYMBOLS 1... Aircraft lamp, 2... Lamp housing, 3... Cover, 4... Lamp outer housing, 5... Lamp chamber, 13... Board mounting member, 15... Board mounting part, 16... Mounting plate part, 19... Light source board, 20 Light source 23 Substrate mounting base 27 Control substrate 34 Inner lens 35 Closure portion 36 Cover portion 38 Control lens portion 51 Vehicle lamp 52 Lamp housing 53 Cover 54... Lamp fitting outer housing 55... Lamp chamber 65... Board mounting member 66... Board mounting part 68... Light source board 69... Light source 71... Inner lens 72... Cover part 74... Control lens part

Claims (5)

a lamp housing having a lamp housing with a lamp chamber formed therein and a lamp housing having a cover;
a substrate mounting member disposed in the lamp chamber and provided with a substrate mounting portion;
a plurality of light source substrates mounted with a light source and attached to the substrate attachment portion in a circumferential direction or spaced apart from each other;
an inner lens having a covering portion that covers the plurality of light source substrates from the outside,
An aircraft lighting device, wherein the cover portion is provided with a control lens portion positioned to face the plurality of light sources and controlling light emitted from the light sources. A plurality of the light sources are mounted on the light source substrate in a predetermined arrangement direction,
The aircraft lighting device according to claim 1, wherein a plurality of said control lens portions are provided side by side in said predetermined arrangement direction. The aircraft lighting device according to claim 1 or 2, wherein the board mounting portion is formed in a cylindrical shape. The inner lens is provided with a closing portion that closes one end of the covering portion in the axial direction,
The board mounting member is provided with a mounting plate section that closes one end of the board mounting section in the axial direction,
The aircraft lighting device according to claim 3, wherein the closing portion is attached to the mounting plate portion in a state in which the board mounting portion is positioned inside the cover portion. A control board is provided for controlling turning on and off of the light source,
A board mounting base is provided to which the control board is mounted and which is arranged in the lamp chamber,
5. The aircraft lighting device according to claim 1, wherein the control board is positioned inside the board mounting member.

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