JP2022129164A - Light source uni and vehicular lamp - Google Patents

Abstract

To provide a light source unit which prevents static electricity from jumping into a light source without increasing cost of manufacture, and a vehicular lamp.SOLUTION: A light source unit 7 of a vehicular lamp comprises: a socket housing 8 which includes a resin molding part 9 including an annular elected wall portion of whose inner space is formed as an arrangement space, and a heat dissipation part 10 formed from a metal material, for performing heat dissipation to the outside; a substrate 21 which is arranged in the arrangement space and on which at least a light source 22 is mounted; a ground terminal 27 which is connected to the substrate 21; and a power receiving part 28 which is partially arranged in the arrangement space and is connected to the ground terminal.EFFECT: Static electricity is easily inputted to the power receiving part and the inputted static electricity flows from the power receiving part to the ground terminal connected to the substrate. Therefore, it is not necessary to use a cover, a wire, etc., for preventing static electricity from jumping into the light source, and static electricity can be prevented from jumping into the light source 22 without increasing cost of manufacture.SELECTED DRAWING: Figure 2

Description

The present invention relates to a technical field of a light source unit and a vehicle lamp having a socket housing and a substrate arranged on the socket housing.

A vehicle lamp is provided with, for example, a light source unit that is detachable from a lamp outer casing composed of a lamp body and a cover and a reflector disposed inside the lamp outer casing. Some use light-emitting elements such as light-emitting diodes.

Such a light source unit is provided with a light-emitting element that functions as a light source and a substrate on which a wiring pattern for supplying current to at least the light-emitting element is formed, and the substrate is attached to a socket housing ( For example, see Patent Document 1 and Patent Document 2).

In the light source unit, the substrate attached to the socket housing is exposed, and static electricity may be applied to the substrate from each part such as the reflector. If the static electricity applied to the substrate reaches the light source mounted on the substrate, the light source unit may malfunction.

Therefore, in the light source units described in Patent Documents 1 and 2, a metal cover is provided to cover a portion of the substrate other than at least a portion of the substrate, thereby preventing static electricity from entering the substrate. It is

JP 2014-107229 A JP 2017-224466 A

However, as in the light source units described in Patent Documents 1 and 2, in a configuration in which a metallic cover is provided to prevent static electricity from entering the substrate, the cover is placed on the side of the light emitted from the light source. Therefore, the cover needs to be formed in a size and shape that does not block the light emitted from the light source, which may increase the manufacturing cost of the light source unit.

On the other hand, there is also a configuration for preventing the application of static electricity to the substrate by connecting a reflector or the like, which is charged with static electricity, and a ground circuit provided in the light source unit or the like with an electric wire or the like. In addition to the preparation of the wires, the work of connecting electric wires and the like is also required, and there is also a risk that the manufacturing cost will rise.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to prevent static electricity from entering a light source without increasing manufacturing costs.

First, the light source unit according to the present invention has a resin molded portion having an annular standing wall portion with an inner space formed as an arrangement space, and a heat radiating portion formed of a metal material for radiating heat to the outside. A socket housing, a substrate arranged in the arrangement space and having at least a light source mounted thereon, a ground terminal connected to the substrate, and a power receiving unit at least partially arranged in the arrangement space and connected to the ground terminal. It is prepared.

This makes it easier for static electricity to be input to the power receiving unit, and the input static electricity flows from the power receiving unit to the ground terminal connected to the substrate. There is no

Secondly, in the light source unit according to the present invention described above, it is desirable that the power receiving portion is formed in a tubular shape along the inner peripheral surface of the standing wall portion.

This makes it difficult for static electricity to enter the substrate in all directions around the light source.

Thirdly, in the above-described light source unit according to the present invention, it is preferable that a lightning rod coupled to the substrate is provided as the power receiving section.

This makes it possible to arbitrarily determine the number of power receiving units and the connection positions of the power receiving units with respect to the board.

Fourthly, in the light source unit according to the above-described present invention, the heat radiation portion is formed in a shape having an internal space, electronic components are mounted thereon, and a control board for controlling turning on/off of the light source is provided, and the internal space is It is desirable that a metal plate is arranged in the space, a closed space surrounded by the heat radiating portion and the metal plate is formed, and the control board is arranged in the closed space.

As a result, the control board with the electronic components mounted is placed in a closed space surrounded by the heat radiation part and the metal plate, both of which are made of metal material. be done.

Fifthly, a vehicle lamp according to the present invention is a vehicle lamp including a light source unit, wherein the light source unit includes a resin-molded portion having an annular standing wall portion with an inner space formed as an arrangement space. A socket housing made of a metal material and having a heat radiating portion for radiating heat to the outside, a substrate arranged in the arrangement space and having at least a light source mounted thereon, a ground terminal connected to the substrate, and at least a portion thereof. is arranged in the arrangement space and is connected to the ground terminal.

This makes it easier for static electricity to be input to the power receiving unit in the light source unit, and the input static electricity flows from the power receiving unit to the ground terminal connected to the substrate. etc. need not be used.

According to the present invention, static electricity is easily input to the power receiving unit and the input static electricity flows from the power receiving unit to the ground terminal connected to the substrate. is not required, and static electricity can be prevented from entering the light source without increasing the manufacturing cost.

The embodiment of the present invention is shown together with FIGS. 2 to 6, and this figure is a cross-sectional view of a vehicle lamp. It is a sectional view showing a light source unit concerning a 1st embodiment. FIG. 5 is a cross-sectional view showing a light source unit according to a second embodiment; FIG. 10 is a cross-sectional view showing a light source unit having another configuration according to the second embodiment; It is a sectional view showing a light source unit concerning a 3rd embodiment. FIG. 11 is a cross-sectional view showing a light source unit having another configuration according to the third embodiment;

EMBODIMENT OF THE INVENTION Below, the form for implementing this invention is demonstrated with reference to an accompanying drawing.

In the following description, the direction of the optical axis is the front-rear direction, and the direction of light emission is the front. 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.

<Schematic configuration of vehicle lamp>
First, a schematic configuration of the vehicle lamp will be described (see FIG. 1).

A vehicle lamp 1 includes a lamp body 2 having a recess opening forward and a cover 3 closing an opening 2a on the front side of the lamp body 2. As shown in FIG. The lamp body 2 and the cover 3 constitute a lamp housing 4, and the inner space of the lamp housing 4 is formed as a lamp chamber 4a.

A substantially cylindrical unit mounting portion 5 is provided vertically through the lower end portion of the lamp body 2, and a space inside the unit mounting portion 5 is formed as a mounting hole 5a. A plurality of engaging protrusions (not shown) that protrude inward are provided on the inner peripheral surface of the unit mounting portion 5 so as to be spaced apart in the circumferential direction.

A reflector 6 is arranged inside the lamp housing 4 . A light transmitting hole 6a is formed at the rear end portion of the lower end portion of the reflector 6. As shown in FIG. The inner surface of the reflector 6 is formed as a reflective surface 6b, and the reflective surface 6b is formed by metal vapor deposition, for example. In the vehicle lamp 1, light emitted from a light source, which will be described later, is transmitted through the light transmitting hole 6a, reflected by the reflecting surface 6b, transmitted through the cover 3, and irradiated to the outside. In the vehicle lamp 1, the reflector 6 may not be arranged, and the inner surface of the lamp body 2 may be formed as a reflective surface by metal deposition.

The vehicle lamp 1 includes a lamp body 2 and a cover 3 as well as a light source unit 7 that can be attached to and detached from a unit mounting portion 5 of the lamp body 2 . The vehicle lamp 1 may be configured to include a light source unit 7A or a light source unit 7B that can be attached to and detached from the unit mounting portion 5 in addition to the lamp outer housing 4 .

The structures and the like of the light source unit 7, the light source unit 7A, and the light source unit 7B will be described in order below (see FIGS. 2 to 6).

<Structure, etc. of the light source unit according to the first embodiment>
First, the structure and the like of the light source unit 7 according to the first embodiment will be described (see FIG. 2).

The light source unit 7 is constructed by disposing required parts in a socket housing 8 . The socket housing 8 is formed by integrally molding a resin molded portion 9 and a heat radiating portion 10, for example.

The resin-molded portion 9 includes a substantially disc-shaped main body base portion 11 facing in the front-rear direction, and a vertical wall portion 12 protruding forward from a portion near the outer periphery of the main body base portion 11, and is positioned behind the main body base portion 11 so as to be spaced apart from each other. It has a disk-shaped base surface portion 13 and a connector connection portion 14 projecting rearward from the base surface portion 13 .

A plurality of engaging portions (not shown) projecting outward are provided on the standing wall portion 12 so as to be spaced apart in the circumferential direction. The vertical wall portion 12 is formed in an annular shape, for example, in a cylindrical shape, and the space inside the vertical wall portion 12 is formed as an arrangement space 12a that opens forward.

The base surface portion 13 is slightly larger in diameter than the main body base portion 11 , and its outer peripheral portion is located outside the main body base portion 11 .

The connector connecting portion 14 has a cylindrical rear end portion, and a space inside the cylindrical shape is formed as a connector insertion space 14a.

The heat radiation part 10 functions as a heat sink, and is made of a plate-shaped metal material such as aluminum having high thermal conductivity formed into a predetermined shape. The heat radiating portion 10 is formed in a rearwardly open shape so as to have an internal space 15, and is composed of a first portion 10a, a second portion 10b, a third portion 10c and a fourth portion 10d.

The first portion 10a is formed in a plate-like shape facing the front-rear direction, the second portion 10b is formed in a cylindrical shape with a front end portion continuing to the outer peripheral portion of the first portion 10a, and the third portion 10c is formed in the front-rear direction. It is formed in a plate-like ring shape facing a direction, and the inner peripheral portion is continuous with the rear end portion of the second portion 10b, and the front end portion of the fourth portion 10d is continuous with the outer peripheral portion of the third portion 10c. is formed in

The first portion 10a is arranged on the front surface of the main body base portion 11 in the arrangement space 12a, the second portion 10b is arranged inside the main body base portion 11, and the third portion 10c is arranged on the main body base portion except for the outer peripheral portion. 11 and the base surface portion 13 , and the fourth portion 10 d is positioned on the outer peripheral side of the base surface portion 13 and the connector connecting portion 14 .

A disk-shaped metal plate 16 , for example, is arranged on the front surface of the base surface portion 13 . Therefore, a space is formed inside the light source unit 7 between the main body base portion 11 and the metal plate 16 , and this space is formed as a closed space 17 . The closed space 17 is surrounded by the heat radiating portion 10 and the metal plate 16, and the input and output of electromagnetic noise to the closed space 17 is shielded by the heat radiating portion 10 and the metal plate 16, which are both made of a metal material.

In addition, there is a possibility that a gap is formed between the outer peripheral surface of the metal plate 16 and the inner peripheral surface of the fourth portion 10d of the heat radiating portion 10. Alternatively, the metal plate 16 and the fourth portion 10d may be joined with the adhesive in a state in which the gap is filled with the adhesive without conductivity. Also, in order to prevent electromagnetic noise from entering and exiting the closed space 17 through this gap, an EMI (Electro Magnetic Interference) removal filter for removing electromagnetic noise may be arranged in or near the gap.

A light source module 18 is provided in the light source unit 7 , and the light source module 18 has a light emitting circuit section 19 and a control circuit section 20 .

The light emitting circuit portion 19 is arranged on the first portion 10a of the heat radiating portion 10 in the arrangement space 12a formed inside the vertical wall portion 12, and is mounted on the light source substrate 21 facing in the front-rear direction and the central portion of the light source substrate 21. and a light source 22 . A circuit pattern is formed on the light source substrate 21 , and part of the circuit pattern is formed as a ground pattern 23 . A light emitting diode (LED) is used as the light source 22 .

The control circuit unit 20 is arranged on the metal plate 16 in a closed space 17 surrounded by a part of the heat radiating unit 10 and the metal plate 16, and is mounted on the control substrate 24 on which a wiring pattern is formed facing the front-rear direction. and electronic components 25, 25, . . . As the electronic component 25, for example, integrated circuits, diodes, capacitors, resistors, and the like are used.

A positive terminal 26 and a ground terminal 27 functioning as connection terminals are connected to the light source substrate 21 , and the positive terminal 26 and the ground terminal 27 are formed, for example, in the shape of a shaft extending forward and backward. The positive terminal 26 and the ground terminal 27 pass through the light source substrate 21, the first portion 10a of the heat radiating portion 10, the resin molded portion 9, the control substrate 24, and the metal plate 16, and the front end protrudes forward from the light source substrate 21, The rear end portion is located in the connector insertion space 14a of the connector connecting portion 14. As shown in FIG.

The positive terminal 26 and the ground terminal 27 are joined to the circuit pattern of the light source substrate 21 and the wiring pattern of the control substrate 24 by soldering, for example. Also, the ground terminal 27 is connected to the ground pattern 23 of the light source substrate 21 and the plus terminal 26 is not connected to the ground pattern 23 .

A gap is formed between the positive terminal 26 and the first portion 10a of the heat radiating portion 10, and a gap is also formed between the metal plate 16. The gap may be filled with a non-conductive adhesive to prevent electromagnetic noise from entering and exiting. Also, in order to prevent electromagnetic noise from entering and exiting the closed space 17 through this gap, an EMI removal filter that removes electromagnetic noise may be arranged in or near the gap.

A connector connected to a power supply circuit (not shown) arranged inside the vehicle is connected to the connector connection portion 14, and a positive terminal 26 and a ground terminal 27 are connected to the power supply circuit via the connector.

A cylindrical power receiving portion 28 made of a metal material is arranged in the arrangement space 12 a of the standing wall portion 12 . The power receiving portion 28 has its outer peripheral surface in contact with the inner peripheral surface of the standing wall portion 12, and is provided at a position where its lower end is aligned with the upper surface of the light source substrate 21, and is connected to the ground pattern 23 of the light source substrate 21 by soldering or the like. ing.

For example, the front end of the power receiving portion 28 is aligned with the front end of the standing wall portion 12 . However, the front end of power receiving portion 28 may be positioned forward of the front end of standing wall portion 12 . Further, the front end of the power receiving portion 28 may be positioned rearward of the front end of the standing wall portion 12 , but preferably positioned at least forward of the front end of the light source 22 . Further, the front end portion of power receiving portion 28 may be bent outward, and the bent portion may be arranged on the front end surface of standing wall portion 12 .

Since the power receiving portion 28 exists inside the vertical wall portion 12, the static electricity that is about to enter the installation space 12a is input to the power receiving portion 28, and the input static electricity is supplied to the power supply circuit from the ground pattern 23 via the ground terminal 27. input to the grounded circuit section. Therefore, the static electricity that tries to jump into the arrangement space 12 a is less likely to jump into the light source 22 mounted on the light source substrate 21 .

As described above, the light source unit 7 is provided with the ground terminal 27 connected to the light source substrate 21 and the power receiving section 28 arranged in the arrangement space 12a and connected to the ground terminal 27 .

Therefore, since static electricity flows from the power receiving portion 28 to the ground terminal 27 connected to the light source substrate 21, there is no need to use a cover, electric wire, or the like for preventing static electricity from entering the light source 22, resulting in an increase in manufacturing cost. static electricity can be prevented from entering the light source 22 without

In particular, since the power receiving portion 28 is formed in a cylindrical shape (annular shape) that covers the light source 22 from its surroundings, it is difficult for static electricity to enter the light source substrate 21 in all directions around the light source 22 , and static electricity does not reach the light source 22 . can be effectively prevented from jumping in.

In addition, by aligning the front end of the power receiving portion 28 with the front end of the standing wall portion 12 or being positioned forward of the front end of the standing wall portion 12, it is possible to more effectively prevent static electricity from entering the light source 22.

Further, since the outer peripheral surface of power receiving portion 28 is in contact with the inner peripheral surface of standing wall portion 12, power receiving portion 28 formed of a metal material can also serve as a reinforcing member for standing wall portion 12 formed of a resin material. It is possible to improve the strength of the light source unit 7 while preventing static electricity from entering the light source 22 .

Furthermore, in the light source unit 7, the heat radiation part 10 is formed in a shape having an internal space 15, a closed space 17 surrounded by the heat radiation part 10 and the metal plate 16 is formed, and the control board 24 is formed in the closed space 17. are placed.

Therefore, since the control board 24 having the electronic components 25, 25, . . . Static electricity does not enter, electromagnetic noise is restricted, and a stable driving state of the control board 24 is ensured, so that the light source 22 can be kept in a good ON/OFF state.

In the light source unit 7, the light source module 18 is divided into the light emitting circuit section 19 and the control circuit section 20, and the control circuit section 20 is arranged in the closed space 17. The control circuit section 20 does not come into contact with other parts such as the unit mounting section 5 when it is attached to or detached from the unit mounting section 5, and the control circuit section 20 can be protected.

Further, the light source module 18 is divided into a light emitting circuit portion 19 and a control circuit portion 20 , the light emitting circuit portion 19 is arranged on the first portion 10 a of the heat dissipation portion 10 and the control circuit portion 20 is arranged on the metal plate 16 . Therefore, the heat generated in the light emitting circuit section 19 is transmitted to the heat radiation section 10 and released to the outside, and the heat generated in the control circuit section 20 is transmitted to the metal plate 16 and released from the heat radiation section 10 to the outside. Since the heat is dissipated through the heat transfer paths, the heat dissipation efficiency can be improved.

Incidentally, the heat radiating portion 10 and the metal plate 16 may be formed of so-called punching metal or expanded metal having a plurality of small holes. However, it is desirable that the size of the small hole is such that electromagnetic noise does not enter the closed space 17, for example, 1 mm to 2 mm smaller than the wavelength of the electromagnetic noise.

<Structure etc. of Light Source Unit According to Second Embodiment>
Next, the structure and the like of the light source unit 7A according to the second embodiment will be described (see FIGS. 3 and 4). Note that the light source unit 7A described below is different from the light source unit 7 described above only in that one substrate is provided and the configuration of the power receiving unit is different. Only the parts will be explained in detail, and the other parts will be given the same reference numerals as the same parts in the light source unit 7, and the explanation will be omitted.

The light source unit 7A is constructed by arranging necessary parts in a socket housing 8A (see FIG. 3). The socket housing 8A is formed by, for example, integrally molding a resin molded portion 9A and a heat radiating portion 10. As shown in FIG.

The resin molded portion 9A includes a substantially disc-shaped main body base portion 11 facing in the front-rear direction, a standing wall portion 12 protruding forward from a portion near the outer periphery of the main body base portion 11, and a disc continuous with the rear surface of the main body base portion 11. It has a shaped base surface portion 13 and a connector connection portion 14 projecting backward from the base surface portion 13 .

As described above, the base surface portion 13 is provided continuously with the main body base portion 11, the closed space 17 is not formed in the light source unit 7A, and the metal plate 16 is not provided.

The light source unit 7A is provided with a light source module 18A, and the light source module 18A is integrated with a light emitting circuit section and a control circuit section.

The light source module 18A is arranged on the first portion 10a of the heat radiating portion 10 in the arrangement space 12a formed inside the vertical wall portion 12, and is mounted on the substrate 21A facing in the front-rear direction and the light source 22 mounted in the central portion of the substrate 21A. It has electronic components 25, 25, . . . mounted around the light source 22 on the substrate 21A. A ground pattern 23 for conducting static electricity is not formed on the substrate 21A.

The positive terminal 26 and the ground terminal 27 pass through the substrate 21A, the first portion 10a of the heat radiating portion 10, and the resin molded portion 9A. It is located in the insertion space 14a.

The positive terminal 26 and the ground terminal 27 are each joined to the substrate 21A by soldering, for example. Also, the ground terminal 27 is electrically connected to the first portion 10 a of the heat dissipation portion 10 .

In the installation space 12a of the standing wall portion 12, a cylindrical power receiving portion 28A made of a metal material is arranged. The power receiving portion 28A has its outer peripheral surface in contact with the inner peripheral surface of the standing wall portion 12, and its rear end portion is continuous with the outer peripheral portion of the first portion 10a of the heat radiating portion 10. For example, the power receiving portion 28A is formed integrally with the heat radiating portion 10. It is By integrally forming the power receiving portion 28A with the heat radiating portion 10, the number of components of the light source unit 7A can be reduced and the strength of the light source unit 7A can be improved.

For example, the front end of the power receiving portion 28</b>A coincides with the front end of the standing wall portion 12 . However, the front end of power receiving portion 28A may be positioned forward of the front end of standing wall portion 12 . Further, the front end of the power receiving portion 28A may be positioned rearward from the front end of the standing wall portion 12, but at least it should be positioned frontward from the front ends of the light source 22 or the electronic components 25, 25, . . . It is desirable that

Since the power receiving portion 28A exists inside the standing wall portion 12, the static electricity that is about to enter the installation space 12a is input to the power receiving portion 28A, and the input static electricity spreads from the first portion 10a of the heat radiating portion 10 to the ground terminal 27. It is input to the ground circuit section provided in the power supply circuit via. Therefore, the static electricity that tries to jump into the arrangement space 12a is less likely to jump into the light source 22 and the electronic components 25, 25, . . . mounted on the substrate 21A.

As described above, the light source unit 7A is provided with the ground terminal 27 connected to the substrate 21A and the power receiving section 28A arranged in the arrangement space 12a and connected to the ground terminal 27. FIG.

Therefore, since static electricity flows from the power receiving portion 28A to the ground terminal 27 connected to the substrate 21A, it is necessary to use a cover, an electric wire, or the like to prevent the static electricity from jumping into the light source 22 and the electronic components 25, 25, . Therefore, static electricity can be prevented from entering the light source 22 and the electronic parts 25, 25, . . . without increasing the manufacturing cost.

In particular, since the power receiving portion 28A is formed in a tubular shape (annular shape) along the inner peripheral surface of the standing wall portion 12 and covers the light source 22 and the electronic components 25, 25, . In all directions around 25, . Dive-in can be effectively prevented.

Further, by aligning the front end of the power receiving portion 28A with the front end of the standing wall portion 12 or being positioned forward of the front end of the standing wall portion 12, static electricity can be more effectively prevented from entering the light source 22 and the electronic components 25, 25, . can be effectively prevented.

Further, since the outer peripheral surface of the power receiving portion 28A is in contact with the inner peripheral surface of the standing wall portion 12, the power receiving portion 28A formed of a metal material can also serve as a reinforcing member for the standing wall portion 12 formed of a resin material. It is possible to prevent static electricity from entering the light source 22 and the electronic components 25, 25, . . . and improve the strength of the light source unit 7A.

In the above example, the ground pattern 23 is not formed on the substrate 21A in the light source unit 7A, and static electricity is input from the power receiving portion 28A to the ground terminal 27 via the first portion 10a of the heat radiating portion 10. Although shown, the ground pattern 23 may be formed on the substrate 21A in the light source unit 7A (see FIG. 4).

In this case, the power receiving portion 28A is not connected to the first portion 10a but is connected to the ground pattern 23, and the static electricity input to the power receiving portion 28A passes from the ground pattern 23 through the ground terminal 27 to the power supply circuit. is input to the ground circuit provided in the

Since the power receiving portion 28A is connected to the ground pattern 23 in this way, it becomes possible to form the power receiving portion 28A from a member separate from the heat radiating portion 10. can be inserted into and placed in the placement space 12a. Therefore, the degree of freedom in assembling each part of the light source unit 7A is increased, and the degree of freedom in design can be improved.

<Structure etc. of Light Source Unit According to Third Embodiment>
Next, the structure and the like of the light source unit 7B according to the third embodiment will be described (see FIGS. 5 and 6). Note that the light source unit 7B described below differs from the light source unit 7 described above only in that it is provided with one substrate and that the configuration of the power receiving unit is different. Only the parts will be explained in detail, and the other parts will be given the same reference numerals as the same parts in the light source unit 7, and the explanation will be omitted.

The light source unit 7B is constructed by arranging necessary parts in a socket housing 8B (see FIG. 5). The socket housing 8B is formed by, for example, integrally molding a resin molded portion 9B and a heat radiating portion 10. As shown in FIG.

The resin molded portion 9B includes a substantially disk-shaped main body base portion 11 facing in the front-rear direction, a vertical wall portion 12 protruding forward from a portion near the outer periphery of the main body base portion 11, and a disc continuous with the rear surface of the main body base portion 11. It has a shaped base surface portion 13 and a connector connection portion 14 projecting backward from the base surface portion 13 .

As described above, the base surface portion 13 is provided continuously with the main body base portion 11, the closed space 17 is not formed in the light source unit 7B, and the metal plate 16 is not provided.

A light source module 18B is provided in the light source unit 7B, and the light emitting circuit section and the control circuit section are integrated in the light source module 18B.

The light source module 18B is arranged on the first portion 10a of the heat radiating portion 10 in the arrangement space 12a formed inside the vertical wall portion 12, and is mounted on the substrate 21B facing the front-rear direction and the light source 22 mounted on the central portion of the substrate 21B. It has electronic components 25, 25, . . . mounted around the light source 22 on the substrate 21B. A ground pattern 23B is formed on the substrate 21B.

The positive terminal 26 and the ground terminal 27 pass through the substrate 21B, the first portion 10a of the heat radiating portion 10, and the resin molded portion 9B, with their front ends protruding forward from the substrate 21B and their rear ends being connected to the connector of the connector connecting portion 14. It is located in the insertion space 14a.

The positive terminal 26 and the ground terminal 27 are each joined to the substrate 21B by soldering, for example. Also, the ground terminal 27 is connected to the ground pattern 23B of the substrate 21B, and the plus terminal 26 is not connected to the ground pattern 23B.

Shaft-shaped power receiving portions 28B, 28B, . The power receiving units 28B are provided as lightning rods, and at least one of them may be arranged in the arrangement space 12a.

The power receiving units 28B, 28B, . The power receiving units 28B, 28B, . . . are provided at positions surrounding the light source 22 and the electronic components 25, 25, .

For example, the front end of the power receiving portion 28B coincides with the front end of the standing wall portion 12 . However, the front end of power receiving portion 28</b>B may be positioned forward of the front end of standing wall portion 12 . Further, the front end of the power receiving portion 28B may be positioned rearward from the front end of the standing wall portion 12, but at least it is positioned frontward from the front ends of the light sources 22 or the electronic components 25, 25, . . . It is desirable that

Since the power receiving units 28B, 28B, . . . The signal is input from 23B through the ground terminal 27 to the ground circuit section provided in the power supply circuit. Therefore, the static electricity that tries to jump into the arrangement space 12a is less likely to jump into the light source 22 and electronic components 25, 25, . . . mounted on the substrate 21B.

As described above, the light source unit 7B is provided with the ground terminal 27 connected to the substrate 21B, and the power receiving units 28B, 28B, . ing.

Therefore, since static electricity flows from the power receiving portions 28B, 28B, . It is possible to prevent static electricity from entering the light source 22 and the electronic components 25, 25, .

In particular, since the power receiving units 28B, 28B, . . . static electricity is difficult to jump into the light source 22 and the electronic parts 25, 25, . be able to.

Also, the front ends of the power receiving portions 28B, 28B, . . . It is possible to more effectively prevent jumping into.

Further, a lightning rod connected to the substrate 21B is provided as a power receiving portion 28B.

Therefore, since the number of power receiving units 28B and the connection position of the power receiving units 28B with respect to the substrate 21B can be determined arbitrarily, one or more power receiving units can be arranged at positions close to the light source 22 and the electronic components 25, 25, . By arranging the portion 28B, it is possible to prevent static electricity from entering the light source 22 and the electronic components 25, 25, .

In the above example, the ground pattern 23B is formed on the substrate 21B in the light source unit 7B, and static electricity is input from the power receiving section 28B to the ground terminal 27 via the ground pattern 23B. 3, the ground pattern 23B may not be formed on the substrate 21B, and the power receiving portion 28B may be electrically connected to the first portion 10a of the heat radiating portion 10 (see FIG. 6).

In this case, the power receiving units 28B, 28B, . The signal is input from the portion 10a through the ground terminal 27 to the ground circuit provided in the power supply circuit.

Since the power receiving portion 28B is connected to the first portion 10a of the heat radiating portion 10 in this way, the power receiving portion 28B penetrates through the substrate 21B to connect the first portion 10a or the first portion 10a and the resin. It is coupled to the molding portion 9B. Therefore, the power receiving portion 28B also functions as a reinforcing member for attaching the substrate 21B to the first portion 10a, preventing static electricity from entering the light source 22 and the electronic components 25, 25, . 8 can be secured.

Further, in the light source unit 7B, since the power receiving portion 28B is formed in a shaft shape, it is possible to extend the ground terminal 27 forward and make this extended portion function as the power receiving portion 28B.

With such a configuration, there is no need to provide a dedicated power receiving section 28B in the light source unit 7B in addition to the ground terminal 27, and the number of components can be reduced and the structure can be simplified. Jumping into the electronic components 25, 25, . . . can be prevented.

DESCRIPTION OF SYMBOLS 1... Vehicle lamp, 7... Light source unit, 8... Socket housing, 9... Resin molding part, 10... Radiation part, 12... Standing wall part, 12a... Layout space, 15... Internal space, 16... Metal plate, 17... Closure Space 18 Light source module 21 Light source board (substrate) 22 Light source 24 Control board 25 Electronic component 27 Ground terminal 28 Power receiving unit 7A Light source unit 8A Socket housing 9A Resin molded portion 18A Light source module 21A Substrate 28A Power receiving portion 7B Light source unit 8B Socket housing 9B Resin molded portion 18B Light source module 21B Substrate 23B Ground pattern 28B …Receiving part

Claims (5)

a socket housing having a resin molded portion having an annular standing wall portion with an inner space formed as an arrangement space and a heat radiating portion formed of a metal material for radiating heat to the outside;
a substrate arranged in the arrangement space and having at least a light source mounted thereon;
a ground terminal connected to the substrate;
a light source unit at least partially arranged in the arrangement space and connected to the ground terminal. The light source unit according to claim 1, wherein the power receiving portion is formed in a tubular shape along the inner peripheral surface of the standing wall portion. The light source unit according to claim 1, wherein a lightning rod coupled to the substrate is provided as the power receiving section. The heat radiation part is formed in a shape having an internal space,
A control board is provided on which electronic components are mounted and controls turning on and off of the light source,
A metal plate is arranged in the internal space,
A closed space surrounded by the heat radiation part and the metal plate is formed,
4. The light source unit according to claim 1, wherein the control board is arranged in the closed space. A vehicle lamp comprising a light source unit,
The light source unit
a socket housing having a resin molded portion having an annular standing wall portion with an inner space formed as an arrangement space and a heat radiating portion formed of a metal material for radiating heat to the outside;
a substrate arranged in the arrangement space and having at least a light source mounted thereon;
a ground terminal connected to the substrate;
and a power receiving unit at least partially arranged in the installation space and connected to the ground terminal.

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