JP2012146574A - Lighting system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lighting system capable of surely maintaining a holding state of a capacitor.SOLUTION: The lighting system 10 is provided with a light source module 23 having a capacitor 23c not directly mounted on a light source circuit board 23a, a base 4 supplying power to the light source module 23, and an insulation ring 3 connected to the base 4. The insulation ring 3 directly retains the capacitor 23c.

Description

  The present invention relates to a lighting device including a power supply circuit unit having a capacitor.

  Since LEDs (light emitting diodes) have advantages such as long life and low power consumption, they are being adopted as light sources for lighting devices. Various lighting devices using LEDs as light sources are attracting attention as the next-generation energy-saving lighting that is kind to the earth.

  For example, Patent Document 1 discloses a bulb-type illumination device (LED bulb) using an LED as a light source. The lighting device of Patent Document 1 includes a lighting device that includes a circuit board and a plurality of electronic components mounted on the circuit board. The lighting state (light emission color, light emission amount, etc.) of the LED is controlled by this lighting device.

JP 2010-129414 A (published on June 10, 2010)

  However, in the lighting device disclosed in Patent Document 1, an electrolytic capacitor, which is a relatively large component among a plurality of electronic components constituting the lighting circuit, is mounted on the surface of the circuit board. That is, the electrolytic capacitor lead wire is simply soldered to the circuit board.

  In general, a capacitor such as an electrolytic capacitor or a ceramic capacitor, which is a relatively large component, is directly mounted on a circuit board as in the lighting device of Patent Document 1. In this case, the columnar exterior portion in which the capacitor element is accommodated is only attached to the circuit board via the lead wire, and is not directly held. For this reason, there is a possibility that the holding state of the capacitor cannot be reliably maintained due to the influence of external force such as vibration acting on the exterior portion as the capacitor main body or poor connection with the circuit board due to deterioration of the lead wire.

  Therefore, the present invention has been made in view of the above-described conventional problems, and an object of the present invention is to provide an illuminating device that can reliably maintain the holding state of the capacitor.

  In order to solve the above problems, a lighting device according to the present invention supplies a light source, a power supply circuit unit that supplies power to the light source, a capacitor, and a base that supplies power from an external power supply to the power supply circuit unit. And the illuminating device provided with the connection member connected to the said nozzle | cap | die, The said connection member is provided with the holding part holding the said capacitor | condenser, It is characterized by the above-mentioned.

  According to said structure, the capacitor | condenser provided in the power supply circuit part is directly hold | maintained by the holding | maintenance part provided in the connection member connected to the nozzle | cap | die. Thereby, even if an external force such as vibration acts on the capacitor, the external force does not affect the holding of the capacitor. Therefore, the holding state of the capacitor can be reliably maintained.

  In the lighting device according to the aspect of the invention, the base includes a screwing mechanism that is screwed and connected to the connection member, and the power supply circuit unit includes a power supply line that is connected to the base and supplies power to the power supply circuit unit. It is preferable that the holding portion is formed with a first opening for inserting and holding the capacitor, and a second opening provided through the feeding line and connected to the first opening. .

  According to said structure, a nozzle | cap | die is screwed and connected to a connection member by the screwing mechanism formed in the nozzle | cap | die. Further, the holding unit for holding the capacitor has two types of openings (first opening and second opening). Moreover, the second opening for inserting and holding the power supply line connected to the base communicates with the first opening for inserting and holding the capacitor. Accordingly, when the connection member is screwed into the base in a state where the power supply line is previously disposed in the first opening, only the connection member can be rotated without rotating the power supply line. Therefore, the holding member can be attached to the base without twisting the power supply line.

  In the lighting device according to the aspect of the invention, it is preferable that the power supply line is configured to hold the capacitor in the holding portion at a communication portion where the first opening and the second opening communicate with each other.

  According to said structure, in the communication part of 1st opening and 2nd opening, the electric power feeding line penetrated by 2nd opening contact | abuts to the capacitor | condenser penetrated by 1st opening. Thereby, in addition to being inserted and held in the first opening, the capacitor is also held in the first opening at the communicating portion due to the flexibility of the power supply line. Therefore, the capacitor can be held more firmly in the holding portion (first opening).

  In the lighting device of the present invention, the capacitor is an electrolytic capacitor, the holding unit holds the electrolytic capacitor with an explosion-proof portion of the electrolytic capacitor facing the base side, and the power supply line is the It is preferable that the electrolytic capacitor is positioned by providing a space in which the explosion-proof portion can operate by contacting the electrolytic capacitor inserted through the first opening on the base side.

  According to said structure, the electrolytic capacitor is hold | maintained at the holding | maintenance part (1st opening) with the explosion-proof part facing the nozzle | cap | die side. Furthermore, the position of the electrolytic capacitor is defined by the power supply line coming into contact with the electrolytic capacitor on the base side. That is, the electrolytic capacitor positions the electrolytic capacitor so that a space that allows the explosion-proof portion to operate is formed between the base and the electrolytic capacitor. Therefore, the electrolytic capacitor can be reliably positioned without separately providing a member such as a spacer and without disturbing the operation of the electrolytic capacitor.

  In the lighting device of the present invention, the capacitor is an electrolytic capacitor, and the holding unit holds the electrolytic capacitor with the explosion-proof portion of the electrolytic capacitor facing the base, and accommodates the power supply circuit unit. A heat dissipating part that dissipates heat from a heat source, one end side of the connection member is connected to the base, and the other end side is connected to the heat dissipating part, the first opening and the second opening, A first resin part filled in a gap between the electrolytic capacitor and the power supply line; and a second resin part filled in the heat radiation part, wherein the explosion-proof part is arranged in the first resin part. It is preferable that the second resin portion is formed so as to prevent the second resin portion from flowing into the space in the base.

  According to said structure, the 1st resin part is filled in the space | gap with a 1st opening and a 2nd opening, an electrolytic capacitor, and a feeder. That is, the gap is closed by the first resin portion. Moreover, the first resin portion is formed so as to prevent the second resin portion from flowing into the space in the base where the explosion-proof portion is disposed. For this reason, the front-end | tip part of the electrolytic capacitor in which an explosion-proof part exists is arrange | positioned in the space inside a nozzle | cap | die, and is not obstruct | occluded by the 1st resin part and the 2nd resin part. Therefore, even if the capacitor is an electrolytic capacitor, the operation of the explosion-proof portion is not hindered.

  Moreover, since the 1st resin part is filled in the said space | gap, the 1st resin part fixes the holding position of an electrolytic capacitor to 1st opening. Therefore, the holding position of the electrolytic capacitor can be fixed.

  As described above, according to the present invention, there is an effect that it is possible to provide an illumination device that can reliably maintain the holding state of the capacitor.

It is a disassembled perspective view which shows schematic structure of the illuminating device of this invention. It is a perspective view of the illuminating device of this invention. It is a figure which shows the bottom part of the insulating ring in the illuminating device of this invention. It is a fragmentary sectional view which shows the lower end part of the illuminating device of this invention. It is a figure which shows the capacitor | condenser in the illuminating device of this invention, (a) shows the capacitor | condenser with which the lead wire was exposed, (b) shows the capacitor | condenser with which the lead wire was coat | covered with the insulating member. It is sectional drawing which shows the lower end part in another illuminating device of this invention.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

(Lighting device 10 according to the present invention)
FIG. 1 is an exploded perspective view showing a schematic configuration of a lighting device 10 according to the present invention. FIG. 2 is a perspective view of the illumination device 10 according to the present invention. As illustrated in FIG. 2, the lighting device 10 has a configuration in which the light emitting unit 1, the support unit 2, the insulating ring (connection member) 3, and the base 4 are arranged in this order. In the following description, for the sake of convenience, the light emitting unit 1 side will be described as the upper side (upper), and the base 4 side will be described as the lower side (lower).

  More specifically, as illustrated in FIG. 1, the illumination device 10 includes a light emitting unit 1 that includes an LED 11 serving as a light source, an LED substrate 12 on which the LED 11 is mounted, and a globe cover 13 that covers the LED 11 and the LED substrate 12. It is configured. In the illumination device 10, the plurality of LEDs 11 are evenly arranged on the LED substrate 12 made of a disk-shaped ceramic substrate.

  The globe cover 13 has a dome shape, covers the LED 11 and the LED substrate 12 inside, and is attached to a heat sink 21 described later. The globe cover 13 has a function of protecting the LED 11 and the LED substrate 12. Furthermore, the globe cover 13 also has a function of transmitting or diffusing light emitted from the LEDs 11. The globe cover 13 can be formed from, for example, glass or synthetic resin. Since the LED 11 generates a relatively large amount of heat when it is turned on, the globe cover 13 is preferably formed from a heat-resistant material. For example, milky white polycarbonate resin is suitable as a constituent material of the glove cover 13 because it is excellent in impact resistance, heat resistance, and light diffusibility.

  The support part 2 is a main body part of the lighting device 10. The light emitting unit 1 is mounted on one end (upper end) of the support unit 2, and the insulating ring 3 (connection member) is mounted on the other end (lower end). The support portion 2 includes a heat radiating plate (heat sink) 21, a heat radiating member (heat radiating portion) 22, a power supply module 23, a holder 24, a potting resin portion 25, and an O-ring 26.

  The heat sink 21 is a disk-shaped member that partitions the light emitting unit 1 and the support unit 2. The heat radiating plate 21 radiates heat generated in the light emitting unit 1 (LED 11, LED substrate 12) to the outside or conducts it to the heat radiating member 22. The LED substrate 12 is fixed to the upper surface of the heat sink 21 by screws 15. Further, a flange is formed on the outer edge portion of the upper surface of the heat radiating plate 21, and the globe cover 13 is attached.

  The heat radiating member 22 is a cylindrical hollow member, and accommodates the holder 24 holding the power supply module 23 therein. The heat radiating member 22 radiates heat from heat sources such as the LED 11 and the power supply module 23. For example, the heat radiating member 22 radiates heat conducted from the heat radiating plate 21 and heat generated in the support portion 2 to the outside. An O-ring 26 is provided on the outer edge portion of the upper surface of the heat dissipation member 22. Thus, the heat radiating plate 21 is fitted in close contact with the upper surface of the heat radiating member 22. On the other hand, the insulating ring 3 is attached to the lower end of the heat radiating member 22.

  Since both the heat radiating plate 21 and the heat radiating member 22 are intended to radiate heat, it is preferable that the heat radiating plate 21 and the heat radiating member 22 be made of a metal having good thermal conductivity. For example, the heat radiating plate 21 and the heat radiating member 22 are preferably made of a metal such as aluminum (Al), copper (Cu), iron (Fe), nickel (Ni), or an alloy thereof. The heat radiating plate 21 and the heat radiating member 22 may be made of an industrial material such as aluminum nitride (AlN) or silicone carbide (SiC), or may be made of a synthetic resin such as a high thermal conductive resin.

  The power supply module 23 is a power supply circuit unit that supplies power to the light emitting unit 1 (LED 11, LED substrate 12). The power supply module 23 is also a control circuit unit that controls the lighting state (emission color, emission amount, etc.) of the LED 11. The power supply module 23 is mounted in the holder 24 and accommodated in the heat dissipation member 22. The power module 23 includes a power circuit board 23a and a plurality of electronic components 23b mounted on both surfaces of the power circuit board 23a.

  The power circuit board 23a is a printed board having wiring. The electronic component 23 b is a circuit component that controls lighting of the LED 11. The power supply circuit board 23a is preferably made of a metal having good thermal conductivity such as aluminum in order to improve heat dissipation. The power circuit board 23a may be made of a nonmetallic member such as a glass epoxy material or may be made of ceramics.

  The electronic component 23b is, for example, a circuit component for performing lighting control, light adjustment, or color adjustment of the LED 11. Specifically, the electronic component 23b is an electrolytic capacitor, a ceramic capacitor, a current transformer, a film capacitor, a REC (rectifier element, diode bridge), a resistor, a transistor, a switching element, or the like.

  The holder 24 holds the power supply module 23 inside. That is, the holder 24 is a PCB holder. An opening is formed in the side surface of the holder 24, and the power supply module 23 is disposed with the electronic component 23 b facing the opening. Thereby, the heat generated in the electronic component 23b is efficiently conducted to the heat dissipation member 22 through the opening. One end of the holder 24 is fixed to the heat sink 21 by screws 27a, and the other end of the holder 24 is fixed to the insulating ring 3 by screws 27b. The holder 24 is covered with the heat radiating member 22. The holder 24 is preferably formed from a material having electrical insulation and thermal conductivity. For example, the holder 24 can be formed from PBT (polybutylene terephthalate), acrylic resin, ABS resin, polyamide resin, or the like.

  The potting resin portion 25 is filled in an internal space formed by the support portion 2 and the insulating ring 3. Thereby, the power supply module 23 is electrically insulated and fixed in the heat dissipation member 22. The potting resin portion 25 conducts heat from the power supply module 23 generated in the support portion 2 and heat from the LED 11 to the heat radiating member 22. For this reason, it is preferable that the potting resin part 25 is formed from resin with high heat conductivity. For example, the potting resin portion 25 can be formed from a synthetic resin such as a heat-resistant silicone resin, an epoxy resin, or a urethane resin having good thermal conductivity and electrical insulation.

  The insulating ring 3 is made of an electrically insulating material, and holds a capacitor 23 c provided therein independently (isolated) from the power supply module 23. The upper end of the insulating ring 3 is attached to the lower end of the heat dissipation member 22. The insulating ring 3 has a thread formed on the outer surface, and is screwed into the base 4 to be connected.

  The base 4 is a metal fitting for external connection, for example, a general E26 type metal fitting. That is, the base 4 supplies power from an external power supply (not shown) to the power supply module 23. On the inner surface of the base 4, a thread that engages with a thread formed on the outer surface of the insulating ring 3 is formed. Thereby, the insulating ring 3 is screwed and connected. That is, the screw thread formed on the inner surface of the base 4 is a screwing mechanism for screwing the base 4 to the insulating ring 3 and connecting it. A screw thread is also formed on the outer surface of the base 4. Thereby, the illuminating device 10 can be attached by being screwed into a socket provided on the ceiling or the like. Although not shown, an insulating layer is formed on the inner side surface of the base 4, and electrical insulation between the capacitor 23 c in the insulating ring 3 and the base 4 is ensured.

  The illumination device 10 includes three pairs of electric wires 5a and 5b, 6a and 6b, and 7a and 7b. In FIG. 1, for convenience, the electric wires 5 a, 5 b, 6 a, 6 b, 7 a, 7 b are shown outside each member, but cannot be confirmed in appearance as in FIG. 2.

  Specifically, one end of the electric wires 5 a and 5 b is connected to the power supply module 23. A through hole (not shown) is formed in the heat radiating plate 21, and a sleeve 14 is provided on the upper surface (surface on the light emitting unit 1 side) of the heat radiating plate 21. The other ends of the electric wires 5a and 5b are connected to the LED substrate 12 through the through holes and the sleeve 14.

  One end of the electric wires 6 a and 6 b is connected to the power supply module 23. The other ends of the electric wires 6 a and 6 b are connected to the base 4 through the inside of the support portion 2 (holder 24, heat dissipation member 22) and insulating ring 3. The end of the electric wire 6 a on the base side is connected (temporarily fixed) to the eyelet part at the bottom of the base 4. The end of the electric wire 6 b on the base side is soldered to the inner surface of the base 4. The electric wires 6 a and 6 b are power supply lines for supplying power to the power supply module 23.

  One end of each of the electric wires 7 a and 7 b is connected to the power supply module 23. The other ends of the electric wires 7a and 7b are connected to a capacitor 23c held inside the insulating ring 3 through the inside of the support portion 2 (holder 24, heat dissipation member 22).

  With such a configuration, when the lighting device 10 is attached by screwing the base 4 into a socket or the like of a commercial power source (external power source), the voltage is applied to the power supply module 23 via the electric wires 6a and 6b connected to the base 4. Is supplied. Then, appropriate voltages are supplied to the LED substrate 12 via the electric wires 5a and 5b and to the capacitor 23c via the electric wires 7a and 7b, respectively. Thereby, LED11 (illuminating device 10) lights. Since the illuminating device 10 includes the LED 11 as a light source, a long life and low power consumption can be realized.

  In the lighting device 10, the lighting state of the LED 11 is controlled by supplying power to the LED 11 through the power supply module 23. For this reason, if the electronic component 23b and the capacitor | condenser 23c which perform lighting control, light control, or toning of LED11 do not function normally, it will have a bad influence on the lighting state of LED11. As a result, the reliability of the lighting device 10 is reduced.

  Therefore, the lighting device 10 includes an insulating ring 3 that holds a capacitor 23c that is not directly mounted on the power circuit board 23a. Since the electronic component 23b and the capacitor 23c are a part of the power supply module 23, they are generally mounted on the power supply circuit board 23a. Also in the lighting device 10, the electronic component 23b is directly mounted on the power circuit board 23a. However, the capacitor 23c is indirectly connected to the power circuit board 23a through the electric wires 7a and 7b.

  The insulating ring 3 directly holds an exterior portion 23f that accommodates therein a capacitor element that is a main body of the capacitor 23c that is intentionally isolated from the power circuit board 23a. Thereby, even if an external force such as vibration acts on the capacitor 23c, the external force does not affect the holding of the capacitor 23c. Therefore, the holding state of the capacitor 23c can be reliably maintained. Therefore, the connection failure of the capacitor 23c does not occur due to the external force, and the highly reliable lighting device 10 can be provided.

  Since the illumination device 10 uses the LED 11 as a light source, the amount of heat generated is relatively large. Furthermore, there are components that easily generate heat in the electronic component 23b. For example, a transformer or the like corresponds to the electronic component 23b that easily generates heat, and the surface temperature may exceed 90 ° C. However, since the bulb-type lighting device 10 is small, there is almost no extra space inside. For this reason, the plurality of electronic components 23b are mounted with high density on the power circuit board 23a on the layout. As a result, the electronic component 23b that easily generates heat and the electronic component 23b having low heat resistance are arranged close to each other. For this reason, the lifetime of the electronic component 23b with low heat resistance tends to be shortened.

  When the capacitor 23c is, for example, an electrolytic capacitor, the heat resistant temperature of the capacitor 23c is relatively low. For this reason, if the capacitor | condenser 23c is hold | maintained by the insulating ring 3 connected to the nozzle | cap | die 4, the capacitor | condenser 23c can be isolated from heat sources, such as the electronic component 23b (heat-generating component) which is easy to generate | occur | produce heat on the power circuit board 23a. . Therefore, there is an advantage that the temperature rise of the capacitor 23c can be suppressed. The type of the capacitor 23c held by the insulating ring 3 is not particularly limited. The capacitor 23c may be, for example, an electrolytic capacitor, a ceramic capacitor, a film capacitor, or the like.

  Specifically, the electrolytic capacitor has a feature that the size is small even if the capacity is increased, and is greatly different from the ceramic capacitor whose size is increased in proportion to the capacity. The large-capacity electrolytic capacitor has a function of reducing the influence of the inrush current from the phase dimmer, or reducing the ripple of the driving current of the LED 11 to prevent the light emission state from flickering. If the life of the electrolytic capacitor comes before the LED 11 having a long life, symptoms such as a decrease in brightness and flickering appear due to a decrease in the capacity of the electrolytic capacitor. Therefore, in order to realize the long life of the lighting device 10, an electrolytic capacitor is indispensable, and the life of the electrolytic capacitor must be extended.

  However, since the electrolytic capacitor uses an electrolytic solution, the heat resistance is particularly low. For example, some commercially available electrolytic capacitors have an ability of about 10,000 hours at an operating temperature of 105 ° C. Moreover, it is known that the lifetime of the electrolytic capacitor has a correlation with the operating temperature. Generally, when the operating temperature is lowered by 10 ° C., the lifetime of the capacitor is doubled. However, in an environment where the internal temperature exceeds 80 ° C., as in the lighting device 10 using the LED 11 as a light source, it is difficult to ensure the life of the electrolytic capacitor to 40,000 h, which is the product life of the lighting device 10 (the life of the LED 11). It is becoming a state. Thus, the electrolytic capacitor life is easily influenced by the ambient temperature.

  Therefore, if the capacitor 23c is an electrolytic capacitor having low heat resistance, it is preferable to keep it away from a heat source such as the power supply module 23. The capacitor 23c is held inside the insulating ring 3 in the vicinity of the base 4 where the temperature is relatively difficult to rise. . That is, the electrolytic capacitor is disposed at a physical distance from the heat source such as the LED 11 and the LED substrate 12 that generate heat and the power supply module 23 (electronic component 23b) that generates heat. For this reason, it is possible to prevent the temperature of the electrolytic capacitor from rising due to the heat generated during the operation of the lighting device 10. That is, even if the lighting device 10 is used for a long period of time, it is possible to prevent the performance degradation (life shortening) of the electrolytic capacitor. Therefore, it is possible to realize the lighting device 10 with higher reliability.

  The holding method and holding position of the capacitor 23c by the insulating ring 3 are not particularly limited. However, it is preferable that the capacitor 23c be held in a position as isolated as possible from heat sources such as the LED 11 and the LED board 12 that generate heat and the power supply module 23 (electronic component 23b) that generates heat. For example, as shown in FIG. 3, the capacitor 23 c is preferably held at the bottom of the insulating ring 3. FIG. 3 is a view showing the bottom of the insulating ring 3 in the lighting device 10. In FIG. 3, the front side of the paper is the light emitting unit 1 side, and the back side is the base 4 side.

  As shown in FIG. 3, two types of openings (first opening 31 and second openings 32 a and 32 b) are formed at the bottom of the insulating ring 3. The first opening 31 is substantially the same size as the outer diameter of the capacitor 23 c and holds the capacitor 23 c inserted into the first opening 31. That is, the first opening 31 is a hole for inserting and holding the cylindrical exterior portion 23f that accommodates the capacitor element that is the main body of the capacitor 23c. Thus, the first opening 31 functions as a holding unit that holds the capacitor 23c.

  On the other hand, the second openings 32a and 32b have substantially the same size as the outer diameters of the cross sections of the electric wires 6a and 6b, and hold the electric wires 6a and 6b inserted into the second openings 32a and 32b. That is, the second openings 32a and 32b are holes for inserting and holding the power supply wires 6a and 6b. The two second openings 32 a and 32 b are formed at point-symmetric positions in the center of the first opening 31.

  The second openings 32a and 32b may be provided without being communicated with the first opening 31, but the second openings 32a and 32b may be communicated with the first opening 31 as shown in FIG. preferable. As described above, in the illumination device 10, the base 4 is screwed and connected to the insulating ring 3 by a screwing mechanism (thread) formed on the base 4. Therefore, when the second openings 32 a and 32 b are not communicated with the first opening 31, one end of the insulating ring 3 is connected to the base 4 when the insulating ring 3 is screwed to the base 4. The electric wires 6a and 6b also rotate. Therefore, the electric wires 6a and 6b are twisted. On the other hand, when the second openings 32 a and 32 b communicate with the first opening 31, the insulating ring 3 is screwed into the base 4 with the electric wires 6 a and 6 b disposed in the first opening 31 in advance. Then, only the insulating ring 3 can be rotated without rotating the electric wires 6a and 6b. Then, after connecting the insulating ring 3 and the base 4, the electric wires 6 a and 6 b can be moved from the first opening 31 and inserted into the second openings 32 a and 32 b to be held. Accordingly, the insulating ring 3 can be attached to the base 4 without the electric wires 6a and 6b being twisted.

  Further, as shown in FIG. 3, when the second openings 32a and 32b communicate with the first opening 31, the communication portions 32c where the first opening 31 and the second openings 32a and 32b are connected have the electric wires 6a and 6b. And the exterior part 23f of the capacitor | condenser 23c penetrated by the 1st opening 31 will contact | abut. That is, the electric wires 6 a and 6 b and the capacitor 23 c are in contact with each other at the communication portion 32 c in the opening portion of the insulating ring 3. Thereby, in addition to being inserted and held in the first opening 31 of the insulating ring 3, the capacitor 23c is held in the first opening 31 by the communication portion 32c due to the flexibility (pressing force) of the electric wires 6a and 6b. Is done. That is, the electric wires 6a and 6b also serve to hold the capacitor 23c in the first opening 31. Therefore, the capacitor 23c can be held in the first opening 31 more firmly.

  When the capacitor 23c is an electrolytic capacitor, an explosion-proof portion (explosion-proof valve) 23e is formed at the tip of the electrolytic capacitor in order to prevent explosion due to evaporation of the electrolytic solution due to rapid heating. In an LED bulb such as the lighting device 10, an electrolytic capacitor having a diameter of 8 mm or less is usually used. In order for the explosion-proof portion 23e of the electrolytic capacitor to function, a space of about 2 mm or more is usually required. Therefore, the lighting device 10 has a configuration that does not hinder the operation of the explosion-proof portion 23e even if the capacitor 23c is an electrolytic capacitor. FIG. 4 is a partial cross-sectional view showing a lower end portion of the lighting device 10.

  In FIG. 4, the capacitor 23c (electrolytic capacitor) is held with the explosion-proof portion 23e formed at the tip (lower end) on the base 4 side facing the base 4 side. Specifically, the tip (lower end) of the capacitor 23 c protrudes from the bottom of the insulating ring 3 toward the base 4 and is disposed in the space S inside the base 4. The potting resin portion 25 is filled in an internal space formed by the heat radiating member 22 and the insulating ring 3, and is not formed in the space S. Moreover, as surrounded by a broken-line circle in FIG. 4, the tip end portion of the capacitor 23c on the base 4 side is in contact with the electric wire 6b. The electric wire 6b used for the illuminating device 10 is usually about 2 mm in thickness.

  For this reason, if the tip of the capacitor 23c on the base side is in contact with the electric wire 6b, an interval of at least 2 mm can be provided between the inner peripheral surface of the base 4 and the explosion-proof portion 23e functions. The space required for the explosion-proof portion 23e is formed. That is, the electric wire 6b serves as a stopper that restricts the insertion of the capacitor 23c into the base 4 until the explosion-proof portion 23e becomes inoperable, and the position of the tip of the capacitor 23c is reliably defined by the electric wire 6b.

  Thus, the electric wire 6b abuts the capacitor 23c on the base 4 side, thereby defining the position of the capacitor 23c. That is, the electric wire 6b positions the capacitor 23c so that a space that allows the explosion-proof portion 23e to operate is formed between the base 4 and the capacitor 23c. Therefore, it is possible to reliably position the capacitor 23c without separately providing a member such as a spacer and without disturbing the operation of the explosion-proof portion 23e of the capacitor 23c.

  In FIG. 4, the tip of the capacitor 23c is in contact with the electric wire 6b, but may be in contact with the electric wire 6a connected to the side surface of the base 4 or in contact with both of the electric wires 6a and 6b. May be. However, the electric wire 6 b is connected to the eyelet portion at the lower end portion of the base 4. For this reason, it is preferable that the front-end | tip part of the capacitor | condenser 23c is contacting the electric wire 6b. Thereby, the space | interval required in order for the explosion-proof part 23e to function can be formed reliably. For this reason, even if the capacitor | condenser 23c is an electrolytic capacitor, operation | movement of the explosion-proof part 23e is not prevented.

  As described above, in the configuration of FIG. 4, the thickness (thickness) of the electric wire 6b not only defines the distance (the position of the capacitor 23c) between the capacitor 23c and the eyelet part (bottom part) of the base 4 but also the insulation. The capacitor 23c is also held by the flexibility (pressing force) of the electric wires 6a and 6b at the opening of the ring 3 (communication portion 32c).

  The depth at which the capacitor 23c is embedded on the base 4 side is not particularly limited. However, the potting resin portion 25 is not formed in the space S inside the base 4. For this reason, as the depth of embedding the capacitor 23c in the space S is increased, the volume accommodated on the cap 4 side of the capacitor 23c is increased. Thereby, the contact area of the capacitor | condenser 23c and the potting resin part 25 decreases. As a result, heat conduction to the capacitor 23c via the potting resin portion 25 is reduced. Therefore, it is possible to reliably prevent the heat of the capacitor 23c from rising. On the other hand, if the depth of embedding the capacitor 23c is shallow, the space S can be reliably provided between the lower end portion (tip portion on the base 4 side) of the capacitor 23c and the bottom portion of the base 4. For this reason, even if the capacitor | condenser 23c is an electrolytic capacitor, operation | movement of the explosion-proof part 23e is not prevented.

  Furthermore, as shown in FIG. 4, in the lighting device 10, the potting resin portion 25 is formed of a first resin portion 25 a and a second resin portion 25 b. The first resin portion 25a is filled in a gap between the first opening 31 and the second openings 32a and 32b (see FIG. 3) and the capacitor 23c and the electric wires 6a and 6b. Thus, the first resin portion 25a fixes the holding position of the capacitor 23c to the bottom portion (first opening 31) of the insulating ring 3. Therefore, the capacitor 23c can be held in the first opening 31 more firmly. Further, since the gap is closed by the first resin portion 25a, the resin of the second resin portion 25b does not flow from the gap to the base 4 side.

  On the other hand, the second resin portion 25b may cover at least the power supply module 23 (not shown in FIG. 4). Here, the second resin portion 25b is laminated on the first resin portion 25a and filled in the entire area inside the support portion 2 and the insulating ring 3 (that is, inside the heat radiating member 22). The member 22 is connected via the second resin portion 25b so as to be able to conduct heat. Thereby, the electronic component 23b mounted on the power circuit board 23a can be protected by the second resin portion 25b. Further, the heat generated in the power supply module 23 can be conducted to the heat radiating member 22 through the second resin portion 25b to be radiated.

  The ratio of the 1st resin part 25a and the 2nd resin part 25b is not specifically limited. However, the first resin portion 25a only needs to fix the capacitor 23c to the insulating ring 3, and when filling, the first opening 31 and the second openings 32a, 32b, and between the capacitor 23c and the electric wires 6a, 6b. The first resin portion 25a is as small as possible (occupation ratio of the first resin portion 25a << occupation ratio of the second resin portion 25b) so as not to flow from the gap into the base 4 (in the space S) as much as possible. It is preferable.

  Further, the first resin portion 25a is preferably formed so as to fill the gap (not shown) between the capacitor 23c and the insulating ring 3 (first opening 31, second openings 32a, 32b). . Thereby, when forming the 2nd resin part 25b on the 1st resin part 25a, the 2nd resin part 25b does not flow into the nozzle | cap | die 4 side through the said space | gap. Therefore, the space S can be reliably provided between the lower end portion of the capacitor 23 c and the bottom portion of the base 4. For this reason, even if the capacitor | condenser 23c is an electrolytic capacitor, operation | movement of the explosion-proof part 23e is not prevented.

  Specifically, the lighting device 10 has a potting structure in which the periphery of the power supply module 23 is covered with a potting resin portion 25 in order to conduct heat from the electronic component 23 b that generates heat to the heat dissipation member 22. In this case, it is necessary to take measures so that the explosion-proof portion (explosion-proof valve) 23e of the electrolytic capacitor is not covered with the potting resin. However, in the lighting device 10, a small amount of the first resin portion 25 a fills and closes the gap between the first opening 31 and the second openings 32 a and 32 b formed at the bottom of the capacitor 23 c and the insulating ring 3. . For this reason, the front-end | tip part of the electrolytic capacitor in which the explosion-proof part 23e exists is arrange | positioned in the space S inside the nozzle | cap | die 4, and is not obstruct | occluded by the 1st resin part 25a and the 2nd resin part 25b. Therefore, even if the capacitor 23c is an electrolytic capacitor, the operation of the explosion-proof portion 23e is not hindered.

  Incidentally, as described above, in the illumination device 10, the capacitor 23c is not directly mounted on the power supply circuit board 23a. The capacitor 23c and the power circuit board 23a are electrically connected via the electric wires 7a and 7b. Although this connection method is not particularly limited, for example, it can be configured as shown in FIG. 5A and 5B are diagrams showing the capacitor 23c in the lighting device 10, where FIG. 5A shows the capacitor 23c with the lead wire 23d exposed, and FIG. 5B shows the capacitor 23c with the lead wire 23d covered with the insulating member 9. .

  As shown in FIG. 5A, the capacitor 23c includes a columnar exterior part (exterior case) 23f in which the capacitor element is accommodated, and two lead wires 23d that are exposed and extend from the exterior part 23f. ing. The exterior portion 23f can be said to be a main body portion of the capacitor 23c. For example, when the capacitor 23c is an electrolytic capacitor, an electrolytic solution or the like is accommodated in the exterior portion 23f. The capacitor 23 c is directly held by the first opening 31 of the insulating ring 3 at the exterior portion 23 f.

  As shown in FIG. 5A, the lead wire 23d of the capacitor 23c is connected to a highly flexible electric wire that is insulation-coated with a crimp terminal called a ribbon terminal 8 or the like. The electric wires 7a and 7b are soldered to the power supply circuit board 23a that is connected to the ribbon terminal 8 and separated to a position where it is difficult to thermally influence the capacitor 23c. As described above, the capacitor 23c is not directly soldered to the power circuit board 23a by the lead wire 23d extending from the exterior portion 23f of the capacitor 23c, and the electric wires 7a and 7b are connected to the lead wire 23d, and the electric power is supplied by the electric wires 7a and 7b. By connecting to the circuit board 23a, electrical connection is ensured while the spatial distance between the power supply module 23 and the capacitor 23c is increased.

  The lead wires of the electronic component 23b mounted on the power circuit board 23a are soldered in a state where they are pierced into the power circuit board 23a. For this reason, there is no possibility that the lead wires of the electronic component 23b are in contact with each other or entangled. However, as shown in FIG. 5A, when the lead wire 23d of the capacitor 23c is exposed, the lead wires 23d may come into contact with each other to be short-circuited or entangled.

  Therefore, as shown in FIG. 5B, it is preferable that the lead wire 23d of the capacitor 23c, the ribbon terminal 8, and the ends of the electric wires 7a and 7b on the ribbon terminal 8 side are covered with an insulating member 9. That is, in FIG. 5B, the crimp terminal connection portion (ribbon terminal 8 portion) between the lead wire 23d of the capacitor 23c and the electric wires 7a and 7b is insulated. Thereby, a short circuit due to contact between the lead wires 23d can be avoided. The insulating member 9 is not particularly limited as long as it has insulating properties, and is preferably a heat shrinkable tube. Thereby, the end part of the lead wire 23d covered with the heat shrinkable tube, the ribbon terminal 8, and the electric wires 7a and 7b can be firmly fixed. Therefore, a short circuit due to contact between the lead wires can be avoided more reliably.

  The illuminating device 10 of this embodiment can also be configured as shown in FIG. FIG. 6 is a cross-sectional view showing the lower end of another illumination device 10a of the present invention. The basic configuration of the illumination device 10a is substantially the same as that of the illumination device 10. Below, the illuminating device 10a is demonstrated centering on difference with the illuminating device 10. FIG.

  In the illumination device 10a, a part of the outer surface of the capacitor 23c is covered with the insulating member 28. Further, a silicone resin (silicone RTV) 29 is formed as a sealing material in the portion where the insulating member 28 is formed. Thus, the capacitor 23c is fixed to the insulating ring 3. In the illumination device 10a, since the silicone resin 29 is formed, the potting resin portion 25 is not divided into the first resin portion 25a and the second resin portion 25b. The insulating member 28 is preferably a heat-shrinkable tube like the insulating member 9. As a result, the capacitor 23c is firmly fixed. In the lighting device 10 a, the portion covered with the insulating member 28 is larger than the opening formed at the bottom of the insulating ring 3. For this reason, the capacitor | condenser 23c is not inserted in the nozzle | cap | die 4 side any more. That is, the insulating member 28 serves as a stopper, and the position of the tip portion of the capacitor 23c is reliably defined by the insulating member 28. Therefore, the capacitor 23c held by the insulating ring 3 can be reliably positioned without separately providing a member such as a spacer. Furthermore, the space S can be reliably provided between the lower end portion of the capacitor 23 c and the bottom portion of the base 4. For this reason, even if the capacitor | condenser 23c is an electrolytic capacitor, operation | movement of the explosion-proof part 23e is not prevented.

  As described above, in the lighting devices 10 and 10a, not all of the plurality of electronic components 23b and the capacitor 23c constituting the power module 23 are mounted on the power circuit board 23a, but the capacitor 23c is mounted on the power circuit board 23a. Not. Further, the capacitor 23 c that is not mounted on the power circuit board 23 a is held by the insulating ring 3. Therefore, it is possible to reliably hold the capacitor 23c that is not mounted on the power supply circuit board 23a and provide a highly reliable lighting device.

  In addition, in this embodiment, the illuminating device 10 provided with LED11 as a light source was demonstrated. However, the light source is not limited to the LED 11 and may be various light emitting elements such as a phosphor, an electroluminescence element, and a semiconductor light source. Moreover, what is necessary is just to set the color of a light source arbitrarily.

  In the present embodiment, the bulb-type (A-type) lighting device 10 that approximates the shape of a general incandescent bulb has been described. However, the illuminating device of the present invention is configured as a ref-shaped light bulb-shaped illuminating device (R-type), a ball-shaped light-bulb-shaped illuminating device (G-type), a cylindrical light-bulb-shaped illuminating device (T-shaped), or the like. May be.

(2) Manufacturing Method of Lighting Device Next, a manufacturing example of the lighting device 10 will be described with reference to FIGS. The method for manufacturing the lighting device 10 includes a step of holding the capacitor 23c not mounted on the power circuit board 23a in the first opening 31 (holding portion) of the insulating ring 3 without mounting the electronic component 23b on the power circuit board 23a. It only has to be.

  Specifically, first, one end of the electric wire 6 b is soldered to the eyelet portion of the base 4, and one end of the electric wire 6 a is soldered to the inner side surface of the base 4. Next, after the electric wires 6 a and 6 b are arranged in the first opening 31 of the insulating ring 3, the insulating ring 3 in which the electric wires 6 a and 6 b are arranged in the first opening 31 is screwed into the base 4.

  In the lighting device 10, two types of openings (first opening 31 and second openings 32 a and 32 b) are formed in the insulating ring 3. Moreover, the second openings 32a and 32b holding the electric wires 6a and 6b communicate with the first opening 31 holding the capacitor 23c. As a result, when the insulating ring 3 is screwed and connected to the base 4 with the electric wires 6a and 6b previously disposed in the first opening 31, only the insulating ring 3 is rotated without rotating the electric wires 6a and 6b. Can be made. Accordingly, the insulating ring 3 can be attached to the base 4 without the electric wires 6a and 6b being twisted.

  Next, the insulating ring 3 and the capacitor 23c not mounted on the power circuit board 23a are held in the insulating ring 3. That is, the electric wires 6 a and 6 b arranged in the first opening 31 are held in the second opening 32 a communicating with the first opening 31. Then, the capacitor 23 c is inserted into the first opening 31. The capacitor 23c is inserted into the first opening 31 until the tip end portion (explosion-proof portion 23e) on the base 4 side contacts the electric wire 6b. As a result, a space S that allows the explosion-proof portion 23e to operate is reliably formed between the lower end portion of the capacitor 23c and the bottom portion of the base 4. That is, the electric wire 6b serves as a stopper, and the position of the tip portion (explosion-proof portion 23e) of the capacitor 23c is reliably defined by the electric wire 6b. Therefore, the capacitor 23c held by the insulating ring 3 can be reliably positioned without separately providing a member such as a spacer. In this way, the lower end portion of the capacitor 23 c does not reach the eyelet portion at the bottom of the base 4.

  Next, in order to fix the capacitor 23c held by the insulating ring 3 to the insulating ring 3, the insulating ring 3 is filled with a small amount of potting resin to form the first resin portion 25a. The 1st resin part 25a is formed so that the space | gap (gap) between the capacitor | condenser 23c and the insulating ring 3 (1st opening 31, 2nd opening 32a, 32b) may be filled up. The potting resin forming the first resin portion 25a leaks from the gap between the capacitor 23c or the electric wires 6a, 6b and the first opening 31 and the second openings 32a, 32b formed in the insulating ring 3, and the cap 4, the insulating ring 3 is filled so that the lower end portion of the capacitor 23 c is not covered with the potting resin even if it accumulates inside the capacitor 4.

  Next, after the curing reaction of the potting resin of the first resin portion 25a proceeds and the capacitor 23c and the insulating ring 3 are sufficiently bonded and fixed, the holder 24 holding the power supply module 23 is fixed to the insulating ring 3. . Next, the electric wires 7a and 7b connected to the capacitor 23c and the electric wires 6a and 6b connected to the base 4 are connected to the power circuit board 23a.

  Next, a potting resin is filled in the entire area inside the insulating ring 3 and the support portion 2 (heat radiation member 22) to form the second resin portion 25b laminated on the first resin portion 25a. Thereby, the second resin portion 25 b covers the power supply module 23. For this reason, the electronic component 23b mounted on the power supply module 23 can be protected by the second resin portion 25b. Further, the heat generated in the power supply module 23 can be conducted to the heat radiating member 22 through the second resin portion 25b to be radiated.

  As described above, in this embodiment, the potting resin is injected into the insulating ring 3 and the support portion 2 in two steps. That is, first, in order to form the first resin portion 25a, a small amount of potting resin is injected to close a gap formed between the insulating ring 3 and the capacitor 23c. Thereby, the potting resin that forms the second resin portion 25 b to be injected later does not enter the inside of the base 4, and a space S is formed between the capacitor 23 c and the bottom of the base 4. Thus, by potting leaving the space S inside the base 4, even if the capacitor 23 c is an electrolytic capacitor, the operation (explosion-proof valve operation) of the explosion-proof portion 23 e is not affected. Note that the potting resin forming the first resin portion 25a and the second resin portion 25b may be the same resin or different resins.

  Finally, the illuminating device 10 can be manufactured by mounting the light emitting unit 1 on the support unit 2 (heat radiation plate 21).

  As described above, according to the method for manufacturing the lighting device 10 of the present embodiment, the capacitor 23c that is not mounted on the power circuit board 23a is directly held by the insulating ring 3 (first opening 31). Thereby, even if an external force such as vibration acts on the capacitor 23c, the external force does not affect the holding of the capacitor 23c. Therefore, it is possible to manufacture the lighting device 10 that can reliably maintain the holding state of the capacitor 23c. The lighting device 10a can also be manufactured in the same manner as the lighting device 10, and thus the description thereof is omitted.

  The lighting device according to the present invention includes a light emitting unit (light source) and a power circuit unit that supplies power to the light emitting unit, and the power circuit unit includes a circuit board and a plurality of electronic components. A configuration in which at least one of the electronic components is not mounted on the circuit board and includes a holding member (insulating ring 3) that holds the electronic component not mounted on the circuit board may be employed.

  According to the above configuration, not all of the plurality of electronic components constituting the power supply circuit unit are mounted on the circuit board, and some of the electronic components (capacitors) are not mounted on the circuit board. Further, the electronic component that is not mounted on the circuit board is held by the holding member. Therefore, it is possible to reliably hold an electronic component that is not mounted on the circuit board and provide a highly reliable lighting device.

  The holding member only needs to hold at least a part of the electronic component that is not mounted on the circuit board.

  An illumination device of the present invention includes a base to which the holding member is screwed and a power supply line having one end connected to the base, and the holding member is an electronic that is not mounted on the circuit board. A first opening for holding a component and a second opening for holding the power supply line are formed, and the first opening and the second opening may communicate with each other.

  According to said structure, two types of opening (1st opening, 2nd opening) is formed in the holding member screwed together by a nozzle | cap | die. In addition, the second opening that holds the power supply line communicates with the first opening that holds the electronic component that is not mounted on the circuit board. Accordingly, when the holding member is screwed into the base in a state where the feeding line is disposed in the first opening in advance, only the holding member can be rotated without rotating the feeding line. Therefore, the holding member can be attached to the base without twisting the power supply line.

  In the illuminating device of the present invention, it is preferable that a tip end portion of the electronic component held by the holding member is in contact with the power supply line.

  According to the above configuration, since the power supply line is in contact with the tip portion on the base side of the electronic component held by the holding member, the position of the electronic component is defined by the power supply line. Therefore, the electronic component held by the holding member can be reliably positioned without separately providing a member such as a spacer.

  In the illuminating device of the present invention, it is preferable that the electronic component held by the holding member is in contact with the power supply line at a portion where the first opening and the second opening are formed (communication portion 32c).

  According to the above configuration, the power supply line and the electronic component held by the holding member are in contact with each other at the position of the opening (communication portion 32c) of the holding member. Thus, the electronic component is held by the flexibility of the power supply line in addition to being held in the first opening formed in the holding member. That is, the feeder line also plays a role of holding the electronic component. Accordingly, the electronic component can be held more firmly.

  The lighting device of the present invention preferably includes a first resin portion that fixes the electronic component held by the holding member to the holding member, and a second resin portion that covers the power supply circuit portion.

  According to said structure, a 1st resin part fixes the holding position of the electronic component by a holding member. Thereby, an electronic component can be hold | maintained more firmly. On the other hand, the second resin portion covers the power supply circuit portion. Thereby, the electronic component mounted in the electronic circuit part can be protected by the second resin part. Moreover, the heat generated in the power supply circuit unit can be radiated through the second resin.

  In order to solve the above problems, a method for manufacturing a lighting device according to the present invention includes a light emitting unit (light source) and a power supply circuit unit that supplies power to the light emitting unit, and the power supply circuit unit includes a circuit board and In a method for manufacturing a lighting device including a plurality of electronic components, a step of holding at least a part of the electronic components on a circuit board and holding the electronic components not mounted on the circuit board on a holding member (insulating ring 3). It is characterized by including.

  According to the above method, not all of the plurality of electronic components constituting the power supply circuit unit are mounted on the circuit board, and some of the electronic components are not mounted on the circuit board. Further, the electronic component that is not mounted on the circuit board is held by the holding member. Therefore, it is possible to reliably hold an electronic component that is not mounted on the circuit board and manufacture a highly reliable lighting device.

  In the lighting device manufacturing method of the present invention, the holding member holds a first opening that holds an electronic component that is not mounted on the circuit board, and a power supply line that has one end connected to the base. Two openings are formed, and the first opening and the second opening communicate with each other, the step of arranging the power supply line in the first opening, and the power supply line in the first opening. And a step of screwing the holding member into the base.

  According to said method, two types of opening (1st opening, 2nd opening) is formed in the holding member screwed together by a nozzle | cap | die. In addition, the second opening that holds the power supply line communicates with the first opening that holds the electronic component that is not mounted on the circuit board. Accordingly, when the holding member is screwed into the base in a state where the feeding line is disposed in the first opening in advance, only the holding member can be rotated without rotating the feeding line. Therefore, the holding member can be attached to the base without twisting the power supply line.

  In the manufacturing method of the lighting device of the present invention, the step of forming the first resin portion for fixing the electronic component held by the holding member to the holding member, and the power supply circuit portion after forming the first resin portion. And forming a second resin portion to be coated.

  According to said method, a 1st resin part fixes the holding position of the electronic component by a holding member. Thereby, an electronic component can be hold | maintained more firmly. On the other hand, the second resin portion covers the power supply circuit portion. Thereby, the electronic component mounted in the electronic circuit part can be protected by the second resin part. Moreover, the heat generated in the power supply circuit unit can be radiated through the second resin.

  The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope shown in the claims. That is, embodiments obtained by combining technical means appropriately modified within the scope of the claims are also included in the technical scope of the present invention.

3 Insulation ring (connection member)
4 Cap 6a, 6b Electric wire (feed line)
10, 10a Illumination device 11 LED (light source)
22 Heat dissipation member (heat dissipation part)
23 Power supply module (Power supply circuit)
23b Electronic component 23c Capacitor (electrolytic capacitor)
23e Explosion-proof part 24 Holder (heat dissipation part)
25a First resin part 25b Second resin part 31 First opening (holding part)
32a, 32b 2nd opening 32c Communication part S space (space in which an explosion-proof part can operate | move, space in a nozzle | cap | die)

Claims (5)

A light source;
A power supply circuit unit for supplying power to the light source and having a capacitor;
A base for supplying power from an external power source to the power supply circuit unit;
In a lighting device comprising a connection member connected to the base,
The connection device includes a holding unit that holds the capacitor. The base includes a screwing mechanism to be screwed and connected to the connection member,
The power supply circuit unit includes a power supply line connected to the base and supplying power to the power supply circuit unit,
In the holding part,
A first opening for inserting and holding the capacitor;
2. The lighting device according to claim 1, wherein a second opening is formed through the power supply line and provided to communicate with the first opening.   The lighting device according to claim 2, wherein the power supply line is configured to hold the capacitor in the holding portion at a communication portion where the first opening and the second opening communicate with each other. The capacitor is an electrolytic capacitor;
The holding portion holds the electrolytic capacitor with the explosion-proof portion of the electrolytic capacitor facing the base side,
The power supply line contacts the electrolytic capacitor inserted into the first opening on the base side, thereby providing a space in which the explosion-proof portion can operate, and the electrolytic capacitor is positioned. The illumination device according to claim 2 or 3. The capacitor is an electrolytic capacitor;
The holding portion holds the electrolytic capacitor with the explosion-proof portion of the electrolytic capacitor facing the base side,
The power supply circuit unit is accommodated, and a heat radiating unit that radiates heat from a heat source is provided,
One end side of the connection member is connected to the base, and the other end side is connected to the heat dissipation part,
A first resin portion filled in a gap between the first opening and the second opening, and the electrolytic capacitor and the power supply line;
A second resin part filled in the heat dissipation part,
The said 1st resin part is formed so that the inflow of the said 2nd resin part to the space in the nozzle | cap | die in which the said explosion-proof part is arrange | positioned may be prevented. The lighting device according to item.

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