JP6700573B2 - Lamp device - Google Patents

Description

  Embodiments of the present invention relate to a lamp device using a light guide.

  Conventionally, there is an incandescent clear light bulb in which a filament is directly visible using a transparent glass globe. When this incandescent clear light bulb is turned on, a strong light is emitted from the filament that can be seen directly through the glass globe, so that a glittering feeling can be obtained and a lighting effect can be obtained.

  Further, there is a lamp device in which a light emitting element is used as a light source, a transparent globe is used, and a light guide body facing the light emitting element is projected into the globe.

  In this case, in order to prevent the displacement of the light guide, it is desired to support the peripheral surface of the light guide. Since the light guide body is configured to guide light by reflecting the light inside the light guide body at the interface between the peripheral surface of the light guide body and air, when a component other than air comes into contact with the peripheral surface of the light guide body, Since the reflectance at the contact portion decreases, the light guide efficiency decreases as the contact area increases, and it may be difficult to reproduce the glittering feeling.

JP, 2014-35790, A

  The problem to be solved by the present invention is to provide a lamp device capable of reliably supporting a light guide body and suppressing a decrease in light guide efficiency due to the light guide body.

The lamp device of the embodiment includes a housing, a substrate, a light emitting unit, a globe, a light guide, a support, and a power feeding unit. The substrate is provided on one end side of the housing. The light emitting unit is provided on one end side of the substrate. The globe is provided so as to cover one end side of the housing. The light guide, the light emitting portion and the other end side is provided a cylindrical light guide posts which are opposed to the light emitting portion, the distal end side of the Shirubekohashira the tip end which is one end side is projected in the glove, and guide It has a mounting portion projecting around the other end of the optical column. The support body has a cover part attached to one end side of the housing, a through hole through which the light guide column penetrates from the tip side , and a contact part protruding into the through hole and contacting the peripheral surface of the light guide column. Press the mounting part of to the board. The power feeding unit is provided on the other end side of the housing.

  According to the present invention, it is possible to reliably support the light guide body and suppress a decrease in light guide efficiency due to the light guide body.

It is sectional drawing of the lamp device which shows one Embodiment. It is a perspective view of a lamp device same as the above. It is an exploded sectional view of a light guide and a support of the same lamp device. FIG. 3 is a plan view of a light guide body and a support body of the above lamp device.

  Hereinafter, one embodiment will be described with reference to FIGS. 1 to 4.

  A lamp device 10 is shown in FIGS. The lamp device 10 is a light bulb shaped lamp that can be used by being attached to a socket for an incandescent light bulb for general lighting.

  The lamp device 10 includes a housing 11. The light emitting module 12, the light guide 13, the support 14, and the globe 15 are disposed on one end side of the housing 11, and the case 16 and the power supply unit 17 are disposed inside the housing 11, and A power supply unit 18 is arranged at the other end of the case 11 and at the other end of the case 16. The lamp device 10 has an imaginary central axis (lamp axis) extending from the globe 15 to the power feeding portion 18, and the globe 15 side of the central axis is referred to as one end side and the power feeding portion 18 side as the other end side.

  The housing 11 is integrally formed of a metal material. For example, the housing 11 is made of aluminum die cast. The housing 11 includes a tubular portion 21 and a partition portion 22 formed in the tubular portion 21. Inside the cylindrical portion 21, a cavity is formed on each of one end side and the other end side of the partition portion 22.

  The tubular portion 21 has an outer tubular portion 23 and an inner tubular portion 24. An annular groove portion 25 opening to one end side is formed between the outer tubular portion 23 and the inner tubular portion 24. The outer peripheral surface of the outer tube portion 23 is an other face body having a plurality of edge portions (ridge line portions) 26 provided along the lamp axial direction and a plurality of housing surface portions 27 provided between the edge portions 26. Has been formed. In this embodiment, each of the edge portions 26 and the case surface portions 27 is formed into 12 dodecahedrons, and the case surface portions 27 are located between the edge portions 26 and closer to the center side of the case 11 than the edge portions 26. It is provided in the shape of a concave curved surface. The edge portion 26 and the case surface portion 27 are formed so as to correspond to the shape of the globe 15. In addition, a communication groove 28 that communicates with the groove portion 25 is formed in each housing surface portion 27 of the outer tubular portion 23. An engaged portion 29 for attaching the support body 14 and an engaged portion 30 for attaching the case 16 are provided on one end side of the inner tubular portion 24.

  Insertion holes 31 and 32 are formed in the partition portion 22 at positions corresponding to the engaged portions 29 and 30 of the tubular portion 21, respectively.

  Further, as shown in FIG. 1, as the light emitting module 12, a COB (Chip On Board) module is used in this embodiment. The light emitting module 12 includes a substrate 35, a plurality of light emitting elements 36 mounted on the substrate 35, and a phosphor layer 37 that seals the light emitting elements 36. The light emitting element 36 and the phosphor layer 37 form a light emitting portion 38.

  The substrate 35 has a flat plate shape, is provided with a light emitting portion 38 on one end side surface, and is attached in a state in which the other end side surface is thermally coupled to the partition portion 22 of the housing 11. An LED is used as the light emitting element 36. A blue light emitting LED is used as the LED. Further, the phosphor layer 37 contains a phosphor that is excited by the light of the light emitting element 36 in a transparent resin. For example, it contains a yellow phosphor that emits yellow light when excited by the blue light of a blue light emitting LED.

  The light emitting unit 38 may be configured by an SMD (Surface Mount Device) package using LEDs, or an organic EL or the like other than LEDs.

  Further, as shown in FIGS. 1 to 4, the light guide 13 is formed of a transparent rubber material having heat resistance and flexibility. Silicone rubber is used as the rubber material. The light guide 13 includes a column-shaped light guide column 40. One end (hereinafter, referred to as a tip) of the light guide column 40 is projected into the globe 15, and the surface on the other end side of the light guide column 40 faces the light emitting unit 38 with a predetermined gap.

  An annular mounting portion 41 is provided so as to project around the other end of the light guide column 40. An annular fitting groove 42 into which the support 14 is fitted is formed on one end side of the mounting portion 41. On the other end side of the mounting portion 41, an annular contact portion 43 that is in contact with the surface on one end side of the substrate 35 around the light emitting portion 38 of the light emitting module 12 is provided. The contact portion 43 is formed with a plurality of protrusions 43a in an annular shape for ensuring flexibility when contacting the substrate 35. An annular connecting portion 44 is provided between the light guide column 40 and the mounting portion 41. The connecting portion 44 is provided with a thin portion 44a having a small thickness, and is provided with rib portions 44b having a large thickness at several locations in the circumferential direction. The mounting portion 41 does not have to be annular, and for example, when a component such as a connector is mounted on the substrate 35 of the light emitting module 12, the mounting portion 41 may have a shape in which a portion that interferes with the component is cut out. .

  A concave portion 45 is formed on the tip surface of the light guide column 40, and a prism 46 is formed on the surface of the concave portion 45.

  The surface on the other end side of the light guide column 40 is an incident surface on which the light emitted from the light emitting unit 38 enters the light guide column 40. A light emitting portion A is formed on the tip end side of the light guide column 40, and emits light that enters from the incident surface and is guided inside the light guide column 40 to the outside of the light guide column 40. In the light emitting portion A, a part of the light guided in the light guide column 40 is reflected by the prism 46 and emitted from the peripheral surface of the light guide column 40, and a part of the light guided in the light guide column 40. Light passes through the prism 46 and is emitted from the tip end surface of the light guide column 40. Therefore, the light emitting portion A is formed on the tip end side of the light guide column 40 in which the concave portion 45 and the prism 46 are provided, and from this light emitting portion A, the side and the light guide column which intersect the axial direction of the light guide column 40. Light is radiated in a wide direction including a front end direction which is one end direction of 40 and a rear direction which is directed from the light guide column 40 to the side of the housing 11. The light emitted from the light emitting portion A of the light guide column 40 reproduces a glittering feeling as if an incandescent clear bulb is lit. Glittering is used to mean "the light looks beautiful and shimmers".

  Further, the diameter of the light guide column 40 is 4 to 9 mm. The light guide column 40 has a cylindrical shape with the same diameter from one end side (tip side) to the other end side, but the diameter of the one end side (tip side) is smaller than the diameter of the other end side, and one end side (tip side) ), it may be a conical shape that tapers off. The diameter of the light guide column 40 is larger than that of the light emitting portion 38.

  The tip of the light guide column 40 is projected in the central region of the globe 15 in the axial direction. The axial center region in the globe 15 includes the axial center in the globe 15 and the vicinity thereof. In the present embodiment, the tip of the light guide column 40 is arranged at the center of the maximum diameter portion where the diameter of the globe 15 is maximum in the direction orthogonal to the lamp axis direction.

  The recess 45 of the light guide column 40 is formed such that the depth from the tip of the light guide column 40 is the deepest at the center of the recess 45.

  The prisms 46 are formed radially from the central axis of the light guide column 40 toward the outside (circumferential direction). Specifically, the prisms 46 are formed in a triangular cross section having a ridge line 46a and valleys 46b on both sides, are arranged in a plurality along the circumferential direction of the light guide column 40, and are each radially from the central axis of the light guide column 40. It is provided.

  The support 14 is made of a resin material having a light-transmitting property. The support 14 is formed in a substantially conical shape so that the central portion thereof projects toward the one end side with respect to the peripheral portion. That is, the support body 14 is provided with a central support portion 14a protruding toward one end side and a cover portion 14b whose diameter increases from the support portion 14a toward the other end side, and is formed in a substantially conical shape.

  A through hole 48, through which the tip side of the light guide 13 passes, is formed in the center of the support 14, that is, inside the support 14a. The through-hole 48 has a tip-side hole portion 48a formed at one end side and an inner-hole portion 48b having a diameter larger than that of the tip-side hole portion 48a at the other end side. Both 48b are formed to have an inner diameter larger than the outer diameter of the light guide column 40.

  Inside the through hole 48 and inside the inner hole portion 48b, a plurality of contact portions 49 that protrude into the through hole 48 and contact the peripheral surface of the light guide column 40 are provided. Each of the contact portions 49 has a cross section in the circumferential direction of the through hole 48 formed in a convex curved surface shape, and the cross section in the axial direction of the through hole 48 is a convex curved surface and is elongated along the axial direction of the through hole 48. Has been formed. The diameter of the virtual circle having the smallest diameter of the virtual circles in contact with the plurality of contact portions 49 is formed to be slightly smaller than the outer diameter of the light guide column 40. Therefore, the plurality of contact portions 49 contact the peripheral surface of the light guide column 40 penetrating the through hole 48 in a point contact state or a state close to the point contact (state in which the contact area is small), and the light guide column 40 is supported by the support body 14. Support. Although the number of the contact portions 49 is six in the present embodiment, it may be smaller or larger than this, and at least three or more can stably support the light guide column 40.

  The other end of the support 14, that is, the other end of the cover 14b is open. The peripheral portion of the cover portion 14b is fitted and attached inside the inner tubular portion 24 of the housing 11. A plurality of engaging claws 50 that engage with the engaged portions 29 and are attached to the housing 11 are provided on the periphery of the cover portion 14b. Then, the cover portion 14b covers the other end side of the light guide 13 and the light emitting portion 38 and the like.

  On the other end side of the support body 14 and inside the cover portion 14b, an annular fitting portion 51 that fits into the fitting groove 42 of the light guide body 13 and presses the contact portion 43 against the substrate 35 is projected. It is set up. Then, by fitting the fitting portion 51 into the fitting groove 42 of the light guide 13 and pressing the contact portion 43 against the substrate 35, the radial direction of the incident surface of the light guide column 40 with respect to the light emitting surface of the light emitting portion 38. The position and the facing distance are positioned.

  As shown in FIGS. 1 and 2, the globe 15 is made of a transparent material having a light transmittance of 95% or more. Polycarbonate, for example, is used as the transparent material. The globe 15 is hollow and has a spherical portion 53 formed at one end side, a reduced diameter portion 54 having a diameter reduced from one end side toward the other end side, and an opening at the other end side. On the other end side of the globe 15, a tubular fitting portion 55 that fits into the groove portion 25 of the housing 11 is provided in a protruding manner, and the fitting portion 55 is fitted in the housing 11 in a fitted state. A plurality of claw portions 56 that engage with the communication grooves 28 of the housing 11 and are attached to the housing 11 are provided in a protruding manner.

  The globe 15 is open at the other end with the apex 57 at one end and a plurality of edge portions (ridge line portions) 58 respectively provided along the lamp axial direction from the apex 57 to the other end side, and these edge portions 58. It is formed in a polyhedron having a plurality of glove surface portions 59 provided between them. That is, along the circumferential direction of the globe 15, the edge portions 58 and the globe surface portions 59 are alternately arranged, and the plurality of globe surface portions 59 are arranged in parallel.

  The plurality of edge portions 58 are radially provided when viewed from the top portion 57 side so as to linearly pass through the top portion 57 and reach both sides of the globe 15. Similarly, the plurality of globe surface portions 59 are also provided radially when viewed from the top portion 57 side.

  In the present embodiment, each of the edge portions 58 and the globe surface portions 59 is formed into 12 dodecahedrons. The glove surface portion 59 is not limited to a dodecahedron, and a polyhedron having more faces is preferable in order to obtain a glittering feeling, but in consideration of manufacturability, a dodecahedron is preferable.

  The globe surface portion 59 is provided between the edge portions 58 so as to have a curved surface shape that protrudes more inside the globe 15 than the edge portions 58. That is, the globe surface portion 59 is provided in a concave curved surface shape as seen from the outside of the globe 15 like a concave lens in which the image of the light emitting portion A of the light guide 13 located at the center of the globe 15 is reduced. ..

  In the present embodiment, the curved surface of the globe surface portion 59 is formed to be a concave curved surface having a predetermined radius over the entire width direction, but it may be formed to be an elliptical surface in the width direction.

  The globe 15 is integrally formed by blow molding. In this blow molding, a cylindrical parison is sandwiched by a pair of molds, one end side corresponding to the top part 57 is sealed, and air is injected into the inside from the other end side to inflate the parison along the mold, Shape the globe 15. In this case, by aligning the seam of the pair of molds with the edge portion 58, the seam of the mold can be made inconspicuous.

  Further, as shown in FIGS. 1 and 2, the case 16 is formed in a cylindrical shape from a resin material having an insulating property. The case 16 is inserted into the housing 11 from the other end side and is fixed to the housing 11. On the outer peripheral surface of the case 16, a flange portion 62 that abuts on the other end side of the housing 11 is provided in a protruding manner. On one end side of the case 16, a plurality of mounting claws 63 that are mounted on the housing 11 by being inserted through the insertion holes 32 of the partitioning part 22 and engaging with the engaged parts 30 are provided in a protruding manner. The other end side of the case 16 protrudes from the other end side of the housing 11, and the power feeding unit 18 is attached thereto. A pair of mounting grooves 64 for mounting the power supply unit 17 are provided facing each other on the inner peripheral portion of the case 16.

  Further, as shown in FIG. 1, the power supply unit 17 converts AC power input from the power supply unit 18 into predetermined DC power and supplies the DC power to the light emitting element 36 of the light emitting module 12. The power supply unit 17 includes a circuit board 67 and a plurality of circuit components 68 mounted on the circuit board 67. The circuit board 67 is fitted into the mounting groove 64 from the other end side of the case 16, is inserted into the case 16, and is held at a predetermined position in the case 16. The pair of input portions of the AC power of the power supply unit 17 are electrically connected to the power feeding unit 18 by the pair of wirings, and the pair of output portions of the DC power of the power supply unit 17 are electrically connected to the light emitting module 12 by the pair of wirings. It is connected to the.

  Further, as the power supply unit 18, for example, a base that can be connected to a socket for a general illumination incandescent light bulb such as E17 or E26 is used. The power supply unit 18 is not limited to the base and may be a pair of pins depending on the type of lamp.

  Then, the operation of the present embodiment will be described.

  The lamp device 10 is used by connecting the power supply unit 18 to a socket for an incandescent lamp for general lighting of a lighting device.

  When the AC power is supplied to the lamp device 10 through the socket, the power supply unit 17 converts the AC power into a predetermined DC power and supplies it to the light emitting element 36. As a result, the light emitting element 36 emits light and the light emitting section 38 emits light.

  The light emitted from the light emitting portion 38 enters the light guide column 40 of the light guide 13 from the incident surface and is guided inside the light guide column 40 toward the light emitting portion A at the tip. At this time, the light in the light guide column 40 is guided by being reflected at the interface between the peripheral surface of the light guide column 40 and the air. A part of the light guided to the light emitting portion A is reflected by the prism 46 and is radiated from the peripheral surface of the light guide column 40, and a part of the light guided to the light emitting portion A is a prism 46. And is radiated from the tip end surface of the light guide column 40. Therefore, from the light emitting portion A of the light guide column 40, the tip direction of the light guide column 40, the lateral direction intersecting the axial direction of the light guide column 40, and the rearward direction from the light guide column 40 to the side of the housing 11 are performed. Light is radiated in a wide direction including. The light emitted from the light emitting portion A of the light guide column 40 passes through the globe 15 and is applied to the illumination space.

  When the globe 15 of the lit lamp device 10 is viewed from the side, a light source image that is an image of the light emitting portion A that emits the light of the light guide 13 is projected onto each globe surface portion 59, and a plurality of light source images are projected. It looks as if the light source images are lined up, and the glittering feeling can be reproduced.

  Moreover, since the globe surface portion 59 is provided in a concave curved surface shape when viewed from the outside of the globe 15, the light source which is an image of the light emitting portion A that emits the light of the light guide 13 by the same action as the concave lens. The image is projected on the globe surface 59 so as to be reduced.

  Therefore, compared to the light source image projected in the case of a spherical globe, a light source image having a small size and high brightness is projected on the globe surface portion 59, and further, since the light source image is projected on each globe surface portion 59, A plurality of light source images of small size and high brightness are projected on the globe 15 to improve the glittering feeling.

  Further, since the light guide 13 of the lamp device 10 is made of silicone rubber, it is possible to secure heat resistance against heat from the light emitting section 38 and suppress deterioration.

  Since the light guide 13 made of silicone rubber has flexibility, it is difficult to dispose the light guide 13 on the housing 11 side by itself, and the position of the light emitting portion A of the light guide column 40 is difficult to be constant. By using the support 14, such a problem can be solved.

  That is, by penetrating the tip end side of the light guide column 40 through the through hole 48 of the support body 14, the light guide column 40 is supported by the support body 14, and the position of the light emitting portion A of the light guide column 40 can be made constant.

At this time, the inside of the through hole 48 of the support 14 and the peripheral surface of the light guide column 40 come into contact with each other. As described above, the light guide 13 is configured to guide light by reflecting the light inside the light guide column 40 at the interface between the peripheral surface of the light guide column 40 and the air. When other parts come into contact with each other, the reflectance at the contact portion is reduced, and the larger the contact area, the lower the light guiding efficiency and the more difficult it is to reproduce the glittering feeling.

  In the lamp device 10 of the present embodiment, since the plurality of contact portions 49 that come into contact with the peripheral surface of the light guide column 40 are provided in the through hole 48 of the support body 14, only these contact portions 49 are included in the light guide column 40. The contact area can be reduced by contacting the peripheral surface of. Therefore, the lamp device 10 can reliably support the light guide body 13, suppress the decrease in the light guide efficiency of the light guide body 13, and can reproduce the glittering feeling.

  Moreover, since the contact portion 49 is formed in a convex curved surface shape in both the circumferential direction and the axial direction of the through hole 48, the contact portion 49 comes into point contact with the circumferential surface of the light guide column 40 or in a state close to the point contact, and has a contact area. Can be minimized.

  Further, since the contact portion 49 is formed in a convex curved surface in the axial direction of the through hole 48, the light guide column 40 is less likely to be caught when the light guide column 40 is inserted into the through hole 48, and the light guide column 40 is not damaged. Can be prevented.

  Further, by fitting the fitting portion 51 of the support body 14 into the fitting groove 42 of the mounting portion 41 of the light guide body 13, the other end side of the light guide body 13 can be positioned, and the incident surface of the light guide body 13 can be positioned. The positional relationship between the light emitting portion 38 and the light emitting portion 38 can be made constant.

  Further, the fitting portion 51 of the support body 14 presses the mounting portion 41 of the light guide body 13 against the substrate 35 of the light emitting module 12 and the substrate 35 against the housing 11. It can be positioned on the body 11, and heat dissipation due to thermal contact between the substrate 35 and the housing 11 can be secured.

  Further, since the support 14 is formed in a substantially conical shape whose diameter increases from one end side to the other end side, it blocks light traveling from the light emitting portion A of the light guide column 40 toward the housing 11. Can be prevented and a wide light distribution can be obtained.

  Further, since the support 14 has a light-transmitting property, even if light enters the support 14 from the contact portion 49 that contacts the light guide column 40, the light can be emitted from the support 14 to the outside. The light extraction efficiency of the lamp device 10 can be improved.

  Further, in the light guide 13, since the thin portion 44a is provided in the connecting portion 44 between the light guide column 40 and the mounting portion 41, the light incident on the light guide column 40 is guided to the mounting portion 41 side. Can be reduced, and the light not used can be reduced. Furthermore, since the connecting portion 44 is provided with thick ribs 44b at several places in the circumferential direction, the connecting strength between the light guide column 40 and the mounting portion 41 that may be insufficient with only the thin portion 44a is secured. can do.

  Moreover, since the diameter of the light guide column 40 of the light guide 13 is 4 to 9 mm, efficiency is high and a glittering feeling can be reproduced. That is, when the diameter of the light guide column 40 is smaller than 4 mm, the light emitting unit 38 is correspondingly small and the output is low, and the light of the light emitting unit 38 is less likely to enter the light guide column 40, which lowers the efficiency. If the diameter of the light guide column 40 is thicker than 9 mm, the light emitting portion A becomes large, and the glittering feeling is reduced.

  Furthermore, since the light emitting portion A of the light guide 13 is arranged in the central area of the globe 15 in the axial direction, a glittering feeling can be reproduced.

  Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the scope equivalent thereto.

10 lamp device
11 case
13 Light guide
14 Support
14b cover
15 gloves
18 power supply
35 circuit board
38 Light emitting part
40 light guide column
41 Mounting part
48 through hole
49 contact
51 Mating part
A light emitting part

Claims (6)

Housing and;
A substrate provided on one end side of the housing;
A light emitting portion provided on one end side of the substrate;
A glove provided to cover one end side of the housing;
Cylindrical light guide pillars with a one end side distal end is protruded into the glove other end is opposed to the light emitting portion of the light guide pillar light emitting portion provided on the distal end side, and the light guide pillar A light guide body having a mounting portion projecting around the other end side;
A cover part attached to one end side of the housing; a through hole through which the light guide column penetrates from the tip side ; and a contact part that protrudes into the through hole and contacts the peripheral surface of the light guide column. A support for pressing the mounting portion of the optical body against the substrate;
A power supply unit provided on the other end side of the housing;
A lamp device comprising: The lamp device according to claim 1, wherein the contact portion is projected in a curved shape along an axial direction of the through hole. The lamp device according to claim 1, wherein the support body has a fitting portion that fits into the mounting portion of the light guide body. The lamp device according to claim 3, wherein the fitting portion of the support body presses the attachment portion of the light guide body and the substrate toward one end side of the housing. The support is provided with the through hole on one end side, the cover portion on the other end side, and is formed in a shape in which a diameter increases from one end side to the other end side. The lamp device according to claim 1. The lamp device according to any one of claims 1 to 5, wherein the support has a light-transmitting property.

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