JP2012103871A - Led lamp used for traffic light for pedestrian - Google Patents

Abstract

PROBLEM TO BE SOLVED: To irradiate a front cover of a traffic light for pedestrians in a favorite color by a plurality of white LEDs.SOLUTION: An LED lamp is screwed in and coupled in a replaceable state to a socket 5 provided to a center part of a reflector 4 of a concave mirror 40 having a rectangular opening part 43. The LED lamp 1 comprises a coupling part 11 having a male screw 12 provided on an outer periphery screwed in and coupled to the socket 5, and a lamp body 10 fixed to the coupling part 11 and having a plurality of white LEDs 2. The lamp body 10 includes a fixed base 15 having the white LEDs 2 fixed to a center part and an outer peripheral part, and a transparent cover 16 covering the outside of the fixed base 15. The transparent cover 16 is constituted by providing a discoloring filter 7 which discolors and transmits light of outer peripheral LEDs 2X, fixed to the outer peripheral part of the fixed base 15, to an outer peripheral part 16A transmitting the light of the outer peripheral LEDs 2X, and the discoloring filter 7 discolors and transmits the light of the outer peripheral LEDs 2X fixed to the outer peripheral part of the fixed base 15.

Description

  The present invention relates to a lamp having an LED as a light source used in place of a light bulb for a pedestrian traffic light, and more particularly to an LED lamp having a luminescent color comparable to a light bulb while using a white LED as the light source.

  Light bulbs are used as lamps for traffic lights. Since the light bulb has low luminous efficiency, it has a drawback of high power consumption. In addition, since the lifetime is as short as several thousand hours, there is a drawback in that it is necessary to replace it regularly, and maintenance is troublesome. Further, in order to simplify the maintenance, if the life of the bulb is designed to be long, there is a drawback that the light emission efficiency is drastically lowered and the power consumption is increased. The luminous efficiency and lifetime of a light bulb are mutually contradictory characteristics, and both cannot be satisfied at the same time. In order to solve this drawback, LED lamps that are used in place of light bulbs in traffic signals have been developed. (See Patent Document 1)

JP 9-265807 A

  As shown in FIG. 1, an LED lamp described in Patent Document 1 that is used in place of a light bulb for a traffic signal light has a large number of LEDs 92 fixed to a side surface 95 </ b> A and a front end surface 95 </ b> B. . When this LED lamp 91 is used in place of a light bulb for a pedestrian traffic light, there is a drawback that the blue-green part of the front cover 99 cannot emit light in a preferred color. This is because the emission spectra of LED lamps and light bulbs are different. FIG. 2 shows an emission spectrum in which the light bulb emits red light to emit light. As shown in this figure, the light bulb has a continuous emission spectrum in the visible light region. On the other hand, the white LED does not emit light in a wide spectrum of visible light like a light bulb. FIG. 3 shows the emission spectrum of the white LED. The white LED is white with a blue light emission peak emitted from the blue LED and a light emission color of the phosphor that is excited by the blue light and emits light. That is, the blue light emission of the blue LED and the light emission of the phosphor that is complementary to the blue light emitted by the phosphor are seen by human eyes and appear white. For this reason, it looks white to the human eye, but the emission spectrum is very different.

  When this white LED is used in place of a light bulb for a pedestrian traffic light, the light emission color of the white portion at the center of the traffic light can be emitted to the same white as the light bulb color. However, the pedestrian traffic light is provided with a blue filter that transmits blue light around it, and light from the light bulb is transmitted through this region to emit blue-green light. Since the light bulb emits light in a broad spectrum of visible light, it can be transmitted through a blue filter and emitted in a predetermined blue-green color. However, since the emission spectrum of the white LED is very different from that of a light bulb, even if the light emission color is transmitted through the same blue filter, it cannot emit light in a blue-green color similar to a light bulb. For this reason, when a white LED is used instead of a light bulb, the white region can be made to emit light that approximates the light bulb, but the blue-green region cannot be made to emit light that is comparable to a light bulb. In a white LED, it is extremely difficult in practice to make the blue region have an emission color comparable to that of a light bulb, but it is possible in principle. However, if this white LED is used in place of a light bulb for a pedestrian traffic light, there is a drawback that the white portion of the front cover cannot emit light in a white color comparable to the light bulb.

  The present invention has been developed for the purpose of solving the above drawbacks. An important object of the present invention is that the white LED and the blue-green portion of the front cover of the traffic light for pedestrians can be compared with the light bulb while significantly saving energy by using white LEDs. It is providing the LED lamp used for the pedestrian traffic light which can be made.

Means for Solving the Problems and Effects of the Invention

  The LED lamp used in the traffic light for pedestrians of the present invention is a concave mirror 40 that reflects light on its surface, and an opening 43 is screwed into a socket 5 provided at the center of a reflector 4 having a quadrangular shape, and is replaceable. Is an LED lamp having a white light source as a light source. The LED lamp 2 includes a connecting portion 11 having a male screw 12 provided on the outer periphery to be screwed and connected to a socket 5, and a lamp body 10 having a plurality of white LEDs 2 fixed to the connecting portion 11. The lamp body 10 includes a fixed base 15 in which the white LED 2 is fixed at the center and the outer periphery, and a transparent cover 16 that covers the outside of the fixed base 15. The transparent cover 16 is provided with a discoloration filter 7 that discolors and transmits the light of the outer peripheral LED 2X in an outer peripheral portion 16A that transmits the light of the outer peripheral LED 2X that is fixed to the outer peripheral portion of the fixing base 15. 7 discolors and transmits the light of the outer peripheral LED 2 </ b> X fixed to the outer peripheral portion of the fixed base 15.

  The above LED lamp uses a white LED as a light source, and while saving energy significantly compared to conventional light bulbs, the white and blue-green parts of the front cover of the pedestrian traffic light are comparable to the light bulbs. There is a feature that can be colored. The above LED lamp has a white LED fixed to the center and outer periphery of the fixed base, a transparent cover is provided on the outer periphery, and a color change filter is provided on the outer periphery of the transparent cover. This is because the light of the outer peripheral LED fixed to the outer peripheral portion of the fixed base is discolored and transmitted.

The LED lamp of the present invention can color the discoloration filter 7 to a blue decay color.
The above LED lamp has a feature that the blue-green portion of the front cover can emit light in a blue-green color closer to the light emission color of the light bulb because the discoloration filter is colored in a blue decay color.

In the LED lamp of the present invention, the transparent cover 16 can be used as the discoloration filter 7 by attaching the colored film 29 to the outer peripheral surface.
The above LED lamp has a colored film attached and a color change filter is provided on the transparent cover. Therefore, by producing a transparent transparent cover and attaching the colored film to the light, it is possible to easily change the optimum color change filter and can do.

In the LED lamp of the present invention, the central portion 16B of the transparent cover 16 can be used as a non-colored portion, and the light of the central LED 2Y disposed in the central portion of the fixed base 15 can be transmitted through the non-colored portion.
The above LED lamp has a feature that the central portion of the transparent cover is a non-colored portion, and thus the white portion of the front cover can be brightly irradiated by transmitting the light emitted from the white LED to the non-colored portion.

The LED lamp of the present invention is provided with the discoloration filter 7 of different colors at the central portion 16B and the outer peripheral portion 16A of the transparent cover 16, and the light of the central LED 2Y fixed to the fixing base 15 is changed to the discoloration filter 7B of the central portion 16B. And the light from the outer peripheral LED 2X can be transmitted through the discoloration filter 7A of the outer peripheral portion 16A.
The above LED lamps are provided with discoloration filters of different colors between the central part of the transparent cover and the outer peripheral part. Therefore, the light transmitted through the central part of the transparent cover and the light transmitted through the outer peripheral part are individually adjusted. Thus, the emission color of the white and blue-green portions of the front cover can be adjusted ideally.

In the LED lamp of the present invention, the white LED 2 fixed to the fixed base 15 can be a white diode that turns white by changing the color of the light emitted from the blue light-emitting diode with a phosphor.
The above-mentioned LED lamp can emit white light of this white LED in a blue-green color comparable to that of a light bulb by using a gallium nitride-based white diode that emits bright light, while causing the white LED to emit light brightly.

In the LED lamp of the present invention, the fixed base 15 can arrange a plurality of rectangular side substrates 15A in a polygonal cylindrical shape, and a central substrate 15B on the tip surface.
The above LED lamps can illuminate the front cover uniformly and brightly with white LEDs arranged at the center and the outer periphery of the fixed base.

In the LED lamp of the present invention, the central portion 16B of the transparent cover 16 can be an infinite number of uneven surfaces that diffusely reflect light, and the surface of the outer peripheral portion 16A can be a smooth surface.
The above LED lamp has a feature that the white portion of the front cover can be illuminated uniformly and brightly.

It is sectional drawing of the conventional traffic signal for pedestrians. It is a graph which shows the light emission spectrum of a light bulb. It is a graph which shows the emission spectrum of white LED. It is a disassembled perspective view which shows an example of the pedestrian traffic light which uses the LED lamp concerning one Example of this invention. It is a back perspective view of the reflector of the traffic signal for pedestrians shown in FIG. It is a disassembled perspective view which shows the state which removed the lamp holder from the reflector of the traffic signal for pedestrians shown in FIG. It is a disassembled perspective view which shows the state which removed the lamp holder from the reflector shown in FIG. It is a horizontal sectional view which shows the connection structure of the reflector of the pedestrian traffic light shown in FIG. 4, and a lamp holder. It is sectional drawing which shows the connection structure of the LED lamp and lamp holder shown in FIG. It is sectional drawing of the LED lamp and lamp holder shown in FIG. It is the figure which removed the transparent cover of the LED lamp shown in FIG. It is the XII-XII sectional view taken on the line of the LED lamp shown in FIG. It is a disassembled perspective view of the fixing stand of the LED lamp shown in FIG. It is a figure which shows the state which looked at the reflector of the traffic signal for pedestrians shown in FIG. 8 from the front, Comprising: It is a figure which shows arrangement | positioning of LED reflected on a concave mirror. It is the figure which removed the transparent cover of the LED lamp concerning the other Example of this invention. It is a figure which shows the state which looked at the reflector of the traffic signal for pedestrians provided with the LED lamp shown in FIG. 15 from the front, Comprising: It is a figure which shows arrangement | positioning of LED reflected on a concave mirror. It is a schematic circuit diagram of the LED lamp concerning one Example of this invention. It is a figure which shows the state which arrange | positions several LED on a center board | substrate and a side board. It is a circuit diagram which shows the principle of a bypass circuit. It is a graph which shows the absorption characteristic which absorbs the light which a discoloration filter permeate | transmits. It is a graph which shows the emission spectrum of the light of white LED which permeate | transmitted the discoloration filter. It is sectional drawing which shows the connection structure of the LED lamp concerning another Example of this invention, and a lamp holder. It is sectional drawing which shows the connection structure of the LED lamp concerning another Example of this invention, and a lamp holder.

  Embodiments of the present invention will be described below with reference to the drawings. However, the examples shown below exemplify LED lamps used in pedestrian traffic lights for embodying the technical idea of the present invention, and the present invention does not specify the LED lamps as follows. . Further, in this specification, in order to facilitate understanding of the scope of claims, numbers corresponding to the members shown in the examples are indicated in the “claims” and “means for solving problems” sections. It is added to the members. However, the members shown in the claims are not limited to the members in the embodiments.

  A pedestrian traffic light using the LED lamp of the present invention is shown in FIGS. The LED lamp 1 is connected to a socket 5 provided at the center of the reflector 4 so that it can be replaced in place of a light bulb. In the illustrated pedestrian traffic light, a socket 5 is connected to a reflector 4 via a lamp holder 3.

  The pedestrian traffic light is provided with an attachment / detachment hole 41 at the center of the reflector 4 that reflects light on the surface, and the attachment / detachment hole 41 is connected so that the lamp holder 3 connecting the socket 5 can be attached / detached. Yes. The LED lamp 1 is not directly connected to the reflector 4 but connected to the lamp holder 3 provided with the socket 5 so as to be exchanged. The pedestrian traffic light removes the lamp holder 3 from the reflector 4 when replacing the LED lamp 1. The lamp holder 3 removed from the reflector 4 removes the old light bulb connected to the socket 5 and connects the LED lamp 1 in place of the light bulb. With the new LED lamp 1 connected to the socket 5, the lamp holder 3 is connected to the attachment / detachment hole 41 of the reflector 4. 6 and 7 show the lamp holder 3 and the LED lamp 1 removed from the reflector 4.

  The reflector 4 is a concave mirror 40 that reflects light on the surface, and the opening 43 has a quadrangular shape. The reflector 4 is manufactured by pressing a metal plate, and the inner surface is plated with metal such as chrome plating so as to reflect light efficiently. The reflector 4 of the concave mirror 40 has a spherical or parabolic shape, a rectangular vertical surface 44 is provided at the opening edge, and the opening 43 is rectangular. Since the vertical surface 44 is provided on a spherical surface or a parabolic surface, the boundary thereof has an arch shape. As shown in FIG. 8, the rectangular opening 43 is sealed in a watertight structure with a rectangular front cover 9 via packings 48 and 49. In the illustrated front cover 9, a filter 9B colored in blue or red is laminated on the inner surface of a transparent plate 9A disposed on the front surface. The transparent plate 9A is made of transparent glass or resin that transmits light. The front cover 9, which is a laminate of the transparent plate 9 </ b> A and the filter 9 </ b> B, covers a ring-shaped packing 48 having a cross-sectional shape on the groove side along the outer peripheral edge. Further, the outer peripheral portion of the front cover 9 covered with the packing 48 is inserted in a state of being fitted inside the stepped portion 45 provided in the opening 43 of the reflector 4. Further, the outside of the stepped portion 45 in which the outer peripheral portion of the front cover 9 is fitted is covered with a ring-shaped packing 49 having a cross-sectional shape as a groove side, and is sealed in a watertight structure.

  The reflector 4 of the concave mirror 40 is provided with an attachment / detachment hole 41 for inserting the lamp holder 3 at the center thereof. The attachment / detachment hole 41 is provided with a cylindrical tubular projecting portion 42 that connects the lamp holder 3 so as to project outward. The cylindrical tubular projecting portion 42 projects in a direction including the rectangular vertical surface 44, and the lamp holder 3 is inserted into the inside. The inner shape of the cylindrical projecting portion 42 is substantially equal to the outer shape of the lamp holder 3, and the lamp holder 3 is inserted into the inside of the peripheral wall that is the cylindrical tubular projecting portion 42 and can be connected to a fixed position. . The lamp holder 3 is inserted and connected to the peripheral wall, and the LED lamp 1 is connected to the lamp holder 3. The cylindrical protrusion 42 has a size that allows the LED lamp 1 and the light bulb to be inserted.

  The lamp holder 3 is manufactured by pressing a metal plate. The lamp holder 3 has a cylindrical connecting cylinder portion 32 that is inserted into and connected to the inside of a cylindrical protruding portion 42 provided at the center of the reflector 4 so as to protrude rearward. A ring plate 31 that closes the attachment / detachment hole 41 of the reflector 4 is provided on the front surface of the connecting cylinder portion 32. Further, the ring plate 31 is provided with a center hole 34 in the lamp holder 3 by connecting an inner cylinder 33 at the center. A socket 5 to which a light bulb is screwed and connected is fixed to the rear end of the inner cylinder 33 constituting the center hole 34, that is, the bottom of the center hole 34. The socket 5 is provided with a female screw 52 on the inner surface in order to screw and connect the male screw 12 of the bulb.

In the above pedestrian traffic light, the lamp is replaced as follows.
(1) As shown in FIGS. 6 and 7, the lamp holder 3 is pulled out from the cylindrical protrusion 42 of the reflector 4 and removed from the reflector 4.
(2) Replace the lamp of the lamp holder 3 with a new one while being removed from the reflector 4.
(3) Thereafter, the connecting cylinder portion 32 of the lamp holder 3 is inserted into the cylindrical protrusion 42 of the reflector 4 and connected to the reflector 4. In order to fix the lamp holder 3 in a state where the lamp holder 3 is inserted into the opening 41 of the reflector 4, the reflector 4 is provided with a connector 8 made of an elastic spring.

  As described above, the LED lamp 1 that is used in place of the light bulb, that is, replaced by the light bulb, is connected to the socket 5 of the lamp holder 3 by screwing as shown in FIGS. 9 to 13. And a lamp body 10 fixed to the connecting portion 11. The connecting portion 11 is provided with a male screw 12 on the outer periphery so that it can be screwed into a female screw 52 of the socket 5. Further, like the light bulb, the connecting portion 11 is provided with electrodes 13 and 14 on the outer peripheral surface and the tip so as to be insulated from each other.

  The lamp body 10 includes a substrate holder 20 having an integral structure in the connecting portion 11, and a fixing base 15 that fixes a plurality of white LEDs 2 at the center and the outer peripheral portion is fixed in front of the substrate holder 20. . The fixing base 15 includes a plurality of side substrates 15A for fixing the white LEDs 2 to the outer peripheral portion, and a central substrate 15B for fixing the white LEDs 2 to the central portion. The side board 15A and the central board 15B of the fixed base 15 have a plurality of white LEDs 2 fixed on their surfaces. Further, the transparent cover 16 is connected to the substrate holder 20 so as to cover the fixed base 15.

  The substrate holder 20 is integrally formed of plastic in a shape formed by connecting a disc-shaped flange portion 22 to one end of a columnar insertion portion 21 inserted into the center hole 34 of the lamp holder 3. The outer shape of the insertion portion 21 is smaller than the outer shape of the center hole 34 so that the insertion portion 21 can be inserted into the center hole 34 of the lamp holder 3. The insertion portion 21 to be inserted into the center hole 34 is fixed by covering the connecting portion 11 at the tip thereof.

  The flange 22 fixes the side substrate 15 </ b> A of the fixing base 15. The flange portion 22 in the figure is provided with a connecting wall 23 protruding from the front surface. The connecting wall 23 is provided on the back side of the side substrate 15A. Further, the flange portion 22 is provided with a fitting convex portion 26 so as to face the connecting wall 23, and the connecting wall 23 and the fitting convex portion 26 are connected by inserting the rear end of the side substrate 15A. The insertion portion 27 is used. Since the insertion portion 27 is inserted into the side substrate 15A and disposed at a fixed position, the interval is substantially equal to the thickness of the side substrate 15A, and more precisely, slightly larger than the thickness of the side substrate 15A.

  In the LED lamp 1 of FIGS. 12 and 13, six side substrates 15A are arranged in a hexagonal cylinder shape, and the fixing base 15 is in a hexagonal cylinder shape. Therefore, the connection wall 23 is arranged in a hexagonal cylinder shape on the substrate holder 20, and the fitting convex portion 26 is provided on the outside thereof.

  In order to connect the side substrate 15A inserted into the fitting portion 27 so as not to come off, the connecting wall 23 is provided with a locking projection 23a guided by the locking recess 15a of the side substrate 15A. Since the side substrate 15A of FIG. 13 is provided with the locking recesses 15a on both sides, the locking projections 23a are provided on both sides of the connecting wall 23. Since the side substrate 15A is provided with a locking recess 15a at a position away from the rear end in the forward direction, the locking projection 23a is disposed at a position where the locking recess 15a is guided. The side substrate 15A having the rear end inserted into the insertion portion 27 is connected to the substrate holder 20 so as not to come out by guiding the locking projection 23a to the locking recess 15a. However, the side substrate 15A is detached from the substrate holder 20 in a tilted posture. In other words, the rear end is inserted into the fitting portion 27 in a tilted posture, and then is engaged with the locking recess 15a in a vertical posture with respect to the flange portion 22. It will be in the state which guides the stop convex part 23a and cannot be removed. The side substrate 15A is connected so as not to be inclined with respect to the central substrate 15B at the tip.

  In order to fix the side substrate 15A to the fixing base 15, the central substrate 15B is provided with a connecting hole 15c for inserting the tip of the side substrate 15A as shown in FIG. Since the side surface substrate 15A shown in the drawing has a plurality of connection protrusions 15b at the tip, a plurality of connection holes 15c are provided in the central substrate 15B to insert and connect the connection protrusions 15b. The connecting protrusion 15b provided at the tip of the side substrate 15A is inserted into the connecting hole 15c of the central substrate 15B, and the tips of the side substrates 15A are connected to each other. In this state, the six side substrates 15A constituting the hexagonal cylindrical fixing base 15 are connected to the substrate holder 20 so that the tips thereof do not spread, that is, do not tilt. The side substrate 15 </ b> A that does not tilt is fixed so that the locking projection 23 a is guided by the locking recess 15 a and does not come out of the substrate holder 20.

  Further, in the LED lamp 1 of FIGS. 10 to 12, a set screw 24 penetrating the side substrate 15 </ b> A is screwed into the connecting wall 23, and the side substrate 15 </ b> A is securely fixed to the substrate holder 20 with the set screw 24. The side substrate 15A does not come off the substrate holder 20 in the state where the set screw 24 is not loosened. Further, the above LED lamp 1 is connected to the substrate holder 20 so as to guide the locking projection 23a to the locking recess 15a and prevent it from coming off even if the set screw 24 is loosened. Therefore, the LED lamp does not necessarily have to fix the side substrate to the connecting wall via the set screw, and the set screw can be omitted. Furthermore, the side substrate can be bonded and fixed to the connecting wall.

  The above fixing base 15 is fixed in a vertical posture with respect to the flange portion 22, and its central axis is coaxial with the male screw 12 of the connecting portion 11, that is, the central axis of the fixing base 15 and the center of the connecting portion 11. The fixing base 15 is fixed to the substrate holder 20 so that the shaft is arranged in the same straight line.

  Further, in the LED lamp 1 shown in the figure, the fixing base 15 has a hexagonal cylindrical shape, but this fixing base can also be a polygonal cylindrical shape of a pentagon or more.

  Each side substrate 15A is electrically connected to the central substrate 15B by coupling the coupling protrusion 15b to the coupling hole 15c of the central substrate 15B. This side substrate 15A is provided with a conductive portion (not shown) in the connecting protrusion 15b, and this conductive portion is soldered to a conductive portion (not shown) provided in the connecting hole 15c of the central substrate 15B for electrical connection. To do. Since the LED lamp 1 of FIG. 13 connects the plurality of connecting protrusions 15b to the central substrate 15B, the positive side and the negative side of the side substrate 15A can be connected to the central substrate 15B. This structure allows the side substrate 15A to be physically fixed to the central substrate 15B and electrically connected to the central substrate 15B. However, the LED lamps of the present invention can also be fixed to each other by adhering the side substrates or via fixing auxiliary parts such as L metal fittings and set screws.

  The side board 15A arranged on the fixed base 15 has a cooling gap 28 between the side boards 15A adjacent to each other. The fixed base 15 having the cooling gap 28 can efficiently cool the side substrate 15A, that is, the white LED 2 by causing the cooling gap 28 to convect air in a state where the LED lamp 1 is disposed in a horizontal posture.

  The fixed base 15 fixes a plurality of white LEDs 2 on the surfaces of the side substrate 15A and the central substrate 15B. The side substrate 15A fixes a plurality of white LEDs 2 apart in the longitudinal direction, and the number of white LEDs 2 arranged in the width direction is larger at the tip than at the rear end. The reason why the number of white LEDs 2 arranged in the width direction is increased at the front end than at the rear end is that the radius of the reflector 4 of the concave mirror 40 increases toward the front end.

  11 and 13, white LEDs 2 are arranged in three rows apart in the longitudinal direction of the side substrate 15A, and two white LEDs 2a are laterally separated in the first row located on the tip side. One white LED 2c is arranged in the third row arranged on the rear end side. Furthermore, the LED lamp 1 shown in the figure also has two white LEDs 2b arranged in the second row. That is, in the illustrated LED lamp 1, two white LEDs 2 are arranged in the first and second rows, and one white LED 2 is arranged in the third row.

  FIG. 14 shows the position of the white LED 2 reflected on the concave mirror 40 by ● when the reflector 4 of the concave mirror 40 is viewed from the front. As shown in this figure, the white LEDs 2 in the first row, the second row, and the third row arranged in the longitudinal direction of the side substrate 15A are reflected on the concave mirror 40 in a state of being gradually arranged from the outside to the inside. The first row of white LEDs 2a reflected on the outermost side of the reflector 4 are arranged on the largest circumference, the second row of white LEDs 2b on the inner circumference, and the third row of white LEDs 2c on the second circumference. It is located on the smallest circumference inside the circumference of the white LEDs 2b in the row. When the same number of white LEDs are arranged on the small circumference and the large circumference, the intervals between the white LEDs on the small circumference are narrowed. This is because the circumference becomes shorter.

  In the LED lamp 1 shown in FIGS. 9 to 13, one white LED 2 is arranged in the third row of the side substrate 15A, and two white LEDs 2 are arranged in the second and first rows. Thus, six white LEDs 2 are arranged on the smallest circumference, and twelve white LEDs 2 are arranged on the middle and outermost circumferences. Therefore, the difference between the brightness of the small circumference and the brightness of the large circumference can be reduced, and the entire surface can be made uniform. That is, the entire surface of the front cover 9 can be illuminated uniformly and brightly. Further, as shown in FIG. 15 and FIG. 16, by arranging three white LEDs 2 in the first row, two in the second row, and one in the third row of the side substrate 15A, The front cover 9 can be evenly brightened with uniform brightness.

  In the LED lamp 1 of FIG. 13, four white LEDs 2 are further fixed to the central substrate 15 </ b> B, and a total of 34 white LEDs 2 are fixed to the fixed base 15. The LED lamp of the present invention does not specify the number of white LEDs fixed to the fixed base, but the overall brightness can be adjusted by changing the number of white LEDs fixed to the fixed base. In addition, the overall brightness can be adjusted by changing the power consumption of the white LED itself fixed to the fixed base.

  The white LED 2 fixed to the side substrate 15A and the central substrate 15B is preferably a chip-type white LED 2 that is a substrate mounting type. The chip-type white LED 2 has a feature that it can be easily mounted at an accurate position on the substrate. Furthermore, the chip-type white LED 2 has a wide directivity characteristic, and has a characteristic that the irradiated light is widely diffused. Therefore, the chip-type white LED 2 is more uniform than a white LED having a shell-type condensing part. There is a feature that can irradiate the front cover. That is, the LED lamp can disperse the light emitted from the white LED widely and uniformly and brightly irradiate the front cover uniformly without disposing the white LED having a wide directivity. However, in the LED lamp of the present invention, the white LED to be used is not necessarily a chip-type LED, and an LED having a condensing part (for example, a bullet-type LED) can also be used. Further, the white LED 2 is preferably a light bulb color LED. However, a white LED that emits white light other than the light bulb color can also be used.

  FIG. 17 is a schematic circuit diagram of the LED lamp 1, and FIG. 18 is a layout diagram in which a plurality of white LEDs 2 are arranged on the central substrate 15B and the side substrate 15A. As shown in these drawings, the LED lamp 1 has electrodes 13, 14 provided on the outer peripheral surface and the tip of the connecting portion 11 connected to a rectifier circuit 18. A current element 19 is connected in series. This LED lamp 1 turns on a plurality of white LEDs 2 by converting a commercial power source into a pulsating flow by a rectifier circuit 18. The constant current element 19 is stabilized so that the current of the white LED 2 does not exceed a certain current value.

  The rectifier circuit 18 is a diode bridge 18A. The diode bridge 18A converts the input AC power source into DC and outputs DC rectified on the plus side and the minus side of a series circuit formed by connecting a plurality of white LEDs 2 in series. The number of white LEDs 2 connected in series is specified by the supplied power supply voltage and the rated voltage of the white LEDs 2. For example, an LED lamp that supplies AC 100V AC power as a commercial power source can be lit by connecting 30 to 40 white LEDs having a rated voltage of 3V in series. Since the LED lamp 1 shown in the drawing includes 34 white LEDs 2, all the white LEDs 2 are connected in series. However, a plurality of white LEDs can also be connected in series and in parallel.

  In a series circuit of white LEDs 2 in which a large number of white LEDs 2 are connected in series, when one white LED is cut off, the entire white LED is not lit. The probability that any of the white LEDs will be cut increases as the number of white LEDs connected in series increases. The pedestrian traffic light causes a traffic accident when the LED lamp 1 is turned off and cannot be lit. Therefore, it is important to reliably turn on the LED lamp 1 in any state. This problem can be solved by connecting a plurality of white LEDs in parallel. The white LEDs connected in parallel do not turn off the white LEDs connected in parallel even if one of the white LEDs is cut off. However, the circuit configuration for connecting the white LEDs in parallel requires that the voltage supplied to the white LEDs be lower than the voltage obtained by rectifying the commercial power supply. Need. A switching power supply is mainly used for this power supply circuit. A switching power supply is more complicated and expensive than a rectifier circuit. In addition, there is a drawback that the life is shortened as compared with the rectifier circuit. This is because the built-in electrolytic capacitor deteriorates with time.

  A circuit configuration in which commercial power is rectified by a rectifier circuit of a diode and directly supplied to a white LED is very simple and can be manufactured at low cost. In particular, a rectifier circuit that does not smooth a pulsating current rectified by a diode with an electrolytic capacitor has no components that deteriorate with time, and operates stably without failing for a long time. However, since this circuit configuration rectifies the commercial power supply, the output voltage is considerably higher than the lighting voltage of the white LED. For example, the pulsating flow obtained by rectifying a 100V commercial power supply has a peak voltage of about 140V, which is considerably high. In order to light a white LED with this voltage, it is necessary to connect a large number of white LEDs in series and reduce the voltage applied to each white LED. However, as described above, in the circuit configuration in which a large number of white LEDs are connected in series, when any one white LED is cut off, all the other white LEDs connected in series are not lit.

  As shown in FIG. 19, the bypass circuit 6 connected in parallel to the white LED 2 bypasses the cut white LED 2 'and prevents other white LEDs 2 from disappearing. The bypass circuit 6 is OFF when the white LEDs 2 connected in parallel are not cut off as shown in FIG. 19A, and the white LED 2 is cut off as shown in FIG. 19B. Is switched on. The bypass circuit 6 includes a voltage detection unit 61 that detects a voltage at both ends of the white LEDs 2 connected in parallel, and a switching element 62 that is controlled to be turned on and off by the voltage detection unit 61. When the white LED 2 is cut off and the input voltage exceeds the normal voltage, the voltage detection unit 61 switches the switching element 62 to ON so that the cut white LED 2 'bypasses the current. The voltage at both ends of the LED is 1.5 to 4 V of the lighting voltage of the white LED 2 when the white LED 2 is not cut off. However, when the white LED 2 is cut off, both ends of the cut off white LED 2 'are in an open state and become higher than the lighting voltage. When the voltage across the LED becomes higher than the lighting voltage, the voltage detection unit 61 is provided with a circuit that switches the switching element 62 to ON and bypasses the cut white LED 2 'to flow current. When the switching element 62 is switched on, the voltage across the broken white LED 2 'decreases. Even in this state, the switching element 62 is maintained in the ON state, and a state in which a current is passed so as to bypass the disconnected white LED 2 ′ is maintained.

  As shown in FIGS. 13 and 10, the bypass circuit 6 is mounted on the back surface of the side substrate 15A and the central substrate 15B and energizes the bypassed white LED to bypass it.

  The bypass circuit 6 is ideally connected in parallel with all white LEDs. However, if the bypass circuits are controlled in parallel with all the white LEDs, the same number of bypass circuits as the white LEDs are required, resulting in a high component cost.

  In the LED lamp 1 of FIGS. 18 and 19, the bypass circuit 6 is connected in parallel with the series circuit of the plurality of white LEDs 2, so that the number of bypass circuits 6 is smaller than that of the white LEDs. The LED lamp 1 of FIGS. 18 and 19 includes a small number of LED bypass circuits 6A connected in parallel with a small number of white LEDs 2, and a large number of LEDs connected in parallel with a series circuit of a larger number of white LEDs 2 than the small number of LED bypass circuits 6A. The bypass circuit 6B is used. In the illustrated LED lamp 1, a minority LED bypass circuit 6A is connected in parallel with one white LED 2, and a majority LED bypass circuit 6B is connected in parallel with a series circuit of two white LEDs 2. Although not shown, the minority LED bypass circuit can be connected in parallel with a series circuit of two or more white LEDs, and the multiple LED bypass circuit can be connected in parallel with the series circuit of more white LEDs than the minority LED bypass circuit. .

  In the LED lamp of FIG. 19, the number of white LEDs 2 to which the bypass circuit 6 is connected in parallel is made larger at the front end portion of the side substrate 15A than at the rear end portion. That is, the majority LED bypass circuit 6B is connected to a series circuit of white LEDs 2 at the front end of the side board 15A, and the minority LED bypass circuit 6A is connected in parallel with the white LED 2 at the rear end of the side board 15A. In the LED lamp of FIG. 19, the first row of white LEDs 2a and the second row of white LEDs 2b arranged in the longitudinal direction on both sides of the side substrate 15A are connected in series, and a number of LED bypasses are connected to the series circuit of these white LEDs 2a and 2b. The circuit 6B is connected in parallel, and the minority LED bypass circuit 6A is connected in parallel with one white LED 2c arranged in the third row. Therefore, two sets of many LED bypass circuits 6B and one set of minority LED bypass circuits 6A are mounted on one side substrate 15A.

  The white LED 2 provided on the central board 15B has two white LEDs 2d connected in series, and a large number of LED bypass circuits 6B are connected in parallel to the series circuit of these white LEDs 2d. However, the white LEDs provided on the central substrate can be connected to each white LED in parallel with a minority LED bypass circuit, that is, a minority LED bypass circuit can be connected in parallel with one white LED.

  When the white LED 2c in the third row is cut off and the LED lamp 1 is not turned on, only the cut off white LED 2 'is turned off and all other white LEDs 2 can be turned on. Further, when any one of the white LEDs 2 arranged in the first row and the second row is cut off and does not light up, only one white LED 2 arranged in the longitudinal direction of the side substrate 15A is turned off with respect to the cut white LED 2 ′. That is, the two white LEDs 2 are turned off and all other white LEDs 2 are turned on. Since the two white LEDs 2 are arranged in the longitudinal direction of the side substrate 15A, even if one of the white LEDs 2 is cut off and turned off, the uneven brightness of the front cover 9 can be minimized. This is because, when the front cover 9 is viewed from the front, the interval between the white LEDs 2 in the first row and the second row is narrower than the interval between the white LEDs 2 arranged on the circumference in the first row and the second row. is there.

  However, the multiple LED bypass circuit is not necessarily connected in parallel with the series circuit of two white LEDs arranged in the longitudinal direction of the side board, but is connected in parallel with the series circuit of white LEDs adjacent in the lateral direction of the side board. It is also possible to connect in parallel with a series circuit of three or more white LEDs without connecting in parallel with a series circuit of two white LEDs. Also, the minority LED bypass circuit is not necessarily connected in parallel with one white LED, but in parallel with the series circuit of a smaller number of white LEDs than the series circuit of white LEDs in which the majority LED bypass circuit is connected in parallel. It can also be connected.

  The transparent cover 16 has translucency that can transmit light emitted from the plurality of white LEDs 2 arranged on the substrate holder 20 to the outside. The transparent cover 16 is formed of plastic or glass into a shape that can accommodate the fixing table 15 made of a plurality of substrates. The transparent cover 16 of FIGS. 9 and 10 has a central LED 2Y that is fixed to the central portion of the fixing base 15 with an outer peripheral portion 16A that transmits the light of the outer peripheral LED 2X that is fixed to the outer peripheral portion of the fixing base 15 being cylindrical. The central portion 16B that transmits the light is spherical, and the outer peripheral portion 16A is closed by the central portion 16B. The transparent cover 16 houses therein a fixing base 15 that is fixed to the substrate holder 20.

  The transparent cover 16 is provided with a discoloration filter 7 that discolors and transmits the light of the outer peripheral LED 2X in the outer peripheral portion 16A that transmits the light of the outer peripheral LED 2X fixed to the outer peripheral portion of the fixed base 15. This discoloration filter 7 discolors and transmits the light of the outer peripheral LED 2X. The transparent cover 16 shown in the figure is provided with the color changing filter 7 on almost the entire outer peripheral portion 16A. This structure can effectively discolor and transmit light emitted from the outer peripheral LED 2X fixed to the outer peripheral portion of the fixed base 15. However, the transparent cover can be partially provided with a discoloration filter on the outer periphery. The transparent cover can disperse and transmit light emitted from the outer peripheral LED fixed to a specific region of the outer peripheral portion of the fixed base. That is, the transparent cover can adjust the state where the light emitted from the outer peripheral LED is discolored by adjusting the region of the color changing filter provided on the outer peripheral portion. The color change filter 7 shown in the figure has a colored film 29 attached to the surface of the transparent cover 16 so as to transmit light of a specific wavelength. However, the discoloration filter can be provided by applying a light-transmitting paint on the surface of the transparent cover and coloring it, or by adding a pigment or dye to transparent plastic or glass forming the transparent cover. You can also.

  The discoloration filter 7 is an absorption spectrum filter that transmits the light of the white LED 2 and irradiates the blue-green portion 9X of the front cover 9 to emit blue-green light comparable to a light bulb. As shown in FIG. 3, the white LED 2 is white by irradiating the emission spectrum of the blue LED and the emission spectrum of the phosphor that is excited by the emission color and emits light. The discoloration filter 7 transmits light of this emission spectrum, and emits the blue-green portion 9X of the front cover 9 to a blue-green color comparable to a light bulb. FIG. 20 shows an absorption characteristic for absorbing the light transmitted by the color change filter 7. The discoloration filter 7 is a filter that absorbs light having a wavelength of 420 nm, and is colored in a blue attenuation color that absorbs a blue emission peak. Here, as the blue attenuation color, a color that transmits white light and is preferably yellow, yellow-green, green, or the like is used. That is, the discoloration filter 7 can be a filter colored yellow or green. The discoloration filter 7 absorbs the blue light emission peak of the white LED 2. Therefore, the emission spectrum of the light transmitted through the color changing filter 7 has a blue emission peak attenuated as shown in FIG. When the light having the emission spectrum shown in FIG. 21 irradiates the blue-green portion 9X of the front cover 9, the light is emitted in a blue-green color comparable to a light bulb. The absorption characteristic of the color changing filter 7 is set to an optimum state in consideration of the emission spectrum of the white LED 2. The discoloration filter 7 has an absorption characteristic selected so as to transmit the light emission color of the white LED 2 and irradiate the blue-green portion 9X of the front cover 9 with the transmitted light to emit light in blue-green comparable to a light bulb. Therefore, the absorption characteristic of the color change filter 7 changes depending on the emission spectrum of the white LED 2 and is not specified as the absorption characteristic shown in FIG.

  The transparent cover 16 of FIG. 9 transmits the light of the outer peripheral LED 2X to the outer peripheral portion 16A and transmits the light of the central LED 2Y to the central portion 16B. The central portion 16B is an uncolored portion that is not colored, and transmits all the emission colors without attenuating the light of the white LED 2 as much as possible. However, by providing a filter that absorbs a specific light emission color at the center, and allowing the light of the white LED to pass therethrough, it is possible to obtain a white color that is closer to a light bulb. This structure uses a white LED whose emission color is different from the white color of the light bulb, and can make the white portion of the front cover a light emission color comparable to the white color of the light bulb.

  The surface of the central portion 16B at the front end of the transparent cover 16 is an infinite number of uneven surfaces that diffusely reflect light, and the outer peripheral portion 16A that is a portion excluding the front end portion has a smooth surface. The smooth surface efficiently transmits the light of the white LED 2 and irradiates the front cover 9 brightly, and the irregular surface that irregularly reflects the light of the central LED 2Y fixed to the central substrate 15B scatters the light of the front cover 9. Irradiate the surface with even brightness.

  The transparent cover 16 is fixed to the front of the substrate holder 20 and transmits the light emitted from the white LED 2 as a light source housed inside to the outside. The transparent cover 16 is fixed to the outer peripheral edge portion of the flange portion 22 of the substrate holder 20 by bonding, screwing, or also with a locking structure.

  Further, the transparent cover 16 shown in the figure opens a ventilation port 17 for ventilating the air inside. The transparent cover 16 shown in FIG. 12 is provided with a slit-like ventilation port 17 at a position facing the cooling gap 28 provided between the side substrates 15 </ b> A constituting the fixed base 15. As described above, the transparent cover 16 provided with the ventilation port 17 at a position facing the cooling gap 28 of the fixed base 15 allows the air flow flowing through the cooling gap 28 between the side substrates 15 </ b> A to flow smoothly outside the transparent cover 16. Ventilation is performed to efficiently cool the heat generated by the side substrate 15A and the white LED 2. Furthermore, the transparent cover 16 shown in FIG. 12 is provided with a ventilation port 17 between the ventilation ports 17 provided at a position facing the cooling gap 28 of the fixed base 15. Thus, the transparent cover 16 provided with a large number of ventilation ports 17 can reliably ventilate the internal air regardless of the position at which the transparent cover 16 is stopped. Further, the ventilation port 17 shown in the figure is opened so that the width of the slit becomes wider from the outer peripheral portion 16A of the transparent cover 16 toward the central portion 16B. Thus, the transparent cover 16 that increases the opening area of the ventilation port 17 toward the central portion 16B can efficiently radiate heat from the central substrate 15B on which many electronic components are arranged.

  In the LED lamp 1 described above, the fixed base 15 has a shape in which a plurality of side substrates 15A are arranged in a polygonal cylindrical shape, and a central substrate 15B is arranged on the front end surface. The LED lamp 1 irradiates light of the outer peripheral LED 2X fixed to the surface of the side substrate 15A of the fixing base 15 in the outer peripheral direction, and irradiates light of the central LED 2Y fixed to the surface of the central substrate 15B forward. The front cover can be illuminated uniformly and brightly. However, the LED lamp does not specify the shape of the fixed base as described above. The fixed base can fix a plurality of white LEDs, and can have all other shapes that can irradiate light emitted from these white LEDs in the forward or outer peripheral direction. For example, the fixed base can be fixed in a posture in which all of the plurality of white LEDs are irradiated forward.

  Furthermore, the LED lamp may have a structure shown in FIG. The LED lamp 1 shown in this figure is provided with a color change filter 7 on almost the entire surface of the transparent cover 16. Further, in the LED lamp 1, the central LED 2Y fixed to the central portion of the fixing base 15 and the outer peripheral LED 2X fixed to the outer peripheral portion have different emission colors. In the LED lamp 1, for example, the center LED 2Y can be a white LED 2 having a higher color temperature than the outer peripheral LED 2X. This LED lamp 1 transmits the light of the central LED 2Y, which has a higher color temperature than the outer peripheral LED 2X, to the central portion 16B of the transparent cover 16, and can brightly illuminate the white portion at the central portion of the front cover. Further, the light of the outer peripheral LED 2X having a color temperature lower than that of the central LED 2Y is transmitted through the outer peripheral portion 16A of the transparent cover 16, and the blue-green portion of the outer peripheral portion of the front cover can be made to emit light comparable to a light bulb. This LED lamp 1 adjusts the absorption characteristic that the discoloration filter 7 provided in the transparent cover 16 absorbs the transmitted light and the emission color of the white LED 2 fixed to the central portion and the outer peripheral portion of the fixing base 15 to adjust the front surface. The cover can be illuminated from the inside with an ideal emission color. However, in the LED lamp in which the color change filter is provided on the entire surface of the transparent cover, all the white LEDs fixed to the central portion and the outer peripheral portion of the fixing base can have the same emission color.

  Further, the LED lamp 1 shown in FIG. 23 is provided with a discoloration filter 7 of a different color at the central portion 16B and the outer peripheral portion 16A of the transparent cover 16. The LED lamp 1 transmits the light of the central LED 2Y fixed to the central portion of the fixing base 15 through the discoloration filter 7B of the central portion 16B and irradiates the outer peripheral LED 2X fixed to the outer peripheral portion of the fixing base 15. The light is transmitted through the discoloration filter 7A on the outer peripheral portion 16A and irradiated. The transparent cover 16 adjusts the transmitted light by changing the absorption characteristic of the transmitted light between the color changing filter 7B in the central portion 16B and the color changing filter 7A in the outer peripheral portion 16A. For example, the transparent cover 16 lowers the blue attenuation characteristic of the color change filter 7B in the central part 16B, that is, the characteristic of absorbing the blue emission peak, as compared with the color change filter 7A in the outer peripheral part 16A. As a result, the LED lamp 1 illuminates the white portion of the central portion of the front cover brightly with the light transmitted through the color change filter 7B of the central portion 16B of the transparent cover 16, and the front surface with the light transmitted through the color change filter 7A of the outer peripheral portion 16A. The blue-green portion of the outer periphery of the cover can emit light in a blue-green color that is closer to the color emitted by the bulb.

  For example, the transparent cover 16 colors the color change filter 7A on the outer peripheral portion 16A to yellow or green, and the color change filter 7B on the central portion 16B is lighter than the color change filter 7A on the outer peripheral portion 16A to adjust the transmitted light. To do. In this LED lamp 1, the light emission color of all the white LEDs 2 fixed to the central portion and the outer peripheral portion of the fixing base 15 is set to white having a higher color temperature than the light bulb color, and the white portion and the outer periphery of the central portion of the front cover The blue-green part of the part can be made an emission color comparable to a light bulb. Further, the LED lamp 1 includes an absorption characteristic in which the color change filter 7B provided in the central portion 16B of the transparent cover 16 and the color change filter 7A provided in the outer peripheral portion 16A absorb transmitted light, and light emission of the white LED 2 fixed to the fixing base 15. By adjusting the color, the front cover can be illuminated with the ideal emission color from the inner surface. However, this LED lamp can also fix white LEDs of different emission colors at the center and the outer periphery of the fixing base.

  The above LED lamps are used in place of light bulbs for pedestrian traffic lights, but these LED lamps are used in place of light bulbs for other traffic traffic lights, for example, traffic lights for vehicles or railways. You can also. Even in this application, the LED lamp described above discolors and transmits the light of the white LED with the discoloration filter, so that the blue-green portion of the front cover can be made bluish green that approximates the color emitted by the light bulb.

1 ... LED lamp 2 ... white LED 2 '... cut white LED
2a ... LED
2b ... LED
2c ... LED
2d ... LED
2X ... Peripheral LED
2Y ... Central LED
3 ... Lamp holder 4 ... Reflector 5 ... Socket 6 ... Bypass circuit 6A ... Minority LED bypass circuit
6B ... Many LED bypass circuits 7 ... Color change filter 7A ... Color change filter
7B ... Discoloration filter 8 ... Connector 9 ... Front cover 9A ... Transparent plate
9B ... Filter
9X: Blue-green part 10 ... Lamp body 11 ... Connecting part 12 ... Male screw 13 ... Electrode 14 ... Electrode 15 ... Fixing base 15A ... Side board
15a ... Locking recess
15b ... Connection protrusion part
15B ... Central substrate
15c ... Connecting hole 16 ... Transparent cover 16A ... Outer periphery
16B ... Central part 17 ... Ventilation port 18 ... Rectification circuit 18A ... Diode bridge 19 ... Constant current element 20 ... Substrate holder 21 ... Insertion part 22 ... Gutter 23 ... Connecting wall 23a ... Locking convex part 24 ... Set screw 26 ... Fit Placement convex part 27 ... Insertion part 28 ... Cooling gap 29 ... Colored film 31 ... Ring plate 32 ... Connection cylinder part 33 ... Inner cylinder 34 ... Center hole 40 ... Concave mirror 41 ... Desorption hole 42 ... Cylindrical protrusion 43 ... Opening part 44 ... Vertical surface 45 ... Stepped portion 48 ... Packing 49 ... Packing 52 ... Female screw 61 ... Voltage detection unit 62 ... Switching element 91 ... LED lamp 92 ... LED
94 ... Reflector 95 ... Cylinder 95A ... Side
95B ... tip end 99 ... front cover

Claims (8)

A concave mirror (40) that reflects light on the surface, and has an opening (43) screwed into a socket (5) provided at the center of a rectangular reflector (4), and a light source connected in a replaceable manner. An LED lamp used for a pedestrian traffic light with a white LED (2),
A lamp provided with a connecting portion (11) provided with a male screw (12) on the outer periphery to be screwed and connected to the socket (5), and a plurality of white LEDs (2) fixed to the connecting portion (11) It consists of the body (10),
The lamp body (10) includes a fixing base (15) in which a white LED (2) is fixed to a central portion and an outer peripheral portion, and a transparent cover (16) that covers the outside of the fixing base (15). Prepared,
This transparent cover (16) discolors and transmits the light of the outer peripheral LED (2X) to the outer peripheral portion (16A) that transmits the light of the outer peripheral LED (2X) fixed to the outer peripheral portion of the fixing base (15). The discoloration filter (7) is provided, and the discoloration filter (7) discolors and transmits the light of the outer peripheral LED (2X) fixed to the outer peripheral portion of the fixed base (15). LED lamps used for pedestrian traffic lights.   The LED lamp used for the traffic light for pedestrians according to claim 1, wherein the discoloration filter (7) is colored in a blue decay color.   The LED lamp used for the traffic light for pedestrians according to claim 1 or 2, wherein the transparent cover (16) has a colored film (29) attached to the outer peripheral surface to form a discoloration filter (7).   The transparent cover (16) has a central portion (16B) as a non-colored portion, and transmits the light of the central LED (2Y) disposed in the central portion of the fixed base (15) to the non-colored portion. The LED lamp used for the pedestrian traffic light as described in any one of Claims 1 thru | or 3.   The transparent cover (16) is provided with a discoloration filter (7) of a different color at the central part (16B) and the outer peripheral part (16A), and the central LED (2Y) fixed to the fixing base (15) The light from the outer peripheral LED (2X) is transmitted through the color changing filter (7A) of the outer peripheral part (16A). The LED lamp used for the traffic signal for pedestrians described in any one of.   The walking according to any one of claims 1 to 5, wherein the white LED (2) fixed to the fixed base (15) is a white diode that changes the light of a blue light emitting diode with a phosphor to become white. LED lamps used for traffic lights for passengers.   7. The fixing base (15) according to any one of claims 1 to 6, wherein a plurality of rectangular side substrates (15A) are arranged in a polygonal cylindrical shape, and a central substrate (15B) is arranged on the front end surface. LED lamp used for the pedestrian traffic light described in the above.   The center part (16B) of the transparent cover (16) is an infinite number of uneven surfaces for irregularly reflecting light, and the surface of the outer peripheral part (16A) is a smooth surface. LED lamp used for traffic lights.

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