JP2014220184A - Lamp and luminaire - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lamp including a fuse resistor by which the scattering of high-temperature molten material is prevented during the fusion cutting of a fusing body, and to provide a luminaire on which the lamp is mounted.SOLUTION: A lamp 1 includes a light source 2, an envelope 4 having a base 20 on one end side 4a and the light source 2 on the other end side 4b, a lighting device 5 for inputting electric power via the base 20 to light on the light source 2, and a fuse resistor 27 which consists of a resistor body 47 having a pair of electrodes 50, 50, a fusing body 40 connected to the pair of electrodes 50, 50 and provided between the pair of electrodes 50, 50, an insulator 51 for electrically insulating the fusing body 40 to protect it, and a pair of lead wires 39a, 39b connected to the pair of electrodes 50, 50, respectively, a protector 48 for protecting the resistor body 47, and fillers 49, 49 having electric insulation and heat resistance, and provided in the protector 48 so as to block the protector 48 at both sides 48a, 48b, and which is electrically connected to the base 20 and the lighting device 5.

Description

  One embodiment of the present invention relates to a lamp including a fuse resistor capable of preventing scattering of a high-temperature melt when a fuse is blown, and a lighting fixture equipped with the lamp.

  A light bulb-type fluorescent lamp as a lamp includes, for example, a cover (case) having a substantially cylindrical portion on one end side and an opening on the other end side, an E-shaped base attached to the substantially cylindrical portion, and a holder in the opening portion via a holder. A fluorescent lamp and a translucent glove that covers the fluorescent lamp are attached. The holder is locked to the opening, and the globe is fixed to the opening with, for example, an adhesive. And the lighting device which lights a fluorescent lamp is accommodated in the cover. The lighting device is protected from an abnormal current by a fuse (see, for example, Patent Document 1).

  In recent years, instead of a bulb-type fluorescent lamp, a bulb-type LED lamp using an LED as a light source has been rapidly used. This bulb-type LED lamp has a light emitting module in which an LED (light emitting diode) is mounted on one side of a substrate, an E-shaped base attached to one end, and a light emitting module on the other end (envelope) And a glove that covers the light emitting module provided on the other end side of the cover and the lighting device that lights the LED disposed in the cover. Some lighting devices include a fuse resistor, and the fuse resistor is disposed inside an E-shaped base (see, for example, Patent Document 2). The fuse resistor protects the lighting device by fusing when the input current flowing from the E-shaped base side abnormally increases due to the abnormality of the lighting device.

JP 2010-192344 A (page 5, FIG. 1) JP 2011-54537 A (page 10, FIG. 5)

  However, the fuse resistor is not quickly blown, and heat is generated by an increase in current, and the outer surface of the main body and the protective tube protecting the lead wire may melt and the main body may be exposed. And when an internal conducting wire (fused body) is melted, there is a problem that the high-temperature melt is scattered and the resin cover of the lamp, the circuit component of the lighting device, and the like are melted. In addition, the high-temperature melt may scatter to the outside of the lamp, and in this case, there is a problem that the luminaire main body, articles under the luminaire, and the like are damaged.

  An object of the present embodiment is to provide a lamp having a fuse resistor in which high-temperature melt is prevented from being scattered when a melted body is blown, and a lighting fixture to which the lamp is mounted.

  The lamp according to this embodiment includes a light source, an envelope, a lighting device, and a fuse resistor. The envelope is provided with a base on one end side and a light source on the other end side.

  The lighting device includes a circuit board disposed in the envelope and circuit components mounted on the circuit board. And the lighting device is formed so that electric power is inputted through the cap of the envelope and the light source is turned on.

The fuse resistor includes a resistor main body, a protective body, and a filling body. The resistor body includes a pair of electrodes, a melted body, an insulator, and a pair of lead wires. The pair of lead wires are respectively connected to a pair of electrodes. The melted body is connected to the pair of electrodes and provided between the pair of electrodes. The insulator protects the melted body by electrical insulation.
The protector protects the resistor body. The filling body has electrical insulation and heat resistance, and is provided in the protective body so as to close both sides of the protective body.

  According to the embodiment of the present invention, since the fuse resistor is closed on both sides of the protector that protects the resistor main body by the filler, it is possible to prevent scattering of the high-temperature melt when the fusing body is blown. Can be expected.

It is a schematic sectional side view of the lamp | ramp which shows the 1st Embodiment of this invention. It is an enlarged view of the A part of FIG. 1 same as the above. It is a schematic circuit diagram of a lighting circuit same as the above. FIG. 2 is a schematic front view showing a part of the fuse resistor of Example 1 in section. It is a schematic front view which partially shows a resistor main body same as the above. FIG. 3 is a schematic front view showing a part of the fuse resistor of Example 2 in section. FIG. 5 is a schematic front view showing a part of the fuse resistor of Example 3 in section. FIG. 6 is a schematic front view showing a part of the fuse resistor of Example 4 in section. FIG. 6 is a schematic front view showing a part of the fuse resistor of Example 5 in section. FIG. 6 is a schematic front view showing a part of the fuse resistor of Example 6 in section. It is a schematic front view which shows a partial cross section of the fuse resistor of Example 7 same as the above. FIG. 10 is a schematic front view showing a part of the fuse resistor of Example 8 in section. FIG. 12 is a schematic front view showing a partial cross section of the fuse resistor of the ninth embodiment. FIG. 12 is a schematic front view showing a partial cross section of the fuse resistor of the tenth embodiment. It is a schematic front view which shows the fuse resistor of Example 11 same as the above. It is a schematic front view which shows the fuse resistor of Example 12 same as the above. It is a schematic front view which shows a partial cross section of the fuse resistor of Example 13 as described above. It is a schematic sectional side view of the lamp | ramp which shows the 2nd Embodiment of this invention. It is a schematic sectional side view of the lamp | ramp which shows the 3rd Embodiment of this invention. It is a partial notch schematic side view of the lighting fixture which shows 4th Embodiment of this invention. It is a partially cut away schematic side view of another lighting fixture same as the above.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. First, a first embodiment of the present invention will be described. The present embodiment is a lamp.

  As shown in FIG. 1, the lamp 1 of the present embodiment is a light bulb-shaped LED lamp (LED light bulb) that is attached to and detached from a light bulb socket, and is configured, for example, as a mini-krypton light bulb type. The lamp 1 includes a light emitter 2 as a light source, an envelope 4 having a mounting body 3, a lighting device 5, and a globe 6. And the fuse resistor 27 which protects the lighting device 5 from overcurrent is provided.

  The light emitter 2 is formed to include a mounting substrate 7 and a plurality of LED elements 8. The mounting substrate 7 is made of, for example, a synthetic resin plate having a thickness of 1.2 mm, for example, a glass epoxy plate, and has an outer shape, for example, a regular square. The LED element 8 is a package product, for example, one that emits white light. The plurality of LED elements 8 are mounted concentrically on the one surface 7a side of the mounting substrate 7, and are connected in series by a wiring pattern (not shown). The LED elements 8 connected in series are connected to a connector 9 provided on the one surface 7 a side of the mounting substrate 7. And it is connected to the lighting device 5 by an output line 10 electrically connected to the connector 9.

  When a predetermined constant current is supplied from the lighting device 5, the LED element 8 is lit (emits light) and emits white light. The white light passes through the globe 6 and is emitted to the external space.

  In this embodiment, the envelope 4 is formed of an outer case 11 made of a metal material having high thermal conductivity, for example, aluminum (Al), and the attachment body 3. The envelope 4 as a whole is formed in a cylindrical shape of a substantially inverted truncated cone that gradually increases in diameter from one end side 4a to the other end side 4b. The outer case 11 is provided with a dowel 12 projecting inwardly on the other end side 4b. Three dowels 12 are formed at 120 ° intervals in the circumferential direction. A plurality of fitting recesses 13 are formed at equal intervals in the circumferential direction on the inner surface 4e of the other end side 4b of the outer case 11. And the end surface 4d of the other end side 4b of the outer case 11 is formed in the plane. The outer case 11 is molded as described above by aluminum die casting.

  And the heat sink 14 is mounted on the end surface 4d of the envelope 4 (outer case 11). The heat radiating plate 14 is fixed to the end face 4d by screws 15. The heat radiating plate 14 is provided with an insertion hole 16 through which the screw 15 is inserted, and the dowel 12 is provided with a screw hole (not shown) of the screw 15. The light emitter 2 is attached to the heat sink 14. The mounting substrate 7 of the light emitter 2 is in close contact with the heat radiating plate 14 and fixed by screws (not shown). Thus, the light emitter 2 as a light source is provided on the other end side 4 b of the envelope 4. Note that the outer case 11 of the envelope 4 may be formed of a resin or ceramic having good thermal conductivity.

  An attachment body 3 is inserted and attached in the outer case 11. The attachment body 3 is formed in a cylindrical shape having an outer shape in which one end side 3 a is formed in a substantially cylindrical shape and the other end side 3 b is in close contact with the inner surface 4 e of the outer case 11. The attachment body 3 is formed of a synthetic resin having electrical insulation and high thermal conductivity, for example, polybutylene terephthalate (PBT) resin.

  The attachment body 3 is attached to the outer case 11 by engaging a fitting claw 17 provided on the other end side 3 b with the fitting recess 13 of the outer case 11. The same number of fitting claws 17 as the fitting recesses 13 are provided at equal intervals in the circumferential direction.

  The mounting body 3 is formed with a ridge 19 spirally on the outer surface of one end side 3a (one end side 4a of the envelope 4), and an E-shaped base 20 as a base is screwed to the ridge 19. Are combined. The E-shaped base 20 is caulked and fixed to the outer surface of the one end side 3 a of the attachment body 3.

  The E-shaped base 20 has, for example, an E17 shape, and is a male screw portion 21 that is screwed and fixed to the ridge 19 and fixed thereto, an insulating portion 22 provided on a distal end side 21a of the male screw portion 21, and the insulating portion 22 It has the top connection part 23 provided in a vertex.

  The male screw portion 21 is made of, for example, aluminum (Al) and is formed in a substantially cylindrical shape having a bottom portion 21b, and the top connection portion 23 is made of, for example, brass and is formed in a substantially cylindrical shape having a conical outer surface 23a. . The insulating portion 22 is made of, for example, glass or ceramic, is formed in a conical shape, is attached to the bottom portion 21 b of the male screw portion 21, and is provided with a top connection portion 23 at the apex.

  The male screw portion 21 and the top connection portion 23 are each electrically connected to an external power source via a light bulb socket. The insulating portion 22 electrically insulates the male screw portion 21 and the top connecting portion 23, each of which is a metal, away from each other. Thus, the E-shaped base 20 is attached to the one end side 4 a of the envelope 4 by attaching the male screw portion 21 to the attachment body 3.

The E-shaped base 20 and the metal outer case 11 are insulated by the outer peripheral surface 24 of the attachment body 3 between the E-shaped base 20 and the end surface 4 c of the outer case 11. The outer case 11 is formed of, for example, aluminum (Al) having a high thermal conductivity, so that heat generated in the light emitter 2 is quickly transferred and released from the outer surface 4f. Therefore, if the outer case 11 is formed of a synthetic resin or ceramic having high thermal conductivity and electrical insulation, the mounting body 3 can be formed integrally with the outer case 11 to form the envelope 4. Good.
The lighting device 5 includes a circuit board 25, various types of circuit components 26 mounted on the circuit board 25, and a fuse resistor 27.

  The circuit board 25 is made of a synthetic resin plate such as a glass epoxy material, and extends from one end side 4a (one end side 3a of the mounting body 3) to the other end side 4b (the other end side 3b of the mounting body 3) of the envelope 4. It is formed in a long shape and is arranged in a direction along the other end side 4b from one end side 4a of the envelope 4. On the inner surface 3c of the mounting body 3, a pair of substrate mounting grooves 28 and 28 (only one of them is shown in FIG. 1) are provided in a straight line from one end side 3a to the other end side 3b. Yes. Both ends of the circuit board 25 in the width direction are press-fitted and attached to the pair of board mounting grooves 28 and 28.

  The circuit board 25 is formed so as to increase in width as it goes from the one end side 3a to the other end side 3b of the mounting body 3, and the mounting area of the circuit component 26 is increased as much as possible. The circuit board 25 is provided with a pair of input terminals 29 and 29 (only one is shown in FIG. 1) on one end side 25a, and an output connector 30 on the other end side 25b.

  As shown in FIG. 3, the circuit component 26 forms a lighting circuit 31 that lights the LED element 8 of the light emitter 2. The lighting circuit 31 includes a fuse resistor 27, a rectifier 32 connected to the input terminals 29 and 29, a step-down chopper circuit 33 connected to the rectifier 32 via a capacitor C1, and a control circuit 34 for controlling the step-down chopper circuit 33. It is formed. The step-down chopper circuit 33 and the control circuit 34 are formed by a known circuit configuration. The output of the step-down chopper circuit 33 is connected to output terminals 35 and 35. Outputs from the output terminals 35 and 35 are fed to the light emitter 2 via the connector 30. The fuse resistor 27 is connected between one input terminal 29 and the commercial AC power supply Vs. The input terminals 29 and 29 are connected to the commercial AC power supply Vs via the fuse resistor 27.

  When the AC voltage (AC 100 V) of the commercial AC power supply Vs is applied to the input terminals 29 and 29, the lighting circuit 31 converts the AC voltage into a DC voltage by the rectifier 32, and the step-down chopper circuit 33 and the control circuit 34 have a predetermined DC voltage. Convert to Thereby, a constant current flows from the output terminals 35 and 35 to the LED element 8. That is, as shown in FIG. 1, one connector 36 of the output line 10 is attached to the connector 30, and the other connector 37 of the output line 10 is attached to the connector 9 of the light emitter 2. The heat sink 14 is provided with a notch portion 14a through which the output line 10 is passed.

  In FIG. 2, the fuse resistor 27 includes a long, substantially cylindrical main body 38, a pair of lead wires 39 a and 39 b led out from both sides in the longitudinal direction of the main body 38, and a non-inductive body provided in the main body 38. This is a discrete component having a melted body 40 to be described later. The fuse resistor 27 makes it difficult to propagate harmonics due to the operation of the step-down chopper circuit 33 of the lighting circuit 31 to the commercial AC power supply Vs side, and blows when an overcurrent exceeding the rated current (allowable current) flows continuously. The body 40 generates heat, the main body portion 38 is heated and the inside of the main body portion 38 is melted, and the fusing body 40 is eventually blown to cut off the input current. And in this embodiment, when the melted body 40 is melted, the anti-scattering means is provided so that the high-temperature melt of the main body 38 and the melted body 40 is not scattered. The scattering prevention means will be described in detail in the examples described later.

  The fuse resistor 27 has one lead wire 39 a connected to the top connection portion 23 of the E-shaped base 20 by soldering or welding, and the other lead wire 39 b soldered to one input terminal 29 of the circuit board 25. Connected by. One lead wire 39 a is connected to the top connection portion 23 on the outer surface 23 a side of the top connection portion 23 through the through hole 41 formed in the insulating portion 22 and the through hole 42 formed in the top connection portion 23. Yes.

  The fuse resistor 27 has a main body portion 38 in the E-shaped base 20, floats from the circuit board 25 and is positioned on the circuit board 25, and the longitudinal direction of the main body portion 38 is one end side 3 a of the mounting body 3. To the other end side 3b. For this reason, one lead wire 39a is directly connected to the top connection portion 23 of the E-shaped base 20, the other lead wire 39b is folded back to the one lead wire 39a side, and is further folded back to the circuit board 25 side. It is connected to one input terminal 29 of the substrate 25. A short circuit component 26 a is mounted between the fuse resistor 27 and the circuit board 25. The main body 38 of the fuse resistor 27 may not be located in the E-shaped base 20, and a part thereof may be located outside the circuit board 25.

  The other input terminal (not shown) of the circuit board 25 is connected to the male screw portion 21 of the E-shaped base 20 by a wire 43. Thus, the lighting device 5 inputs the AC voltage of the commercial AC power source Vs applied to the E-shaped base 20 through the fuse resistor 27 and the wire 43. That is, the lighting circuit 31 of the circuit board 25 inputs power including the power consumption of the LED element 8 through the E-shaped base 20.

In FIG. 1, the globe 6 is made of a resin material having translucency. Here, for example, polycarbonate (PC) resin is molded into a substantially spherical shape so that the other end side 6 b is closed and the one end side 6 a is opened and the light emitter 2 is covered. The globe 6 is attached to the envelope 4 with the locking portion 44 on one end side 6 a being locked to the locked portion 45 on the other end side 4 b of the envelope 4.
Next, the operation of the first embodiment of the present invention will be described.

  The light bulb shaped LED lamp 1 is mounted on a light bulb socket of a lighting fixture. When the AC voltage of the commercial AC power source Vs is applied to the E-shaped base 20, the lighting device 5 is operated, and a predetermined constant current (power) is supplied from the lighting device 5 to the plurality of LED elements 8 of the light emitter 2. The The plurality of LED elements 8 are lit and white light is emitted from the light emitter 2. The white light passes through the substantially spherical globe 6 and is emitted to the external space.

  In the bulb-type LED lamp 1, an overcurrent exceeding the rated current or allowable current of the fuse resistor 27 flows to the input terminals 29 and 29 due to an electrical accident such as an abnormal operation of the lighting circuit 31 or a short circuit in the lighting circuit 31. is there. In the fuse resistor 27, when an overcurrent flows, the fusing body 40 generates heat. This heat is conducted to the main body 38. The main body 38 is heated and the inside of the main body 38 is gradually melted. When melting in the main body portion 38 proceeds, the melted body 40 itself is also melted.

  And if fusion of melted body 40 advances by continuation of overcurrent, melted body 40 will melt. Due to the shock at the time of melting, the melted melted body 40 and the main body 38 are ruptured so as to be scattered as a high-temperature melt. However, since the fuse resistor 27 is provided with the scattering prevention means, each of the melted melted body 40 and the main body portion 38 is prevented from scattering. That is, when the fuse resistor 27 is blown, the high-temperature melt of the fuse resistor 27 is not scattered in the attachment body 3, and the resin attachment body 3, the circuit board 25 of the lighting device 5, the circuit component 26, etc. Thermal damage and ignition are prevented.

  As a result of the fusing of the fuse resistor 27, no current flows from the E-shaped base 20 to the lighting device 5, the operation of the lighting device 5 is stopped, and the LED element 8 is turned off. White light is no longer emitted from the light emitter 2.

  According to the lamp 1 of the present embodiment, the fuse resistor 27 is configured to prevent the high temperature melt from being scattered when blown, so that the resin attachment body 3 of the envelope 4, the lighting device 5, and the like. Has the effect of preventing electrical accidents such as thermal damage and fire.

  Next, an embodiment of the fuse resistor 27 will be described in detail. The fuse resistor 27 is a general term for the fuse resistors of the respective embodiments, and different reference numerals are given to the respective embodiments. Moreover, in each Example, the same code | symbol is attached | subjected to the same part and description is abbreviate | omitted.

  FIG. 4 is a schematic front view showing a part of the fuse resistor 46 according to the first embodiment. The fuse resistor 46 includes a resistor main body 47, a protective body 48 and a filling body 49.

  As shown in FIG. 5, the resistor main body 47 is formed with a pair of electrodes 50, 50, a melted body 40, an insulator 51, and a pair of lead wires 39a, 39b. The pair of electrodes 50, 50 is a metal plate such as copper or aluminum, is formed in a disk, and is bonded and fixed to both sides of a columnar fixed body 52. The fixed body 52 is made of an insulating material such as glass or ceramics.

  The melted body 40 is, for example, a metal wire of copper-nickel alloy, is spirally wound around the fixed body 52 and is provided between the pair of electrodes 50, 50, and both ends are respectively welded to the pair of electrodes 50, 50 by welding, for example. It is connected. The fusing body 40 has a predetermined resistance value and generates heat according to the current flowing between the pair of electrodes 50 and 50.

  A pair of lead wires 39a and 39b is connected to the pair of electrodes 50 and 50, for example, by welding. The pair of lead wires 39a and 39b are, for example, thick round electric wires, and are formed of copper, brass, or the like.

  An insulator 51 is provided so as to surround the pair of electrodes 50, 50, the fixed body 52 and the fusing body 40. The insulator 51 is a flame-retardant insulating resin such as a phenol resin or an epoxy resin, for example, and is coated and molded on the pair of electrodes 50 and 50, the fixed body 52, and the melted body 40. The insulator 51 electrically insulates the pair of electrodes 50, 50 and the melted body 40 from the outside, and protects the pair of electrodes 50, 50, the fixed body 52, and the melted body 40 from the outside.

  The resistor body 47 can be a commercially available fuse resistor. That is, a commercially available fuse resistor having a pair of electrodes 50, 50, a melted body 40, an insulator 51, and a pair of lead wires 39a, 39b is included in the resistor body 47 of this embodiment. Since the commercial product differs in material, shape, and the like for each manufacturer, the resistor main body 47 described in FIG. 5 is merely an example.

  In FIG. 4, the resistor main body 47 is housed and protected by a protective body 48 formed in a cylindrical shape. Lead wires 39a and 39b of the resistor main body 47 are drawn out from openings 53a and 53b on both sides 48a and 48b of the protector 48, respectively. The protective body 48 is filled with a filler 49 so as to close the openings 53a and 53b on both sides 48a and 48b of the protective body 48. The filling body 49 is an inorganic material having electrical insulation and heat resistance, such as inorganic cement. In this embodiment, the filling body 49 is filled in the space between the openings 53a and 53b and the pair of electrodes 50 and 50 of the resistor body 47. ing. In the protector 48, the space between the fillers 49 is sealed.

  The protector 48 is formed in a cylindrical shape from porous ceramics. Accordingly, the gap 54 between the protector 48 and the resistor main body 47 is ventilated to the external space by a ceramic (not shown) porous. The protective body 48 and the filling bodies 49, 49 constitute the main body portion 38 of the fuse resistor 46 and constitute scattering prevention means.

  In the fuse resistor 46, when an overcurrent exceeding the rated current (allowable current) continuously flows through the pair of lead wires 39a and 39b, the melted body 40 of the resistor main body 47 generates heat intensely. This heat is conducted to the insulator 51 of the resistor body 47 and gradually melts the insulator 51. Further, heat is conducted to the fixed body 52 to melt the fixed body 52. In particular, when the fixed body 52 is an insulator having a low melting point such as glass, the fixing body 52 melts faster. Further, the melted body 40 itself is gradually melted.

  The heat conducted to the insulator 51 causes the air in the gap 54 between the protector 48 and the resistor main body 47 to thermally expand. This thermally expanded air is discharged to the external space through the ceramic porous (pores). Therefore, the air pressure in the gap 54 does not increase, and the protector 48 does not crack.

  The melted body 40 is finally melted as the melting progresses. Due to this fusing shock, the melt of the fusing body 40, the insulator 51, and the fixed body 52 of the resistor main body 47 scatters as a high-temperature melt. The high-temperature melt hits the protection body 48 and the filling bodies 49 and 49 and remains in the protection body 48. Thus, the fuse resistor 47 prevents the high-temperature melt of the resistor main body 47 from scattering into the external space by the protector 48 and the fillers 49 and 49 when the melted body 40 is melted.

FIG. 6 shows the fuse resistor 55 of the present embodiment. In the fuse resistor 46 shown in FIG. 4, the infrared reflecting film 56 is formed on the outer surface 48 c and the inner surface 48 d of the protector 48. The infrared reflecting film 56 is formed by evaporating, for example, titanium oxide (TiO ₂ ) on the outer surface 48c and the inner surface 48d. The infrared reflection film 56 may reflect visible light in addition to infrared reflection.

  When an overcurrent flows through the pair of lead wires 39a and 39b, the melted body 40 of the resistor main body 47 generates heat, and infrared rays are emitted. Infrared rays are reflected by the infrared reflecting film 56 toward the resistor body 47 side. The resistor main body 47 is further heated by the heat generated by the melted body 40 and the reflected infrared rays. Thereby, the fusing time of the fusing body 40 is shortened. The infrared reflection film 56 suppresses heat radiation to the external space of the fuse resistor 55. Therefore, when an overcurrent flows through the lamp 1, heating of the attachment 3 of the envelope 4, the lighting device 5 and the like can be suppressed.

  The infrared reflecting film 56 only needs to be formed on either the outer surface 48c or the inner surface 48d of the protector 48. Further, the protector 48 is not limited to porous ceramics, and may be ceramics having no porous (pores).

  As shown in FIG. 7, the fuse resistor 57 of this embodiment includes a resistor main body 47, a protective body 58, first beads 59 and 59 as a filling body, a plurality of second beads 60 and a protective tube 61. It is formed.

  The protector 58 is made of ceramics and is formed in a cylindrical shape similar to the protector 48 in FIG. And the resistor main body 47 is accommodated so that a pair of lead wire 39a, 39b may be pulled out from opening 53a, 53b of both sides 58a, 58b. The ceramic of the protective body 58 may be porous or not porous.

  The first beads 59 and 59 are provided on both sides of the resistor main body 47 and are accommodated in both sides 58 a and 58 b of the protector 58. The first beads 59 and 59 are made of ceramics and are formed in a columnar shape having through holes 62 through which the lead wires 39a and 39b pass, respectively. In this embodiment, it is formed in a cylinder located between the openings 53a and 53b of the protector 58 and the pair of electrodes 50 and 50 of the resistor body 47, and closes the openings 53a and 53b of the protector 58.

  A plurality of second beads 60 are provided on the outer sides of both sides 58a and 58b of the protector 58, respectively. The second bead 60 is made of ceramics and is formed in a columnar shape having a through hole 63 through which the lead wires 39a and 39b pass, similarly to the first bead 59.

The protective tube 61 is a glass fiber (glass braided tube) made of, for example, silicon dioxide (SiO ₂ ), is formed in a columnar shape, and houses the resistor main body 47 and a plurality of beads 60. The pair of lead wires 39a, 39b of the resistor main body 47 passes through the through holes 62, 62 of the first beads 59, 59 and the through holes 63 of the plurality of second beads 60, and both sides 61a of the protective tube 61. , 61b.

  In the fuse resistor 57, when the melted body 40 of the resistor body 47 is melted, the high temperature melt of the resistor body 47 is prevented from being scattered by the protector 58 and the first beads 59 and 59. Therefore, the attachment body 3 of the envelope 4 of the lamp 1 and the lighting device 5 are prevented from being damaged or ignited. The protector 58 and the first beads 59 and 59 form a means for preventing the high temperature melt of the resistor body 47 from scattering.

  Then, the heat of the resistor main body 47 heated by the heat generation of the fusing body 40 is conducted to the protective body 58, the first beads 59 and 59, and the plurality of second beads 60, and is heated in the entire protective tube 61. Conducted. Therefore, since the local temperature rise is prevented, the protection tube 61 can suppress melting.

  Further, since the protective tube 61 accommodates the protective body 58 and the plurality of second beads 60 so as to draw out the pair of lead wires 39a and 39b, the fuse resistor 57 includes the protective body 58 and the plurality of second beads 60. The two beads 60 can be focused, and the pair of lead wires 39a and 39b can be bent, whereby the workability at the time of assembling the lamp 1 can be improved.

  As shown in FIG. 8, the fuse resistor 64 of the present embodiment is formed to have a resistor main body 47, a protective body 65, and a filling body 66 shown in FIG. The protector 65 is made of non-porous ceramic and is formed in a cylindrical shape similar to the protector 48 of FIG. And the resistor main body 47 is accommodated so that a pair of lead wire 39a, 39b may be pulled out from opening 53a, 53b of both sides 65a, 65b. Note that the ceramic of the protector 64 may be porous.

The filler 66 is, for example, cotton-like glass fiber or cotton-like ceramic fiber made of silicon dioxide (SiO ₂ ), and is provided in the protective body 65 so as to cover the resistor main body 47. The filling body 66 covers the resistor main body 47 and is provided in the protection body 65, and closes the openings 53a and 53b on both sides 65a and 65b.

  When an overcurrent flows through the pair of lead wires 39a and 39b, the resistor main body 47 itself is heated by the heat generated by the melted body 40. The resistor main body 47 heats the filling body 66 and the protection body 65. However, since the filling body 66 is made of cotton-like glass fiber or ceramic fiber, and the protection body 65 is made of ceramics, the filling body 66 is resistant to heat, and the heating of the resistor body 47 continues in the filling body 66 and the protection body 65. However, it does not melt easily.

  Then, when the melted body 40 of the resistor main body 47 is melted and melted, the melt of the resistor main body 47 is scattered as a high-temperature melt due to the shock of the melting. However, the high temperature melt is prevented from being scattered to the outside by the filler 66 and the protective body 65. Thus, the fuse resistor 64 prevents the high-temperature melt of the resistor body 47 from being scattered into the external space by the filling body 66 and the protective body 65 when the melted body 40 of the resistor body 47 is melted. Yes. The filling body 66 and the protection body 65 serve as means for preventing the high temperature melt of the resistor body 47 from scattering.

  FIG. 9 is a schematic front view showing a partial cross section of the fuse resistor 67 of the present embodiment. The fuse resistor 67 is obtained by providing caps 68 and 68 on both sides 65a and 65b of the protection body 65 in the fuse resistor 64 shown in FIG. The caps 68 and 68 are made of, for example, ceramics and are formed in a cylindrical body having a convex cross section. The caps 68 and 68 are fixed to both ends 65 a and 65 b of the protective body 65 with an inorganic adhesive 69 so as to confine the filler 66. The caps 68 and 68 are provided with insertion holes 70 through which the pair of lead wires 39a and 39b are inserted, respectively, and are formed to have an outer diameter substantially equal to that of the protective body 65.

  Since the caps 68 and 68 are fixed to the protective body 65, when the melt of the resistor main body 47 becomes a high-temperature melt and scatters, the shock of the filler 66 pops out to the external space due to the shock. To prevent. The caps 68 and 68 together with the filling body 66 and the protection body 65 serve as means for preventing the high temperature melt of the resistor main body 47 from scattering.

  FIG. 10 is a schematic front view showing a partial cross section of the fuse resistor 81 of the present embodiment. The fuse resistor 81 is provided with a protection body 83 having a bottom 82 instead of the protection body 65 in the fuse resistor 67 shown in FIG. 9, and the remaining configuration is the same as that of the fuse resistor 67. The protector 83 is made of ceramics, and is formed in the same manner as the protector 65 except that it has a bottom 82 at one end 83a. An insertion hole 84 through which the lead wire 39a is inserted is formed in the bottom portion 82.

  The cap 68 of the bottom portion 82 of the protector 83 and the other end 83b of the protector 83 is such that when the melt of the resistor main body 47 is scattered as a high-temperature melt, the filler 66 jumps out to the external space by the shock, Prevent splashing. The bottom portion 82 and the cap 68 of the protection body 83 together with the filling body 66 and the protection body 83 serve as means for preventing the high temperature melt of the resistor body 47 from scattering.

  FIG. 11 is a schematic front view showing a partial cross section of the fuse resistor 85 of the present embodiment. The fuse resistor 85 has a resistor main body 47, a protective body 86, and a filling body 87 shown in FIG.

The protector 86 is made of a cylindrical glass braided tube. The glass braided tube is made of, for example, double braided glass fibers mainly composed of silicon dioxide (SiO ₂ ) and impregnated with a heat-resistant varnish. Have. The protector 86 houses the resistor main body 47 and draws out the lead wires 39a and 39b from the openings 88a and 88b on both sides 86a and 86b, respectively.

  A filling body 87 is provided in the protection body 86 so as to close the openings 88a and 88b on both sides 86a and 86b of the protection body 86. The filling body 87 is an inorganic material having electrical insulation and heat resistance, for example, a silicone resin. In this embodiment, the filling body 87 is filled in the space between the openings 88a and 88b and the pair of electrodes 50 and 50 of the resistor main body 47. ing. In the protector 86, the space between the fillers 87 and 87 is sealed. Further, a gap 89 is provided between the resistor main body 47 and the protector 86. The protector 86 and the fillers 87 and 87 constitute the main body portion 38 of the fuse resistor 85 and constitute scattering prevention means.

  When an overcurrent exceeding the rated current (allowable current) continuously flows through the pair of lead wires 39a and 39b, the fuse resistor 85 generates intense heat, and the air in the gap 89 between the resistor body 47 and the protector 86 is discharged. Thermally expand. This thermally expanded air is discharged to the external space through a vent hole (not shown) of the glass braided tube. Therefore, the air pressure in the gap 89 does not increase, and the pressing force to the fillers 87 and 87 is suppressed.

  Then, the melted body 40 of the resistor main body 47 is melted, and the melt of the resistor main body 47 is scattered as a high-temperature melt by the shock. The high-temperature melt hits the protector 86 and the fillers 87 and 87 and stays in the protector 86. Thus, when the resistor main body 47 is melted, the fuse resistor 85 prevents the high-temperature melt of the resistor main body 47 from scattering into the external space by the protective body 86 and the filling bodies 87 and 87.

  In the present embodiment, the fillers 87 and 87 may be glass beads or ceramic beads, or may be filled into the protective body 86 using an inorganic adhesive.

As shown in FIG. 12, the fuse resistor 90 of the present embodiment is formed by having the resistor main body 47 and the protective body 86 shown in FIG. The filling body 91 is, for example, cotton-like glass fiber or cotton-like ceramic fiber made of silicon dioxide (SiO ₂ ), and is provided in the protection body 86 so as to cover the resistor main body 47. The filling body 91 covers the resistor body 47 and is provided in the protection body 86, and closes the openings 88a and 88b on both sides 86a and 86b of the protection body 86.

  In the fuse resistor 90, when an overcurrent continues to flow through the pair of lead wires 39a and 39b, the resistor main body 47 generates intense heat and heats the filling body 91 and the protection body 86. However, since the filling body 91 is made of cotton-like glass fiber or ceramic fiber, and the protection body 86 is made of a super flame-retardant glass braided tube, it is resistant to heat, and the filling body 91 and the protection body 86 are made of resistors. Even if heating of the main body 47 continues, it does not melt easily.

  Then, the melt of the melted body 40 of the resistor body 47 causes the melt of the resistor body 47 to become a high-temperature melt and scatter. However, the high-temperature melt is prevented from scattering to the outside by the filler 91 and the protective body 86. Thus, the fuse resistor 90 prevents the high-temperature melt of the resistor body 47 from being scattered into the external space by the filling body 91 and the protection body 86 when the melted body 40 of the resistor body 47 is melted. Yes. The filling body 91 and the protection body 86 serve as means for preventing the high temperature melt of the resistor body 47 from scattering. The filler 91 may be a silicone resin having electrical insulation and heat resistance.

  The fuse resistor 92 of the present embodiment is configured as shown in FIG. The fuse resistor 92 is obtained by applying a cement adhesive 93 as an inorganic adhesive to the outer surface 86c of the protector 86 in the fuse resistor 90 shown in FIG. The cement adhesive 93 is provided on the outer surface 86c of the protection body 86 so as to surround at least the resistor main body 47.

  The cement adhesive 93 prevents the high-temperature melt of the resistor main body 47 from splashing into the external space through a vent hole (not shown) of the glass braided tube that is the protector 86. The cement adhesive 93, together with the filler 91 and the protective body 86, serves as a means for preventing the high temperature melt of the resistor body 47 from scattering.

  As shown in FIG. 14, the fuse resistor 94 of the present embodiment is formed having a resistor main body 47, a heat shrinkable tube 95, and a protective body 96.

  The shape of the heat shrinkable tube 95 that shrinks when heated is a shape that follows the resistor main body 47 in advance, so that the resistor main body 47 including the pair of lead wires 39a and 39b is accommodated. It is heated and formed into a predetermined shape. The pair of lead wires 39 a and 39 b are exposed from the heat-shrinkable tube 95 at portions where the lamp 1 is connected to the E-shaped base 20 and the input terminal 29.

  The protector 96 is made of the glass braided tube described in the fuse resistor 85 of FIG. 11, is formed in a cylindrical shape, and houses the heat shrinkable tube 95. That is, the protector 96 houses the resistor main body 47 including the pair of lead wires 39a and 39b via the heat shrinkable tube 95. The protector 96 is formed so as to be in close contact with the heat-shrinkable tube portion 95a located on the insulator 51 of the resistor main body 47. That is, the protector 96 is provided so as to be pushed outward from the heat-shrinkable tube portion 95a. The heat-shrinkable tube 95 is a filler that closes both ends 96 a and 96 b of the protective body 96.

  In the fuse resistor 94, when an overcurrent flows through the pair of lead wires 39a and 39b, the resistor body 47 itself is heated by the heat generated by the fusing member 40. When the heating of the resistor main body 47 is continued, the heat shrinkable tube 95 is gradually melted by the heat of the resistor main body 47. However, since the protector 96 is made of a glass braided tube having super heat resistance, it does not melt easily.

  When melting of the melted body 40 of the resistor main body 47 proceeds and melts, the melt of the resistor main body 47 and the heat shrinkable tube 95 scatters as a high-temperature melt due to the shock of melting. However, the high-temperature melt is prevented from scattering to the outside by the protector 96. Thus, the fuse resistor 94 prevents the high temperature melts of the resistor main body 47 and the heat shrinkable tube 95 from being scattered into the external space by the protector 96 when the melted body 40 of the resistor main body 47 is melted. It is preventing. The protector 96 is a means for preventing the high temperature melt of the resistor main body 47 and the heat shrinkable tube 95 from being scattered.

  The fuse resistor 94 is formed so that the protector 96 is in close contact with the heat shrinkable tube portion 95a located on the insulator 51 of the resistor body 47. Therefore, the protector 96 is connected to the resistor body 47 and the heat resistor. This has the effect of preventing displacement from the shrinkable tube 95 and dropping off when the lamp 1 is assembled.

  As shown in FIG. 15, the fuse resistor 97 of the present embodiment is formed having a resistor main body 47, a heat shrinkable tube 95, and a protective body 98.

The protector 98 is a glass fiber made of, for example, silicon dioxide (SiO ₂ ), and is formed on a ribbon. The entire heat shrinkable tube 95 is wound so that the heat shrinkable tube 95 is not exposed. Both ends of the protector 98 are fixed to the heat shrinkable tube 95 or the pair of lead wires 39a and 39b, for example, with an inorganic adhesive.

  When an overcurrent flows through the pair of lead wires 39a and 39b, the resistor body 47 itself is heated by the heat generated by the melted body 40 of the resistor body 47. When the heating of the resistor main body 47 is continued, the heat shrinkable tube 95 is gradually melted by the heat of the resistor main body 47. However, since the protector 98 is made of a glass fiber ribbon, it is resistant to heat and does not melt easily.

  When melting of the melted body 40 progresses and melts, the melt of the resistor main body 47 and the heat-shrinkable tube 95 scatters as a high-temperature melt due to the melt shock. However, the high-temperature melt is prevented from scattering to the outside by the protector 98. Thus, the fuse resistor 97 prevents the high temperature melts of the resistor main body 47 and the heat shrinkable tube 95 from being scattered into the external space by the protector 98 when the melted body 40 of the resistor main body 47 is melted. It is preventing. The protector 98 is a means for preventing the high temperature melt of the resistor main body 47 and the heat shrinkable tube 95 from being scattered.

  As shown in FIG. 16, the fuse resistor 99 of the present embodiment is formed by having a resistor main body 47 and a protective body 98 shown in FIG. The protector 98 is wound around a resistor body 47 including a pair of lead wires 39a and 39b so that the resistor body 47 is not exposed. In the pair of lead wires 39 a and 39 b, the connection portion of the lamp 1 to the E-shaped base 20 and the input terminal 29 is exposed from the protective body 98.

  When an overcurrent flows through the pair of lead wires 39a and 39b, the resistor body 47 itself is heated by the heat generated by the melted body 40 of the resistor body 47. When the heating of the resistor main body 47 continues, the resistor main body 47 itself gradually melts. However, since the protector 98 is made of glass fiber, it is resistant to heat and does not melt easily.

  When the melt of the melted body 40 is melted, the melt of the resistor main body 47 scatters as a high-temperature melt due to the melt shock. However, the high-temperature melt is prevented from scattering to the outside by the protector 98. Thus, the fuse resistor 99 prevents the high-temperature melts of the resistor main body 47 from scattering into the external space by the protector 98 when the melted body 40 of the resistor main body 47 is melted. The protector 98 is a means for preventing the high temperature melt of the resistor body 47 from scattering.

  As shown in FIG. 17, the fuse resistor 100 according to the present embodiment includes a resistor main body 47, a protective tube 101, and a protective body 102.

  In the present embodiment, the heat-shrinkable tube 95 of Example 10 and Example 11 is used as the protective tube 101. The protective tube 101 is provided so as to accommodate a resistor main body 47 including a pair of lead wires 39a and 39b. In the pair of lead wires 39 a and 39 b, the connection portion of the lamp 1 to the E-shaped base 20 and the input terminal 29 is exposed from the protective tube 101.

  The protection body 102 is made of laminated glass having heat resistance, and is provided at least on the protection tube portion 101 a located on the insulator 51 of the resistor main body 47. That is, the protection body 102 is formed by laminating a number of glass plates 102a each having a through-hole 103 through which a protection tube portion 101a and a pair of lead wires 39a and 39b are passed. Is attached to the resistor main body 47 through the protective tube 101 so as to surround the resistor without any gap. The glass plate 102a is made of heat-resistant glass such as borosilicate glass, and is fixed to each other with a heat-resistant adhesive.

  When an overcurrent flows through the pair of lead wires 39a and 39b, the resistor body 47 itself is heated by the heat generated by the melted body 40 of the resistor body 47. When the heating of the resistor main body 47 is continued, the protection tube 101 is gradually melted by the heat of the resistor main body 47, and the resistor main body 47 itself is also gradually melted. However, since the protective body 102 is formed by laminating a heat-resistant glass plate 102a, it is resistant to heat and does not melt easily.

  When melting of the melted body 40 proceeds and melts, the melt of the resistor main body 47 and the protection tube 101 scatters as a high-temperature melt due to the shock of melting. However, the high-temperature melt is prevented from scattering to the outside by the protector 102. Thus, the fuse resistor 100 prevents the high temperature melts of the resistor main body 47 and the protective tube 102 from being scattered into the external space by the protective body 102 when the melted body 40 of the resistor main body 47 is blown. doing. The protector 102 is a means for preventing scattering of the resistor main body 47 and the protective tube 101 with respect to the high-temperature melt.

  As shown in the above-described Examples 1 to 13, since the fuse resistor 27 forms the scattering prevention means for preventing the high temperature melt from being scattered when the melted body 40 of the resistor main body 47 is melted. It is possible to prevent thermal damage and ignition of the envelope 4 and the lighting device 5.

  In the present embodiment, the light emitting body 2 uses the packaged LED element 8 as a semiconductor light emitting element, but is not limited thereto, and may be formed using an LED bare chip. An organic electroluminescence (EL) element may be used as the semiconductor light emitting element.

  Further, the envelope 4 is not limited to a substantially circular truncated conical shape that smoothly increases in diameter, and may be a cylindrical shape such as a cylinder or a square tube. The globe 6 does not have to be substantially spherical. The shape of the globe 6 is not limited as long as the other end 6b is closed and the one end 6a is opened. For example, the globe 6 has a bowl shape or a square box shape. There may be. Moreover, the globe 6 may be formed of translucent glass.

  The lamp 1 may not include the globe 6, and may be, for example, a light-emitting body 2 sealed in a lens shape with a translucent resin. Further, the base is not limited to the E-shaped base 20 but may be a plug-in type or a GX53 type. The lamp 1 is not limited to a light bulb shaped LED lamp, but may be a light bulb shaped fluorescent lamp whose light source is a fluorescent lamp.

  Next, a second embodiment of the present invention will be described. The lamp 104 of this embodiment is configured as shown in FIG. The same parts as those in FIG. 1 are denoted by the same reference numerals, and description thereof is omitted.

  The lamp 104 is obtained by replacing a plurality of fuse resistors 27 with three fuse resistors 105 in the present embodiment in the lamp 1 shown in FIG. The plurality of fuse resistors 105 are connected in series and connected to the top connection portion 23 of the E-shaped base 20 and one input terminal 29 of the lighting device 5. The plurality of fuse resistors 105 are the same product, and their combined resistance is set to be the same as that of the fuse resistor 27. The fuse resistor 105 is formed in the same manner as the fuse resistor 27 except that the resistance value of the melted body 40 is different.

  The fusing resistor 27 varies in fusing time of the fusing body 40 due to variations in resistance values. When the resistance value is on the maximum value side of the variation, the fusing time of the fusing body 40 may become considerably long, the heating time in the envelope 4 becomes long, and heat damage or damage in the envelope 4 occurs. There is a high risk of ignition.

  On the other hand, in the plurality of fuse resistors 105, the melted body 40 having the smallest resistance value is usually blown early. Therefore, the plurality of fuse resistors 105 can suppress the influence of variations in their resistance values. In the lamp 104, the fusing time of the fusing body 40 of each fuse resistor 105 is unlikely to become long at the same time, which makes it easy to prevent the heating time in the envelope 4 from becoming long, and thus causes thermal damage and ignition. This has the effect of reducing the risk of reaching.

  Next, a third embodiment of the present invention will be described. The lamp 106 of this embodiment is configured as shown in FIG. The same parts as those in FIG. 1 are denoted by the same reference numerals, and description thereof is omitted.

  The lamp 106 includes the thermal fuse 107 connected in series with the fuse resistor 27 in the lamp 1 shown in FIG. The fuse resistor 27 and the thermal fuse 107 are coupled by a thermally conductive resin 108 having electrical insulation. As the thermally conductive resin 108, for example, a silicone resin can be used.

  When an overcurrent flows from the E-shaped base 20 to the lighting device 5, the fuse resistor 27 generates heat. This heat is quickly transferred to the thermal fuse 107 via the heat conductive resin 108. The temperature fuse 107 immediately rises in temperature and shuts off. As a result, the lamp 106 has an effect of preventing an electrical accident such as thermal damage or ignition in the envelope 4 when an overcurrent flows through the fuse resistor 27.

  Next, a fourth embodiment of the present invention will be described. FIG. 20 is a partially cutaway schematic front view of a lighting fixture showing a fourth embodiment of the present invention, and FIG. 21 is a partially cutout schematic front view of another lighting fixture. The same parts as those in FIG. 1 are denoted by the same reference numerals, and description thereof is omitted.

  A lighting fixture 111 illustrated in FIG. 20 is a downlight that uses the lamp (bulb-shaped LED lamp) 1 illustrated in FIG. 1 and is embedded in the ceiling 112. A light bulb socket 114 as a socket is disposed on a tool body 113 having an outer shape formed in a substantially cylindrical shape with a bottom. The instrument main body 113 is sandwiched between the ceiling 112 and fixed to the ceiling 112 by a cover body 115 and leaf springs 116, 116 provided integrally with the instrument main body 113. The bulb-type LED lamp 1 is attached to the bulb socket 114.

  When the light bulb socket 114 is energized, the lighting device 5 (not shown) of the lamp 1 operates to supply a predetermined constant current to each LED element 8 (not shown) of the light emitter 2 (not shown). Is done. As a result, the plurality of LED elements 8 are turned on, and white light is emitted from the globe 6. The white light emitted from the globe 6 becomes direct light and reflected light reflected by the inner surface 113a of the instrument body 113, and is emitted from the light transmitting portion 117 of the cover body 115 to the floor surface side.

  A lighting fixture 121 shown in FIG. 21 is a hanging type lighting fixture that is suspended from a ceiling 112, and an E of the lamp (bulb-shaped LED lamp) 1 shown in FIG. A light bulb socket 123 is provided as a socket to which the die 20 (not shown) is attached. The instrument body 122 is connected to a power cord 125 having a hooking sealing cap 124 at the tip.

The hook sealing cap 124 is attached to a hook ceiling body 126 disposed on the ceiling 112. As a result, external power is supplied to the light bulb socket 123 via the power cord 125 or the like. The hook sealing cap 124 and the hook sealing body 126 are covered with a sealing cover 127. The lamp 1 is mounted on a light bulb socket 123.
The lamp 1 is turned on in response to an on / off operation of a wall switch (not shown). And the white light radiated | emitted from the globe 6 illuminates the floor surface side.

  According to the lighting fixtures 111 and 121 of the present embodiment, when the input current becomes an overcurrent due to an abnormality of the lighting device 5 or the like, the lamp resistor 1 is melted and the high-temperature melt of the fuse resistor 27 is melted. Therefore, the lamp 1 can be prevented from being thermally damaged, ignited, etc., and the safety and reliability are improved.

  In addition, the lighting fixture of this embodiment is not limited to an embedded type or a hanging type, but may be a direct-attached type lighting fixture. Further, the above-described embodiment of the present invention is presented as an example, and is 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 scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 1,104,106 ... Lamp, 2 ... Light emitter as light source, 4 ... Envelope, 5 ... Lighting device, 20 ... E-shaped base as base, 25 ... Circuit board, 26 ... Circuit component, 27, 46, 55, 57, 64, 67, 81, 85, 90, 92, 94, 97, 99, 100, 105 ... fuse resistors, 39a, 39b ... a pair of lead wires, 40 ... fusing body, 47 ... resistor body, 50, 50 ... a pair of electrodes, 51 ... insulator, 48, 58, 65, 83, 86, 96, 98, 102 ... protector, 49, 66, 87, 91 ... filler, 61, 101 ... protective tube, 95 ... Heat-shrinkable tube, 107 ... Thermal fuse, 108 ... Thermally conductive resin, 111, 121 ... Lighting equipment, 113, 122 ... Equipment body, 114, 123 ... Light bulb socket as a socket

Claims (6)

With a light source;
An envelope provided with a base on one end and the light source on the other end;
A lighting device that has a circuit board disposed in the envelope and a circuit component mounted on the circuit board, and inputs power through the base to turn on the light source;
A pair of electrodes, a fusing body connected to the pair of electrodes and provided between the pair of electrodes, an insulator for electrically insulating and protecting the fusing body, and a pair of lead wires respectively connected to the pair of electrodes A resistor body, a protector for housing the resistor body, and a filler having electrical insulation and heat resistance provided in the protector so as to block both sides of the protector. And a fuse resistor electrically connected to the lighting device;
The lamp characterized by comprising.   The lamp of claim 1, wherein the fuse resistor comprises a plurality of series connected resistors.   3. The lamp according to claim 1, wherein the protective body is made of a cylindrical ceramic.   The lamp according to claim 1 or 2, wherein the protective body is made of a glass braided tube.   3. The lamp according to claim 1, wherein the protective body is made of a glass fiber ribbon. A lamp according to any one of claims 1 to 5;
An instrument body having a socket to which the base of the lamp is connected;
The lighting fixture characterized by comprising.

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