JP2007157368A - Fluorescent lamp apparatus and luminaire - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a thin and small fluorescent lamp apparatus with a lighting device, in which influence of heat generated in electric components to a ceiling surface is suppressed, and an operation space for an explosion proof valve of an electrolytic capacitor is secured. <P>SOLUTION: A fluorescent lamp apparatus 11 is detachably attached in a socket apparatus 10 installed on a ceiling surface 2. The fluorescent lamp apparatus 11 has: a main body 21; a circular lighting device housing part 20 in the main body 21; and a lighting device 22 housed in the circular lighting device housing part 20. A GX53 type base 23 is provided in the main body 21 in one body. The fluorescent lamp 24 is attached on the lower surface side of the main body 21. A globe 25 covers the lower surface side of the main body 21 together with the fluorescent lamp 24. The lighting device 22 has a rectangular circuit board 77 and an electric components 79 of discrete components attached on the lower surface of the circuit board 77 facing the fluorescent lamp 24. An explosion proof valve 81a of an electrolytic capacitor 81 is arranged along an edge of the circuit board 77. A field effect transistor 80 as a surface mounting component 78 is aligned with the opposite surface of the electrolytic capacitor 81 and arranged on the upper surface of the circuit board 77. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a fluorescent lamp device and a lighting fixture including a fluorescent lamp and a lighting device.

2. Description of the Related Art Conventionally, a fluorescent lamp device that is integrally provided with a fluorescent lamp having an arc tube having a bent bulb and a lighting device that lights the arc tube has been used (see, for example, Patent Document 1). For such a fluorescent lamp device, in order to obtain a planar light source, the lighting device is accommodated in a flat disk-shaped main body, and a base portion is provided integrally on the upper surface of the main body, and the flat surface along the lower surface of the main body There has been known a flat disk-shaped fluorescent lamp device in which arc tubes bent in a shape are arranged and the lower surface of the main body and the arc tube are covered with a globe (see, for example, Non-Patent Document 1).
JP-A-6-283139 Sylvania 0025219 Microlinks F 7W / 840 (SYLVANIA 0025219 Micro-Lynx F 7W / 840), [online], 2005, Sylvania Lighting International, [November 10, 2005 search], Internet <http : //www.sylvania-lamps.com/catalog/pdflib/lamps2pdf.php? id = 2514>

However, in the configuration in which the arc tube and the lighting device are arranged so as to overlap each other, the temperature of each part is likely to rise due to heat generated by the arc tube and the lighting device arranged close to each other. Furthermore, for electrical components that are discrete components other than surface-mounted components mounted on a circuit board,
There are many varieties that easily rise in temperature compared to surface mount type electrical components. For example, PTC elements may rarely generate abnormal heat. When an electrical component such as a PTC element abnormally generates heat, the temperature of the portion facing the installation portion of the main body adjacent to the electrical component rises, causing discoloration or deterioration of the mounting surface. In addition, the lighting device accommodating portion that accommodates the lighting device is a flat disk-shaped space with a small height in relation to the base portion, but the electrolytic capacitor accommodated in the lighting device accommodating portion is at the tip portion. There is a problem that it is difficult to secure a space in which the provided lid portion opens in the event of a failure. On the other hand, when the volume of the lighting device accommodating portion is increased, there is a problem that the fluorescent lamp device is increased in size.

  The present invention has been made in view of these points, and an object of the present invention is to provide a fluorescent lamp device and a lighting fixture that can realize a small and thin planar light source using a fluorescent lamp.

  The fluorescent lamp device according to claim 1 is a flat having a base portion that can be attached to a socket portion provided in the installation portion, a lighting device housing portion that faces the installation portion, and a lamp mounting surface that faces the opposite side of the installation portion. A main body; a circuit board, a surface-mounted component mounted on the circuit board, and an electrical component that is a discrete component other than the surface-mounted component, and a surface on which the electrical component that is the discrete component is mounted is directed to the opposite side of the installation portion A lighting device housed in the lighting device housing portion; a translucent globe covering the lamp mounting surface side of the main body; and a fluorescent lamp having a bulb arranged in a plane along the lamp mounting surface. To do.

  An electrical component, which is a discrete component, is an element in which multiple lead wires are derived in the same direction from electrical component elements such as resistors, inductors, capacitors, etc., and these lead wires are inserted into through holes formed on the circuit board surface. To be implemented.

  In this configuration, a small and thin planar light source is realized by disposing the bulb of the fluorescent lamp along the lamp mounting surface of the main body having the base and housing the lighting device. Since the surface on which the electrical component which is a discrete component is mounted is accommodated in the lighting device accommodating portion so as to face the opposite side of the installation portion, the thermal influence on the installation portion is suppressed when the electrical component abnormally generates heat.

  The fluorescent lamp device according to claim 2 is a base part mounted on a socket part provided in the installation part, a lighting device housing part having a substantially cylindrical side wall part, and a lamp mounting surface facing the opposite side of the installation part A flat body having a rectangular circuit board, and an electrical component having a lid portion mounted on the circuit board and deployable, the electrical component being disposed along the edge of the circuit board, A lighting device housed in the lighting device housing portion; a translucent globe covering the lamp mounting surface side of the main body; and a fluorescent lamp having a bulb arranged in a plane along the lamp mounting surface. Is.

  The electrical component having the lid is, for example, an electrolytic capacitor having an explosion-proof valve at the tip.

  In this configuration, a small and thin planar light source is realized by disposing the bulb of the fluorescent lamp along the lamp mounting surface of the main body having the base and housing the lighting device. By accommodating a square circuit board different from the shape of the lighting device housing portion in the lighting device housing portion having a substantially cylindrical side wall portion, between the edge of the circuit board and the inner surface portion of the lighting device housing portion. Space is secured. Therefore, by arranging the lid portion along the edge of the circuit board, the electrical component secures a space where the lid portion is developed.

  A lighting fixture according to a third aspect includes the fluorescent lamp device according to the first or second aspect; and a socket device that includes a socket portion that is electrically connected to the base portion and mechanically holds the main body. It is.

  In this configuration, since the fluorescent lamp device according to claim 1 or 2 is provided, a small and thin planar light source is realized, and each effect of claim 1 or 2 is obtained. In addition, the fluorescent lamp device incorporating the lighting device is attached to and detached from the socket device, and the handling becomes easy.

  According to the fluorescent lamp device of the first aspect, a small and thin planar light source can be realized by disposing the bulb of the fluorescent lamp along the lamp mounting surface of the main body having the base and housing the lighting device. Since the surface on which the electrical component, which is a discrete component, is mounted is stored in the lighting device storage portion with the surface opposite to the installation portion, the thermal influence on the installation portion can be suppressed when the electrical component abnormally generates heat.

  According to the fluorescent lamp device of the second aspect, a small and thin planar light source can be realized by disposing the bulb of the fluorescent lamp along the lamp mounting surface of the main body provided with the base and housing the lighting device. By accommodating a square circuit board different from the shape of the lighting device housing portion in the lighting device housing portion having a substantially cylindrical side wall portion, between the edge of the circuit board and the inner surface portion of the lighting device housing portion. Space is secured. Therefore, the electrical component can secure a space in which the lid is developed by arranging the lid along the edge of the circuit board.

  According to the lighting apparatus of claim 3, since the fluorescent lamp device of claim 1 or 2 is provided, a small and thin planar light source can be realized, and the respective effects of claim 1 or 2 are realized. it can. In addition, the fluorescent lamp device incorporating the lighting device is attached to and detached from the socket device, so that it can be easily handled.

  Hereinafter, an embodiment of a fluorescent lamp device and a lighting fixture of the present invention will be described with reference to the drawings.

  FIG. 1 is an explanatory view showing an embodiment of a lighting fixture provided with the fluorescent lamp device of the present invention, wherein (a) is a longitudinal sectional view and (b) is a transverse sectional view. FIG. 2 is a perspective view showing a state in which the fluorescent lamp device of the lighting fixture is removed from the socket device. FIG. 3 is an exploded perspective view of the fluorescent lamp device. FIG. 4 is a side view of the fluorescent lamp device. FIG. 5 is a perspective view of the partition plate of the same fluorescent lamp device as viewed from the lower surface side. FIG. 6 is a cross-sectional view of the fluorescent lamp device.

  1 and 2, reference numeral 1 denotes a lighting fixture. The lighting fixture 1 is installed directly on a ceiling surface 2 as an installation portion, for example, and has a flat cylindrical shape directly attached to the ceiling surface 2. A socket device 10 and a flat disk-shaped fluorescent lamp device 11 that is detachably attached to the socket device 10 are provided. Hereinafter, the direction such as the vertical direction will be described with reference to the state in which the lighting fixture 1 is attached to the horizontal ceiling surface 2, and the base side will be described as the upper side and the non-base side as the lower side.

  The socket device 10 includes a cylindrical case body 14, and the case body 14 is fixed to the ceiling surface 2 with screws or the like. Further, the case body 14 accommodates a pair of connection fittings (not shown) constituting the socket portion, and the core wires of the commercial AC power supply F cable wired to the ceiling portion are electrically connected to the connection fittings, respectively. Yes. Further, the lower surface of the case body 14 is formed with a power feeding hole 15 constituting a socket portion along each connection fitting. Each power supply hole 15 is positioned rotationally symmetrically with respect to the center of the case body 14, and a circular hole-shaped enlarged diameter portion 15a is provided at one end of the circular hole-shaped groove portion. Furthermore, a circular hole-shaped main body accommodating portion 16 penetrating vertically is formed in the central portion of the case body 14, and a pair of engagement holding portions 17 project from the center of the main body accommodating portion 16. .

  The fluorescent lamp device 11 is a so-called compact fluorescent lamp with a built-in ballast. As shown in FIGS. 1 to 4, a main body 21 that constitutes a lighting device accommodating portion 20 is housed in the main body 21. A lighting device 22, a base portion 23 of the GX53 format provided integrally with the main body 21, a fluorescent lamp 24 attached to the lower surface side of the main body 21, and a glove that covers the lower surface side of the main body 21 together with the fluorescent lamp 24 And 25.

  The main body 21 has a substantially circular plane, and includes a holder 31 that is combined with each other, a partition plate 32 that constitutes heat insulating means, a base body 33, and a pair of base pins 34.

  The holder 31 has a substantially disc shape formed of aluminum, which is a metal having good heat conductivity, and can also be called an aluminum cover. The holder 31 has a disc-like shape, and an outer periphery of the cover substrate 36. A cover edge portion 37 continuous with the portion is integrally formed. A pair of through holes 38 on both sides is formed in the cover substrate portion 36, and the lower surface is a flat lamp mounting surface 39. Further, the cover edge portion 37 has a substantially V-shaped cross section with the lower surface opened, and the outer peripheral surface is inclined so that the radial dimension decreases toward the upper side. Further, the lower opening of the cover edge portion 37 is an attachment receiving portion 41 to which the globe 25 is attached by adhesion or the like. Furthermore, the inner peripheral side on the upper side of the cover edge portion 37 is formed in a ring shape so as to protrude inward, and serves as a cap body holding portion 42 that engages and holds the cap body 33. Further, in the present embodiment, positioning portions 43 are formed on the main body 21 so as to protrude in a rectangular shape at two corners of the upper surface of the cover substrate portion 36 and the inner peripheral surface of the cover edge portion 37. ing.

  Further, as shown in FIGS. 3 and 5, etc., the partition plate 32 has a substantially disc shape formed of an insulating resin and can also be referred to as a resin insulation partition plate. Part 45, a cap pin mounting portion 47 provided on both sides of the upper surface of the partition plate substrate portion 45, and a partition plate edge portion 48 provided on the outer peripheral portion of the partition plate substrate portion 45 are integrally formed. . In addition, the partition plate substrate portion 45 is disposed in close contact with the upper surface of the cover substrate portion 36 of the holder 31 or is opposed to the cover substrate portion 36 with a predetermined interval. In the present embodiment, the partition plate substrate portion 45 is in close contact with the upper surface of the cover substrate portion 36. Can be stacked. The partition plate substrate portion 45 is formed with two through holes 50 in alignment with the through holes 38 of the holder 31. Further, the lower surface side portion 51 of the through hole 50 protrudes downward and is positioned by being fitted into the through hole 38 of the holder 31. Further, a positioning receiving portion 53 that is aligned with the positioning portion 43 and is positioned by being fitted to the positioning portion 43 is recessed in the lower surface portion of the partition plate substrate portion 45. Each base pin mounting portion 47 includes a base 58 projecting upward in a semicircular shape, and a pin insertion portion into which the base pin 34 is press-fitted to the base 58. 59 and.

  As shown in FIG. 1 and FIG. 3, the base body 33 is a substantially disk-shaped base body substrate portion 61 formed of an insulating resin, and this base body substrate portion. A side wall portion 62 which is an inner cylindrical portion projecting upward from the inner edge portion of 61 is integrally formed with a top plate portion 63 which closes the upper end portion of the side wall portion 62. . A cylindrical engagement receiving portion 65 that is engaged with the base body holding portion 42 of the holder 31 is formed from the vicinity of the outer peripheral portion of the lower surface of the base body substrate portion 61. Further, on both side portions of the base substrate portion 61, a base pin mounting portion 66 to which the base pin 34 is mounted is formed. Each of the base pin mounting portions 66 has a circular hole shape penetrating vertically, but has a stepped portion 67 and has a lower side diameter than the upper side portion, and the base pin 34 inserted from the lower side. Is held without slipping upward. Further, the outer diameter of the side wall portion 62 is formed so as to be insertable into the main body accommodating portion 16 of the socket device 10. Further, an engagement holding receiving portion 68 that is detachably engaged with and held by the engagement holding portion 17 of the socket device 10 is formed in the outer peripheral surface of the side wall portion 62 so as to be recessed in a substantially L shape. ing. Although not shown, a lighting device mounting portion that positions the lighting device or engages and holds the lighting device can also be provided on the inner surface, that is, the lower surface of the top plate portion 63.

  The base pin 34 is made of a conductive metal and has a cylindrical shaft portion 71, a press-fit portion 72 projecting downward from the lower end portion of the shaft portion 71, and a position above the press-fit portion 72. Thus, a flange portion 73 projecting from the outer peripheral portion of the shaft portion 71 and a plug portion 74 projecting in a T-shaped cross section from the upper end portion of the shaft portion 71 are integrally formed. The shaft portion 71 is inserted into the base pin mounting portion 66 of the base body 33, the flange portion 73 is engaged with the stepped portion 67, and the press-fit portion 72 is press-fit into the pin insertion portion 59 of the partition plate 32. Further, the plug portion 74 protrudes above the base substrate portion 61 of the base body 33, is inserted from the enlarged diameter portion 15a into the power feeding hole 15 of the socket device 10, and is electrically and mechanically held by the connection fitting. It has become.

  The lighting device 22 includes a circuit board 77, a surface mounting component 78 mounted on the upper surface component arrangement surface 77b which is one surface of the circuit board 77, and a lower component arrangement surface which is the other surface of the circuit board 77. And an electrical component 79 which is a discrete component other than the surface mount component 78 mounted on 77a. The circuit board 77 is a multi-layered substantially quadrangular plate shape, and is formed with cutout portions 77c that are obliquely cut at the four corner portions, and projecting piece portions 77d from the middle portion of each side toward the outer peripheral side. Is protruding. The surface mount component is, for example, a metal oxide semiconductor field effect transistor (MOSFET) 80 constituting a main switch of the inverter circuit, or a chip resistor or chip capacitor (not shown). The electrical component 79, which is a discrete component, includes a height component such as an electrolytic capacitor 81 and an inductor 82, which is a ballast choke, or a positive temperature coefficient thermistor 83, also called a PTC varistor, other inductors L1, L3, a capacitor C1, Negative characteristic thermistors NTC1 and NTC2, constant voltage diodes ZD1 and ZD2, etc., which are electrically and mechanically attached to the circuit board 77 by soldering a plurality of wire terminals.

  The electrolytic capacitor 81 has a cylindrical shape, and includes an explosion-proof valve 81a as a lid that can be opened at the tip at the time of abnormality. Further, a display 81b indicating polarity is provided on the side surface. The electrolytic capacitor 81 is bent in a terminal so that the axial direction, which is the longitudinal direction, is along the surface direction of the circuit board 77, so to speak, is arranged horizontally, and the explosion-proof valve 81a is formed on one side of the circuit board 77 that forms a straight line. In the present embodiment, the edge portion is arranged so as to be along the edge portion of the protruding piece portion 77d and to be positioned at the center portion in the longitudinal direction of the edge portion.

  On the other hand, a field effect transistor (FET) 80 is a so-called SOP 8 having a total of eight terminals on both sides of a rectangular plate-shaped package in which one Nch and Pch FET is packaged. In order to reduce the influence and improve the reliability, as shown in FIG. 1 (b), it is arranged in alignment with the opposite surface of the electrolytic capacitor 81 which is a component that hardly generates heat.

  Furthermore, on one side of the component placement surface 77a of the circuit board 77, four connection pins 84 that are output units connected to the fluorescent lamp 24 and the like are provided. On the other hand, on the other side of the component placement surface 77a of the circuit board 77, two input portions 85 to which commercial AC power is input are provided. In this way, the wiring connection work is facilitated by distributing the output unit and the input unit 85 to the left and right.

  In order to electrically connect the input portion 85 of the lighting device 22 and the base pin 34, two wirings 86 are provided. One end of each wiring 86 has a core wire exposed, and is electrically connected to the input portion 85 of the lighting device 22 by soldering or the like. In addition, an annular terminal portion is provided at the other end of the wiring 86 and is pressed and electrically connected to the cap pin 34 of the cap portion 23.

  Note that the cutout portions 77c at the four corners of the circuit board 77 may be so-called corner processing (C processing) cut out in a straight line or so-called round processing (R processing) cut out in a curved shape. Further, the distance between the notches 77c that face each other on the diagonal line, that is, the outer diameter of the circuit board 77 is set to be slightly smaller than the inner diameter of the side wall 62 of the base 33. The interval between the notch 77c and the side wall 62 is 1 mm or more, preferably 3 mm or more.

  The fluorescent lamp 24 includes an arc tube 88. The arc tube 88 is provided with, for example, a three-wavelength phosphor on the inner surface, and argon (Ar), neon (Ne), krypton (Kr), or the like inside. One or a plurality of discharge paths are formed in which a sealing gas containing noble gas or mercury is sealed. In this embodiment, the arc tube 88 is formed by connecting three U-shaped bent bulbs 91, 92, and 93 sequentially with a communication tube 94 to form one continuous discharge path. . Each valve 91, 92, 93 includes a bent portion in which a substantially cylindrical tube body made of glass is bent at an intermediate portion, and a pair of straight pipe portions that are continuous with the bent portion and are parallel to each other. Yes. The valves 91, 92, and 93 are arranged so that the straight pipe portions are parallel to each other and located on the same plane, and the length of the straight pipe portion of the central valve 92 is the largest. The lengths of the straight tube portions outside the bulbs 91 and 93 on both sides are formed to be the smallest, and as a whole, are formed so as to constitute a so-called flat disk-shaped light source. In addition, a pair of electrodes 96 are sealed by stem seals or pinch seals at one end portions of the bulbs 91 and 93 located on both ends of the discharge path. That is, the central bulb 92 does not have the electrode 96. Each electrode 96 has a filament coil, and this filament coil is supported by a pair of linear wells. Each well is, for example, led to the outside from the bulbs 91 and 93 on both sides via a jumet wire sealed at each end of the bulbs 91 and 93 on both sides, and connected to a wire 97 connected to the lighting device 22. Yes. Further, for example, exhaust pipes (not shown) sealed by stem seals or pinch seals are formed at one end portions of the valves 91 and 93 on both sides. Each exhaust pipe exhausts the arc tube 88 in the manufacturing process of the arc tube 88 and is sealed by fusing.

  Furthermore, an amalgam-specific thin tube 98 is provided at one end of the central bulb 92 that does not have the electrode 96 as an extended portion that is a glass tube that is longer than the exhaust pipe and extends in a straight line, for example, 5 mm to 20 mm. Yes. An amalgam 99 is enclosed at the tip of the amalgam-specific thin tube 98. The amalgam 99 is also called a main amalgam and is an alloy composed of bismuth, tin, and mercury, and is formed in a substantially spherical shape, and controls the mercury vapor pressure in the arc tube 88 within an appropriate range. The amalgam 99 is mercury or a mercury alloy, and can be formed of an alloy that combines indium, lead, etc. in addition to bismuth and tin. Further, an auxiliary amalgam having a mercury adsorption / release action is attached and sealed in the wells of the electrode 96 at one end of the valves 91 and 93 on both sides. Further, auxiliary amalgam is also sealed at the end of the central valve 92 on the side where the main amalgam is not provided.

  The bulbs 91, 92, and 93 are attached along the lamp attachment surface 39 by lamp adhesion means 100 that is an adhesive such as silicone.

  Further, the globe 25 has a light projecting property, that is, is formed in a flat curved surface shape having an opening 101 on the upper side thereof by glass or synthetic resin having transparency or light diffusibility. The edge surrounding the opening 101 becomes an attachment portion 102 facing upward, and the opening 101, that is, the front portion 104 facing below the attachment portion 102 is formed in a smooth curved surface. Further, the outer peripheral portion connecting the mounting portion 102 and the front portion 104 is a bulging portion 105 that bulges to the outer peripheral side of the opening 101, and the outer surface 106 of the bulging portion 105 is from below. It is an inclined surface that has a diameter that decreases upward.

  Then, in the assembling work of the fluorescent lamp device 11, first, the partition plate 32 is put on the upper side of the cover substrate portion 36 of the holder 31, and bonded as necessary. At this time, the partition plate 32 is positioned in the cover edge 37, the fitting between the positioning portion 43 and the positioning receiving portion 53, and the lower surface side portion 51 of the through hole 50 and the through hole 38 of the holder 31. By the fitting, the holder 31 and the partition plate 32 are positioned in the rotation direction.

  Then, the fluorescent lamp 24 is arranged along the lamp mounting surface 39 on the lower surface of the cover substrate portion 36 of the holder 31, and the lamps 91, 92, 93 of the arc tube 88 of the fluorescent lamp 24 are mounted on the lamp by the lamp bonding means 100. Glue to surface 39. Then, the two-to-four wires 97 of the fluorescent lamp 24 are led out to the upper side of the holder 31 and the partition plate 32 through the through holes 50 and connected to the connection pins 84 of the lighting device 22 by wrapping or the like. .

  In addition, with the terminal portion of the other end of each wiring connected to the input portion 85 of the lighting device 22 on the base portion 58 of the partition plate 32, the base pin 34 is attached to each pin insertion portion 59 from above. The base pin 34 is mechanically attached to the partition plate 32, and the base pin 34 and the input unit 85, that is, the lighting device 22 are electrically connected.

  Then, the lighting device 22 in which the electric component 79 is mounted on the circuit board 77 is inserted into the side wall portion 62 of the base 33, and adhesive such as silicone applied in a spot shape (potting) to the top plate portion 63 in advance. The circuit board 77 is pressed against the agent and adhered and fixed so as to be parallel to the top plate portion 63, that is, the lamp mounting surface 39 of the holder 31, that is, the virtual surface formed by the fluorescent lamp 24. At this time, as shown in FIG. 1 (b), the distance between the notches 77c facing each other on the diagonal of the circuit board 77 is substantially equal to the inner diameter of the side wall 62. Thus, the circuit board 77 is positioned, and a space A is formed between each edge of the circuit board 77 and the inner surface of the side wall 62, and is arranged along the edge of the circuit board 77. The explosion-proof valve 81a of the electrolytic capacitor 81 is disposed at a distance of 1 mm or more, preferably 3 mm or more, between the inner surface of the side wall portion 62. Further, since there is a space A between each edge of the circuit board 77 and the inner surface of the side wall 62, even when the amount of the adhesive is large, the adhesive is not allowed to pass through the space A. By flowing out to the base side, the entire circuit board 77 can be firmly fixed at a desired position.

  Then, the base body 33 is covered from the upper side of the holder 31, and the engagement receiving portion 65 is press-fitted into the base body holding portion 42 of the holder 31 and engaged. In this state, the plug portion 74 of each cap pin 34 protrudes above the base substrate portion 61 of the base body 33, and the flange portion 73 is engaged with the step portion 67 and is prevented from coming off. In this state, the lighting device accommodating portion 20 is configured inside the main body 21, and the lighting device 22 is accommodated in the lighting device accommodating portion 20.

  Further, the fluorescent lamp device 11 is configured by covering the globe 25 from the lower side of the holder 31 and inserting the attachment portion 102 into the attachment receiving portion 41 and bonding them with an adhesive such as silicone. In this state, the tip of the amalgam-specific thin tube 98 extending from the bulb 92 of the arc tube 88 of the fluorescent lamp 24 is protruded to the outer peripheral side of the opening 101 of the globe 25 and is positioned in the bulging portion 105. The distal end portion of the amalgam-specific thin tube 98 is disposed close to the inner surface of the outer surface 106 of the outer peripheral portion of the globe 25, for example, at a position separated by about 2 mm.

  The fluorescent lamp device 11 configured as described above aligns the side wall portion 62 of the base body 33, that is, the top plate portion 63, with the main body accommodating portion 16 of the socket device 10 attached to the ceiling surface 2 from the lower side. Further, the plug part 74 of the base pin 34 of the base part 23 is inserted into the enlarged diameter part 15a of each power supply hole 15, and the fluorescent lamp device 11 is rotated in a predetermined direction. Then, the plug portion 74 of each cap pin 34 is electrically and mechanically connected to the connection fitting of the socket device 10, and the engagement holding portion 68 of the base body 33 is connected to the engagement holding portion 17 of the socket device 10. And is mechanically held. The fluorescent lamp device 11 mounted on the socket device 10 in this way is mechanically held by the socket device 10 and supplied with commercial AC power from the socket device 10, and the built-in lighting device 22 The arc tube 88 is lit at a high frequency.

  Further, the fluorescent lamp device 11 is easily detached from the socket device 10 by rotating the fluorescent lamp device 11 in the direction opposite to the operation at the time of attachment.

  Then, according to the fluorescent lamp device 11 of the present embodiment, the fluorescent lamp 24 is provided along the lamp mounting surface 39 of the main body 21 in which the base portion 23 is integrally provided and the lighting device 22 is accommodated, that is, overlapped with the lighting device 22. Since the bulbs 91, 92 and 93 of the arc tube 88 are arranged in parallel, a small and thin planar light source can be realized.

  In addition, the lighting device 22 includes an electric component 79 that is a discrete component, particularly a fluorescent lamp 24 side that is opposite to the ceiling surface 2 that is an installation portion of a positive temperature coefficient thermistor 83 that is an electric component 79 that may generate abnormal heat. Since this is accommodated in the lighting device accommodating portion 20, when the electrical component 79 abnormally generates heat due to a failure, the thermal influence on the ceiling surface 2 can be suppressed. The electrical component 79 is disposed toward the fluorescent lamp 24. The electrical component 79 is insulated by the partition plate 32, which is an insulating resin internal cover, and the fluorescent light in the lighting device housing portion 20 is also insulated. Heat is dissipated by the metal holder 31 having good heat conductivity covering the lamp 24 side, and the temperature rise of the electric component 79 can be suppressed. In addition, since the holder 31 also serves as a heat dissipation structure for the fluorescent lamp 24, the structure can be simplified.

  Further, by accommodating a square circuit board 77 that is different from the shape of the lighting device housing portion 20 in the lighting device housing portion 20 having the substantially cylindrical side wall portion 62, each side of the outside of the circuit board 77 is accommodated. A space A is secured between the edge and the inner surface of the lighting device housing 20. Thus, the electrolytic capacitor 81 is placed sideways, and the explosion-proof valve 81a of the electrolytic capacitor 81 is disposed in parallel along the linear edge of one side of the circuit board 77, so that the explosion-proof valve 81a is deployed (opened). For example, a 1 mm space can be easily secured. Moreover, this space part A becomes a space from which the adhesive protruding during manufacture escapes, and can be manufactured easily. Furthermore, since the circuit board 77 has a square shape, the circuit board can be efficiently manufactured from a worksheet that is a square base material, and the manufacturing cost can be reduced.

  Further, the field effect transistor 80 of the inverter circuit is disposed away from the heat generating component, particularly the inductor 82 which is a ballast choke, and is aligned with the opposite surface of the electrolytic capacitor 81 which is a component which does not easily generate heat, so that the surface component arrangement surface 77b. Therefore, the thermal influence by the electrical component 79 can be reduced and the reliability can be improved.

  In addition, the circuit board 77 is arranged with the four connection pins 84 as the output section and the input section 85 to which the wiring is connected distributed to the left and right of the component placement surface 77a, so that the wrapping work and the wiring work interfere with each other. Workability can be improved.

  Further, the arc tube 88 of the fluorescent lamp 24 is disposed in a narrow space between the main body 21 and the globe 25, and further disposed along the lamp mounting surface 39 in the vicinity of the lighting device 22, so that the temperature is high. Although it tends to rise, since the amalgam-specific thin tube 98 is extended from the bulb 92 of the arc tube 88 to the vicinity of the inner surface of the globe 25, the amalgam-specific thin tube 98 is cooled in the vicinity of the globe 25 to a desired temperature. The coldest part is formed, that is, the temperature of the coldest part is lowered, and the luminous efficiency can be easily improved.

  Further, since the amalgam-specific thin tube 98 in which the amalgam 99 is enclosed is used as the extended portion, the coldest portion can be formed without complicating the configuration of the fluorescent lamp 24. In addition, the use of the amalgam-specific narrow tube 98 facilitates formation with high accuracy as compared with the configuration using the exhaust tube formed for the manufacture of the fluorescent lamp 24, and the amalgam-specific thin tube 98 as the extending portion. And the glove 25 can be set with high accuracy, and the coldest part at a desired temperature can be formed.

  In addition, since at least a part of the amalgam tubule 98, in this embodiment, the tip is positioned at the bulging portion 105 that bulges more outward than the opening 101 of the globe 25, a decrease in temperature due to outside air is expected. Due to the bulging portion 105, the amalgam-specific thin tube 98 as the extending portion is efficiently cooled, and the coldest portion having a desired temperature can be formed.

  Further, the separation dimension, that is, the minimum distance between the amalgam-specific thin tube 98 as the extending portion and the inner surface of the globe 25 is preferably 1 mm or more and 5 mm or less, and more preferably 1.5 mm or more and 3 mm or less. In other words, by setting the minimum distance between the amalgam-specific thin tube 98 and the globe 25 to 1 mm or more, more preferably 1.5 mm or more, even when the fluorescent lamp device 11 is dropped or the like and an impact is applied to the globe 25. The globe 25 is less likely to come into contact with the amalgam tubule 98, and the amalgam tubule 98 can be protected. In addition, by setting the minimum distance between the amalgam-specific thin tube 98 and the globe 25 to 5 mm or less, more preferably 3 mm or less, the amalgam-specific thin tube 98 is efficiently cooled, and the coldest part can be easily set to a desired temperature.

  In addition, the holder 31 in which at least the arc tube 88 of the fluorescent lamp 24 is disposed in proximity is formed of aluminum which is a material having good heat conductivity, and further, a cover for adhering and holding the arc tube 88 of the fluorescent lamp 24. Since the cover edge portion 37 formed integrally with the substrate portion 36 is exposed to a space outside the main body 21, the heat of the fluorescent lamp 24 is released to the external space through the holder 31, and the entire fluorescent lamp 24 is The temperature can be lowered and the temperature of the entire fluorescent lamp device 11 can be lowered.

  Further, since the arc tube 88 of the fluorescent lamp 24 and the holder 31 are bonded by the lamp bonding means 100 made of silicone, the heat of the fluorescent lamp 24 can be efficiently transmitted to the holder 31.

  In addition, the temperature of the arc tube 88 of the fluorescent lamp 24 is lowered, the heat of the fluorescent lamp 24 is efficiently released to the outside of the main body, and further, heat conduction is performed between the arc tube 88 of the fluorescent lamp 24 and the lighting device 22. Since the partition plate 32 having low properties is disposed, and the lighting device 22 is held in a separated state on the upper surface of the partition plate substrate portion 45 of the partition plate 32, the heat of the fluorescent lamp 24 affects the lighting device 22. This can be suppressed. Therefore, it is not necessary to increase the distance between the fluorescent lamp 24 and the lighting device 22, and it is not necessary to increase the volume of the lighting device housing portion 20, and the temperature of the lighting device 22 can be easily reduced. The upper limit temperature can be easily satisfied and the reliability can be improved.

  Furthermore, while reducing the temperature of the arc tube 88 of the fluorescent lamp 24 and efficiently releasing the heat of the fluorescent lamp 24 to the outside of the main body, the temperature of the base body 33 of the main body 21 can be easily reduced, for example, The top plate portion 63 at the upper end of the base body 33 facing the ceiling surface 2 with an interval of 2 mm to 3 mm is set to 76 ° C. or lower, the ceiling surface 2 is set to 70 ° C. or lower, and the influence of discoloration on the mounting surface such as the ceiling surface 2 Can be easily suppressed.

  Further, since the holder 31 and the base body 33 are connected in line contact with each other by the engagement of the base body holding part 42, heat transmitted from the holder 31 to the base body 33 is suppressed, and the mounting surface such as the ceiling surface 2 is prevented. The influence of discoloration can be easily suppressed.

  In this way, the temperature of the coldest part can be easily lowered to easily improve the luminous efficiency, the upper limit temperature of the lighting device 22 can be easily satisfied, and the temperature of the upper surface of the main body 21 can be lowered. Since the problem can be solved, it is easy to configure the high-power fluorescent lamp device 11. Further, it becomes possible to use a mercury alloy having a high mercury vapor pressure, improving the efficiency, improving the rising characteristics of the luminous flux, and obtaining a predetermined total luminous flux. Furthermore, in order to lower the coldest part temperature of the arc tube 88, it is not necessary to increase the volume of a portion for housing the arc tube 88, etc., and the fluorescent lamp device 11 can be downsized to improve the appliance compatibility rate. In this way, the fluorescent lamp device 11 can be provided which is thin and small and has a substantially disk shape and becomes bright immediately.

  The main body 21 is a so-called two-piece structure in which the holder 31 and the base body 33 form an outer shell, and the holder 31 and the base body 33 are attached by engagement. Furthermore, the partition plate 32 constituting the heat insulating means is merely placed on the holder 31 and the positioning portion 43 and the positioning receiving portion 53 are fitted and positioned in the rotational direction. It is positioned and fixed in the vertical direction and the rotational direction while being sandwiched between them. Therefore, the partition plate 32 can insulate the lighting device 22 from the heat of the fluorescent lamp 24, simplify the structure, simplify the assembly work, and reduce the manufacturing cost.

  In addition, since the holder 31 disposed in the vicinity of the fluorescent lamp 24 is made of a conductive metal, the starting characteristics of the fluorescent lamp 24 can be improved.

  Further, since the outer peripheral surface of the cover edge portion 37 of the holder 31 is an inclined surface, the surface area is improved and the heat dissipation can be improved.

  Further, with respect to the outer peripheral portion of the fluorescent lamp device 11, the outer peripheral surface of the cover edge 37 of the holder 31 and the outer surface 106 of the bulging portion 105 of the globe 25 are substantially smoothly continuous with each other, and as a whole, on the upper side, that is, on the base 23 side Since the inclined surface has a smaller radial dimension, it is possible to make it difficult to touch the cover edge 37 of the heated holder 31 when the user grasps the outer periphery of the fluorescent lamp device 11 from the lower side.

  FIG. 7 is an explanatory view showing another embodiment of the fluorescent lamp device of the present invention.

  In the above embodiment, as shown in FIG. 7, the commercial AC power supply has four connection pins 84 provided on the circuit board 77 of the lighting device 22 and connected to the wire 97 of the fluorescent lamp 24. Symmetric about the center line C passing through the base pin 34 of the base part 23 with respect to the input part 85 input from the wiring 86, that is, the wire 97 as an output line with respect to the wiring 86 as an input line. Can be provided at any position. In this configuration, the noise of the output line is difficult to be superimposed on the input line, and the insulation processing in the circuit board 77 can be facilitated. Further, in this configuration, the input / output-related parts of the circuit board 77 are arranged in accordance with the arrangement direction of the through holes 38 of the holder 31, that is, the through holes 50 of the partition plate 32, and the arrangement direction of the base pins 34 of the base part 23. By arranging, wiring work can be facilitated.

  Further, in each of the above-described embodiments, the amalgam-specific thin tube 98 that is the extending portion is linearly extended to be close to the inner surface of the globe 25, and the temperature of the coldest portion is reduced. In addition, or in place of this configuration, a bent thin tube 98 having various shapes such as bent is used, or other portions of the fluorescent lamp 24 other than the thin tube 98 for amalgam are close to a low temperature part such as the inner surface of the globe 25. Thus, the temperature of the coldest part can be lowered. Further, the shape of the arc tube 88 of the fluorescent lamp 24 is not limited to the configuration in which the three U-shaped bulbs 91, 92, 93 are sequentially connected by the communication tube 94, and various shapes can be adopted.

  Furthermore, in the above-described embodiment, the temperature of the coldest part is lowered by bringing the amalgam-specific thin tube 98, which is the extending part, close to the inner surface of the globe 25, but with this configuration or instead of this configuration A part of the arc tube 88 of the fluorescent lamp 24 can be adhered to another part such as the inner surface of the globe 25 by an adhesive means which is a heat conductive material, and the temperature of the coldest part can be lowered. That is, by adhering a part of the fluorescent lamp 24 and the globe 25 with an adhesive means having a large thermal conductivity and elasticity, the fluorescent lamp 24 can be stably supported, and the heat of the fluorescent lamp 24 passes through the adhesive means. Thus, it is transmitted to the globe 25 to form the coldest part at a desired temperature, and the luminous efficiency can be easily improved. Furthermore, the bonding means efficiently cools the fluorescent lamp 24 via the bonding means by the peripheral portion of the globe 25 where the temperature is expected to be lowered by the outside air by bonding the fluorescent lamp 24 to the peripheral portion of the globe 25, The coldest part at a desired temperature can be formed. In addition, the coldest part is provided in the central bulb 92 farthest from the electrode 96 where the temperature becomes high, so that the temperature can be easily lowered, and further, the temperature can be easily lowered by bending downward. Become.

  The integral structure holder 31 for holding the arc tube 88 is not limited to aluminum, but is made of aluminum (Al), copper (Cu), iron (Fe), nickel (Ni) having a thermal conductivity of 10 W / m · K or more. By comprising at least one kind of metal or ceramic, it is possible to ensure the effect of reducing the temperature of the arc tube 88, the lighting device 22, and the base 33 of the fluorescent lamp 24.

  Further, the heat treatment can be performed on the outer peripheral surface of the cover edge portion 37 of the holder 31 to reduce the temperature of each portion. For example, by applying white melanin phenol to the entire surface of the holder 31 made of aluminum, the outer peripheral surface of the cover edge 37 of the holder 31 can efficiently radiate and reduce the temperature of each part. The portion such as the lamp mounting surface 39 covered with the light can be efficiently illuminated with improved reflectance.

  On the other hand, the partition plate 32 which is a heat insulating means is made of a material having a thermal conductivity of 10 W / m · K or less, thereby ensuring the effect of reducing the temperature of the lighting device 22 and the base 33.

  Further, instead of the partition plate 32 or together with the partition plate 32, for example, a space is provided between the holder 31 that holds the arc tube 88 of the fluorescent lamp 24 and the partition plate 32 that holds the lighting device 22, or heat By arranging the heat insulating means having a conductivity of 5 W / m · K or less, the effect of reducing the temperature of the lighting device 22 and the base 33 can be easily improved.

  Further, the space between the holder 31 that holds the arc tube 88 of the fluorescent lamp 24 and the partition plate 32 that holds the lighting device 22 is provided with a vent that communicates with the outside of the main body 21, that is, the external atmosphere, or accommodates the lighting device. By providing the vent 20 in the base 33 or the like so that the portion 20 communicates with the outside of the main body 21, that is, the external atmosphere, the effect of reducing the temperature of the lighting device 22 and the base 33 can be easily improved, and the fluorescent lamp device 11 The rise of the pressure inside can be suppressed.

  Further, the arc tube 88 of the fluorescent lamp 24 is slightly separated from the lamp mounting surface 39 of the holder 31 by, for example, about 1 mm, so that the reflectance can be improved and illumination can be efficiently performed. Note that the arc tube 88 is supported by, for example, a leg projecting from the lamp mounting surface 39 and bonded by lamp bonding means such as silicone, so that it is thermally coupled to the holder 31 and can efficiently dissipate heat.

  Further, the arc tube 88 of the fluorescent lamp 24 can take various shapes. For example, in addition to the three U-shaped bulbs 91, 92, and 93, a straight tube fourth bulb is provided. An amalgam-specific thin tube 98 extending from the fourth valve can be projected. Further, the arc tube 88 can be formed by bending one bulb at a plurality of locations without providing the communication tube 94. Alternatively, the arc tube 88 can be formed by bending a single bulb in a spiral shape without providing the communication tube 94. In the configuration in which the arc tube 88 is configured by being bent or bent and the communication tube 94 is not provided, a decrease in the light beam due to the portion of the communication tube 94 is suppressed, and the light beam can be easily improved.

  In addition, in said embodiment, although the lighting fixture 1 directly attached and installed in the lower surface of the ceiling surface 2 was demonstrated, it is not restricted to this structure, The socket embedded and installed in the circular hole formed in the ceiling surface 2 The apparatus can also be used to configure a lighting fixture that is a downlight. Moreover, it is not restricted to the attachment to the ceiling surface 2, It can also attach to a wall surface or can suspend a socket apparatus from a ceiling surface.

  The present invention can be applied to, for example, a lighting fixture that is directly installed on a lower surface of a ceiling surface.

It is explanatory drawing which shows one Embodiment of the lighting fixture provided with the fluorescent lamp apparatus of this invention, (a) is a longitudinal cross-sectional view, (b) is a cross-sectional view. It is a perspective view of the state which removed the fluorescent lamp apparatus of the lighting fixture same as the above from the socket apparatus. It is a disassembled perspective view of a fluorescent lamp device same as the above. It is a side view of a fluorescent lamp device same as the above. It is the perspective view which looked at the partition plate of the fluorescent lamp device same as the above from the lower surface side. It is a cross-sectional view of the same fluorescent lamp device. It is explanatory drawing which shows other embodiment of the fluorescent lamp apparatus of this invention.

Explanation of symbols

1 lighting equipment
10 Socket device
11 Fluorescent lamp device
15 Power supply holes constituting the socket
20 Lighting device housing
21 Body
22 Lighting device
23 Base
24 Fluorescent lamp
25 Globe
39 Lamp mounting surface
62 Side wall
77 Circuit board
78 Surface mount components
79 Electrical components
81a Explosion-proof valve as lid

Claims (3)

A base body provided with a base part that can be attached to a socket part provided in the installation part, a lighting device housing part that faces the installation part, and a lamp mounting surface that faces the opposite side of the installation part;
The circuit board and the surface-mounted component mounted on the circuit board and the electrical component that is a discrete component other than the surface-mounted component are housed in the lighting device with the surface on which the electrical component that is the discrete component is mounted facing the opposite side of the installation part. A lighting device housed in a section;
A translucent glove covering the lamp mounting surface side of the main body;
A fluorescent lamp having a bulb arranged in a plane along the lamp mounting surface;
A fluorescent lamp device comprising: A base part mounted on a socket part provided in the installation part, a lighting device housing part having a substantially cylindrical side wall part, and a flat main body having a lamp mounting surface facing the installation part;
A square circuit board and an electrical component mounted on the circuit board and having a deployable lid, the electrical component being placed along the edge of the circuit board and housed in the lighting device housing With a lighting device;
A translucent glove covering the lamp mounting surface side of the main body;
A fluorescent lamp having a bulb arranged in a plane along the lamp mounting surface;
A fluorescent lamp device comprising: A fluorescent lamp device according to claim 1 or 2;
A socket device having a socket portion electrically connected to the base portion and mechanically holding the main body;
The lighting fixture characterized by comprising.

Images