JP2018078091A - LED glass tube lamp - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a slim LED glass tube lamp with high luminance which has excellent heat radiation and which can achieve slimness.SOLUTION: An LED glass tube lamp includes: a support body 10 for holding hard conductor wires 8, 9, 13, 14 mounted on electrodes 4-7 of filament LEDs 2, 3 for arranging the filament LEDs 2, 3 along a center line of a cylindrical glass tube 1 having light transmissivity. The support body 10 is made of an insulation material having good heat conductivity and light transmissivity. The LED glass tube lamp also has a recess for holding the hard conductor wires 8, 9, 13, 14 mounted on the electrodes 4-7 of the filament LEDs 2, 3 in the vicinity of the center of the support body 10. A periphery part of the support body 10 comes into contact with an inner surface of the glass tube 1. A highly heat conductive helium gas is sealed inside the cylindrical glass tube 1 for storing the filaments LEDs 2, 3.SELECTED DRAWING: Figure 1

Description

  In order to accommodate a filament LED that emits light in all directions in an elongated glass tube, a large glass bulb is generally required for heat resistance. For this reason, when using it for a large chandelier with many decorations such as a bag, not only the outer shape becomes larger but also the weight becomes heavier. Therefore, there is a demand for a bow lamp using a filament LED that is thin and has a slim and high brightness. Here, it proposes regarding the structure and manufacture of a thin and slim high-intensity LED baud lamp using a filament LED.

  Lighting fixtures such as chandeliers and pendants that are installed on the ceilings of salons often require large, gorgeous and heavy objects. Accordingly, the light source is required to have a high brightness, a thin shape, and a slim shape. Therefore, as an alternative to a light bulb-type LED lamp containing a conventional chip LED, a thin, slim, high-brightness, high-luminance, omnidirectionally emitting filament LED is housed in a heat-resistant, translucent glass tube. The present invention seeks to provide a tubular filament LED baud lamp.

  Patent Document 1 describes that, as in the present invention, a light-emitting strip with an LED chip that emits omnidirectional light is housed in a valve shell that forms a vacuum sealed chamber. Also shown is a structural schematic diagram in which the vacuum sealed chamber is filled with a gas with high thermal conductivity having a low viscosity coefficient, and the LED chip is covered with a luminescent powder layer. It is described that this LED light-emitting strip is electrically connected to a driver and an electrical connector to light up.

  Further, it is described that a PS type, a T type and the like are used as a valve shell, and a base such as an E26 type and an E14 type is used as an electrical connector. Further, it is described that in the embodiment using the T-type bulb shell, the LED light-emitting strip does not have a luminous powder layer and a luminous powder layer is provided on the inner wall of the bulb shell.

  However, there is no description about the structure of the LED baud lamp when the filament LED is housed inside a glass tube having a tube diameter of 17 mm and a length exceeding 200 mm. Especially 1. 1. Description of the shape and structure corresponding to the support referred to in the present proposal, regarding the structure in which the filament LED is arranged so as to substantially coincide with the center line of the glass tube. 2. Description of sealing plug structure for sealing the inside of the glass tube and sealing procedure; There is no specific description about a procedure for filling a gas tube with high thermal conductivity into a glass tube to be evacuated.

Japanese Patent No. 5687524

  As shown in [0005], the present invention proposes a matter in which the structure of an LED baud lamp that accommodates a filament LED is not described. The filament LED is mainly contained in a hard glass tube having a tube diameter of 17 mm and a length of 200 mm or more. It proposes about the structure of the LED baud lamp which stores.

  This will be described with reference to FIGS. 1, 2, 3, and 4.

  An E17 or E26 base 24 for supplying external electricity to the driving device 23 is attached. The E17 or E26 base 24 is integrated with the sealing plug 17 at the base of the hard glass tube 1 and the driving device 23, and is jointed with an insulating base adapter A25, base adapter B26, and base adapter C27 that cover them. It acts as an electrical insulation cover and forms an aesthetic appearance.

  In the case where a plurality of filament LEDs including 2 and 3 are arranged inside the hard glass tube 1, the electrode end 5 of the 2 filament LED and the electrode end 6 of the 3 filament LED are adjacent to each other. The connecting wire 8 of the hard conductive wire is spot-welded while remaining straight. When the electrode end portions are adjacent to each other like the electrode end portions 5 and 6, the connecting wire 8 of the hard conducting wire can be easily disposed near the center portion of the hard glass tube 1. As a result, it is convenient to fit into the recess 11 near the center among the plurality of recesses 11 and 12 of the support 10 provided to stably fix the jumper wire 8. Thereby, a few filament LED can be arrange | positioned easily and stably in the center part of the hard glass tube 1. FIG.

  On the other hand, when the electrode ends 4 separated from each other, such as the electrode end 4 of the second filament LED and the electrode end 7 of the third filament LED, are connected by the connecting wire of the hard conductor, the connecting wire 9 has two or three filaments. Pass away from the LED and close to the inner surface of the hard glass tube 1. At this time, the crossover wire 9 is fitted into the concave portion 12 away from the center portion of the support 10 and fixed.

  The filament LEDs 2 and 3 are arranged in the vicinity of the central portion in the hard glass tube 1 by fixing the crossover wires 8 and 9 of the hard conductors to the recesses 11 and 12 of the support 10, respectively. Hard lead lead wires 15 and 16 are spot welded to the hard lead wires 13 and 14 drawn from the filament LED on the outlet side in the hard glass tube 1. Next, after the introduction wires 15 and 16 pass through the holes 18 and 19 of the sealing plug 17, the introduction wire ends are drawn out of the hard glass tube 1 like the introduction wires 20 and 21. The lead wires 15, 16, 20, and 21 pass through the holes 18 and 19 of the sealing plug 17, and then the gaps are sealed with a heat-resistant adhesive. This completes the subassembly of the parts that enter the hard glass tube 1.

  Next, the aforementioned subassembly is inserted from the open end side of the hard glass tube 1. Thereafter, the sealing plug 17 and the hard glass tube 1 are bonded with a heat-resistant adhesive. In order to seal the gap with the holes 18 and 19 of the sealing plug 17 through the introduction lines 15, 16, 20, and 21, the bonding operation may be performed at this time. Thereafter, the air inside the hard glass tube 1 is exhausted through the exhaust hole 22 provided in the sealing plug 17.

  Another embodiment in which the air in the hard glass tube 1 is exhausted and gas is enclosed will be described with reference to FIG. FIG. 4 shows a schematic structure of a part called a stem in which an exhaust port 22 that has been widely used so far is formed when manufacturing a light bulb. The introduction wires 15, 16, 20, and 21 having a stem glass 28 and a jumet wire connected to a part thereof are heat-sealed and securely sealed. The stem glass 28 with the jumet line portion 31 has a top hat-shaped stem collar portion 29 attached thereto. After the filament LED crossover wires 13 and 14 and the stem lead wires 15 and 16 are spot welded and the stem is assembled to the filament LED, the filament LED is inserted into the rigid glass tube 1 and the stem collar 29 and the The glass tube 1 is heat-sealed.

  After the air in the hard glass tube 1 is exhausted from the exhaust hole 22, helium gas with high thermal conductivity is sealed, and the exhaust port 22 is sealed. Thereby, the light emitting part is completed.

  In order to make this light emitting part electrically connected to the outside so that it can be lit, the E23 or E26 base 24 is connected after the drive device 23 is attached.

  The sealing plug 17, the driving device 23, E17 or E26 base 24 is fixed by the base adapters A, B and C 25, 26 and 27 so that the charging portion of the E17 or E26 base 24 is not unnecessarily exposed. It is mechanically integrated with the hard glass tube 1 to enhance safety and appearance design.

  In the filament LED baud lamp of the present invention, helium gas having a high thermal conductivity is sealed in a hard glass tube having a tube diameter of 17 mm to cause the filament LED to emit light. Therefore, it has good heat dissipation and can increase the load on the tube wall compared to conventional LED bo lamps. It can be used as a light source for lighting fixtures such as decorative chandeliers that are mounted on high ceilings. is there. In addition, helium gas with high thermal conductivity is inert and nonflammable like the rare gases argon, xenon, krypton, etc., and can be handled safely. The filament LED baud lamp of the present invention is light in weight and small in volume, and can reduce packaging and transportation costs. In addition to high brightness, it is a slim light source, so it is ideal for brackets as well as pendants. In addition, dimming can produce a variety of effects and enhance the interior. The hard glass tube may be transparent or frosted.

It is an Example of the filament LED baud lamp concerning this invention. It is an enlarged view of the support body concerning the Example of this invention. It is an enlarged view at the time of manufacturing the sealing stopper concerning the Example of this invention with an aluminum material. It is an enlarged view at the time of manufacturing the sealing stopper concerning the Example of this invention with glass material.

  DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below with reference to FIG. 1 to FIG.

  The filament LED baud lamp according to the present invention has a plurality of omnidirectional light emitting filament LEDs 2 and 3 arranged inside a hard glass tube 1 having an elongated test tube shape, that is, two in series and two in parallel, and is fed to one end. Therefore, an E17 or E26 base 24 is attached. As many filament LEDs as necessary can be combined and connected in a series, parallel, and series-parallel with crossovers so that a necessary luminous flux can be obtained. The introduction lines 15 and 16 at the power supply end are connected to the driving device 23 via introduction lines 20 and 21 passing through the sealing plug 17 shown in FIG. Further, the driving device 23 is electrically connected to the E17 or E26 base 24.

  Another embodiment in which the sealing plug is made of the glass material shown in FIG. 4 will be described. This glass sealing plug uses a technique that is often used in the manufacture of the stem portion of a light bulb, and the necessary portions of the lead wires 15, 16, 20, 21 having the jumet wire portion 31 are the stem glass. 29 is fused. Thereafter, the lead wires 15 and 16 are spot-welded to the crossover wires 13 and 14 from the filament LED. This subassembly is inserted into the hard glass tube 1, and the stem collar 29 and the end of the hard glass tube 1 are heat-sealed. Exhausting air from the exhaust port 22 of the stem portion and sealing the helium gas is the same as in the case of the aluminum sealing plug of FIG.

  When the stem of FIG. 4 is heat-sealed to the hard glass tube 1, the support 10 made of resin may be melted and deformed by the heat. For this reason, the heat shield plate 30 is inserted between the support 10 and the stem for heat insulation. Thereby, it is not necessary to lengthen the base part of the hard glass tube 1 unnecessarily.

  As another embodiment from the optical aspect according to the present invention, a frosted hard glass tube having translucency may be used in place of the transparent hard glass tube to suppress the luminance.

  The filament LED bow lamp of the present invention is a luminaire having a design with high brightness and excellent decorativeness, including chandeliers and pendants and brackets that require high brightness. A slim and inexpensive product can be provided.

1 Hard glass tube 2 Filament LED
3 Filament LED
DESCRIPTION OF SYMBOLS 4 Electrode end part 5 Electrode end part 6 Electrode end part 7 Electrode end part 8 Crossover wire 9 Crossover line 10 Support body 11 Recessed part 12 Recessed part 13 Crossover line 14 Crossover line 15 Introduction line 16 Introduction line 17 Sealing plug 18 Hole 19 Hole 20 Lead wire 21 Lead wire 22 Exhaust port 23 Drive unit 24 E17 or E26 base 25 Base adapter A
26 Base Adapter B
27 Base Adapter C
28 Stem Glass 29 Stem Brim 30 Heat-shielding Plate 31 Jumet Wire

In order to accommodate a filament LED that emits light in all directions in an elongated glass tube, a large glass bulb is generally required for heat resistance. For this reason, when using it for a large chandelier with many decorations such as a bag, not only the outer shape becomes larger but also the weight becomes heavier. Therefore, there is a demand for an LED glass tube lamp using a filament LED that is thin and has a slim and high brightness. Here, it proposes regarding the structure and manufacture of the thin and slim high-intensity LED glass tube lamp which uses filament LED.

Lighting fixtures such as chandeliers and pendants that are installed on the ceilings of salons often require large, gorgeous and heavy objects. Accordingly, the light source is required to have a high brightness, a thin shape, and a slim shape. Therefore, as an alternative to a light bulb-type LED lamp containing a conventional chip LED, a thin, slim, high-brightness, high-luminance, omnidirectionally emitting filament LED is housed in a heat-resistant, translucent glass tube. It is intended to provide a tubular filament LED glass tube lamp.

  Patent Document 1 describes that, as in the present invention, a light-emitting strip with an LED chip that emits omnidirectional light is housed in a valve shell that forms a vacuum sealed chamber. Also shown is a structural schematic diagram in which the vacuum sealed chamber is filled with a gas with high thermal conductivity having a low viscosity coefficient, and the LED chip is covered with a luminescent powder layer. It is described that this LED light-emitting strip is electrically connected to a driver and an electrical connector to light up.

  Further, it is described that a PS type, a T type and the like are used as a valve shell, and a base such as an E26 type and an E14 type is used as an electrical connector. Further, it is described that in the embodiment using the T-type bulb shell, the LED light-emitting strip does not have a luminous powder layer and a luminous powder layer is provided on the inner wall of the bulb shell.

However, there is no description about the structure of the LED glass tube lamp in the case where the filament LED is housed in a glass tube having a tube diameter of 17 mm and a length exceeding 200 mm. Especially 1. 1. Description of the shape and structure corresponding to the support referred to in the present proposal, regarding the structure in which the filament LED is arranged so as to substantially coincide with the center line of the glass tube. 2. Description of sealing plug structure for sealing the inside of the glass tube and sealing procedure; There is no specific description about a procedure for filling a gas tube with high thermal conductivity into a glass tube to be evacuated.

Japanese Patent No. 5687524

As described above, the present invention proposes the matter that the structure of the LED glass tube lamp that accommodates the filament LED is not described . The filament LED is mainly accommodated in a hard glass tube having a tube diameter of 17 mm and a length of 200 mm or more. The structure of the LED glass tube lamp is proposed.

  This will be described with reference to FIGS. 1, 2, 3, and 4.

  An E17 or E26 base 24 for supplying external electricity to the driving device 23 is attached. The E17 or E26 base 24 is integrated with the sealing plug 17 at the base of the hard glass tube 1 and the driving device 23, and is jointed with an insulating base adapter A25, base adapter B26, and base adapter C27 that cover them. It acts as an electrical insulation cover and forms an aesthetic appearance.

  In the case where a plurality of filament LEDs including 2 and 3 are arranged inside the hard glass tube 1, the electrode end 5 of the 2 filament LED and the electrode end 6 of the 3 filament LED are adjacent to each other. The connecting wire 8 of the hard conductive wire is spot-welded while remaining straight. When the electrode end portions are adjacent to each other like the electrode end portions 5 and 6, the connecting wire 8 of the hard conducting wire can be easily disposed near the center portion of the hard glass tube 1. As a result, it is convenient to fit into the recess 11 near the center among the plurality of recesses 11 and 12 of the support 10 provided to stably fix the jumper wire 8. Thereby, a few filament LED can be arrange | positioned easily and stably in the center part of the hard glass tube 1. FIG.

  On the other hand, when the electrode ends 4 separated from each other, such as the electrode end 4 of the second filament LED and the electrode end 7 of the third filament LED, are connected by the connecting wire of the hard conductor, the connecting wire 9 has two or three filaments. Pass away from the LED and close to the inner surface of the hard glass tube 1. At this time, the crossover wire 9 is fitted into the concave portion 12 away from the center portion of the support 10 and fixed.

  The filament LEDs 2 and 3 are arranged in the vicinity of the central portion in the hard glass tube 1 by fixing the crossover wires 8 and 9 of the hard conductors to the recesses 11 and 12 of the support 10, respectively. Hard lead lead wires 15 and 16 are spot welded to the hard lead wires 13 and 14 drawn from the filament LED on the outlet side in the hard glass tube 1. Next, after the introduction wires 15 and 16 pass through the holes 18 and 19 of the sealing plug 17, the introduction wire ends are drawn out of the hard glass tube 1 like the introduction wires 20 and 21. The lead wires 15, 16, 20, and 21 pass through the holes 18 and 19 of the sealing plug 17, and then the gaps are sealed with a heat-resistant adhesive. This completes the subassembly of the parts that enter the hard glass tube 1.

  Next, the aforementioned subassembly is inserted from the open end side of the hard glass tube 1. Thereafter, the sealing plug 17 and the hard glass tube 1 are bonded with a heat-resistant adhesive. In order to seal the gap with the holes 18 and 19 of the sealing plug 17 through the introduction lines 15, 16, 20, and 21, the bonding operation may be performed at this time. Thereafter, the air inside the hard glass tube 1 is exhausted through the exhaust hole 22 provided in the sealing plug 17.

Another embodiment in which the air in the hard glass tube 1 is exhausted and gas is enclosed will be described with reference to FIG. FIG. 4 shows a schematic structure of a part called a stem in which an exhaust hole 22 that has been widely used so far is formed when manufacturing a light bulb. The introduction wires 15, 16, 20, and 21 having a stem glass 28 and a jumet wire connected to a part thereof are heat-sealed and securely sealed. The stem glass 28 with the jumet line portion 31 has a top hat-like stem collar portion 29 attached thereto. After the filament LED crossover wires 13 and 14 and the stem lead wires 15 and 16 are spot welded and the stem is assembled to the filament LED, the filament LED is inserted into the rigid glass tube 1 and the stem collar 29 and the The glass tube 1 is heat-sealed.

After the air in the hard glass tube 1 is exhausted from the exhaust hole 22 , helium gas with high thermal conductivity is sealed, and the exhaust hole 22 is sealed. Thereby, the light emitting part is completed.

  In order to make this light emitting part electrically connected to the outside so that it can be lit, the E23 or E26 base 24 is connected after the drive device 23 is attached.

  The sealing plug 17, the driving device 23, E17 or E26 base 24 is fixed by the base adapters A, B and C 25, 26 and 27 so that the charging portion of the E17 or E26 base 24 is not unnecessarily exposed. It is mechanically integrated with the hard glass tube 1 to enhance safety and appearance design.

In the filament LED glass tube lamp of the present invention, helium gas having a high thermal conductivity is sealed in a hard glass tube having a tube diameter of 17 mm to emit light from the filament LED. Therefore, heat dissipation is good and the tube wall load can be increased compared to conventional LED glass tube lamps, so that high-intensity lamps can be obtained and used as a light source for lighting fixtures such as decorative chandeliers mounted on high ceilings. Is optimal. In addition, helium gas with high thermal conductivity is inert and nonflammable like the rare gases argon, xenon, krypton, etc., so it can be handled safely. The filament LED glass tube lamp of the present invention can be reduced in weight and volume, and the packaging and transportation costs can be reduced. In addition to high brightness, it is a slim light source, so it is ideal for brackets as well as pendants. In addition, dimming can produce a variety of effects and enhance the interior. The hard glass tube may be transparent or frosted.

It is an Example of the filament LED glass tube lamp concerning this invention. It is an enlarged view of the support body concerning the Example of this invention. It is an enlarged view at the time of manufacturing the sealing stopper concerning the Example of this invention with an aluminum material. It is an enlarged view at the time of manufacturing the sealing stopper concerning the Example of this invention with glass material.

Hereinafter, the embodiments of the present invention will be described based on the exemplary illustration of FIGS.

The filament LED glass tube lamp according to the present invention has a plurality of omnidirectional light emitting filament LEDs 2 and 3 arranged inside a hard glass tube 1 having an elongated test tube shape, that is, two in series and two in parallel, arranged in a straight line at one end. An E17 or E26 base 24 is attached for power supply. As many filament LEDs as necessary can be combined and connected in a series, parallel, and series-parallel with crossovers so that a necessary luminous flux can be obtained. The introduction lines 15 and 16 at the power supply end are connected to the driving device 23 via introduction lines 20 and 21 passing through the sealing plug 17 shown in FIG. Further, the driving device 23 is electrically connected to the E17 or E26 base 24.

Another embodiment in which the sealing plug is made of the glass material shown in FIG. This glass sealing plug uses a technique that is often used in the manufacture of the stem portion of a light bulb, and the necessary portions of the lead wires 15, 16, 20, 21 having the jumet wire portion 31 are the stem glass. Fused to 28 . Thereafter, the lead wires 15 and 16 are spot-welded to the crossover wires 13 and 14 from the filament LED. This subassembly is inserted into the hard glass tube 1, and the stem collar 29 and the end of the hard glass tube 1 are heat-sealed. Exhausting air from the exhaust hole 22 of the stem portion and sealing the helium gas is the same as in the case of the aluminum sealing plug of FIG.

  When the stem of FIG. 4 is heat-sealed to the hard glass tube 1, the support 10 made of resin may be melted and deformed by the heat. For this reason, the heat shield plate 30 is inserted between the support 10 and the stem for heat insulation. Thereby, it is not necessary to lengthen the base part of the hard glass tube 1 unnecessarily.

  As another embodiment from the optical aspect according to the present invention, a frosted hard glass tube having translucency may be used in place of the transparent hard glass tube to suppress the luminance.

The filament LED glass tube lamp of the present invention is lighter and safer than ever in luminaires with high brightness and decorative design, including chandeliers, pendants and brackets that require high brightness. Therefore, a slim and inexpensive product can be provided.

1 Hard glass tube 2 Filament LED
3 Filament LED
DESCRIPTION OF SYMBOLS 4 Electrode end part 5 Electrode end part 6 Electrode end part 7 Electrode end part 8 Crossover wire 9 Crossover line 10 Support body 11 Recessed part 12 Recessed part 13 Crossover line 14 Crossover line 15 Introduction line 16 Introduction line 17 Sealing plug 18 Hole 19 Hole 20 Lead line 21 Lead line 22 Exhaust hole 23 Drive unit 24 E17 or E26 base 25 Base adapter A
26 Base Adapter B
27 Base Adapter C
28 Stem Glass 29 Stem Brim 30 Heat-shielding Plate 31 Jumet Wire

  An E17 base 24 for supplying external electricity to the driving device 23 is attached. The E17 base 24 is integrated with the sealing plug 17 at the base of the hard glass tube 1 and the driving device 23, and is electrically insulated in cooperation with the insulating base adapter A25, base adapter B26, and base adapter C27 covering these. While acting as a cover, it forms an aesthetic appearance.

  In order to be able to light up the light emitting portion by making an electrical connection with the outside, the E17 base 24 is connected after the driving device 23 is attached.

  The sealing plug 17, the drive device 23, and the E17 base 24 are fixed by the base adapters A, B, and C 25, 26, and 27 so that the charging portion of the E17 base 24 is not unnecessarily exposed. Mechanically integrated to enhance the design of safety and appearance.

  The filament LED glass tube lamp according to the present invention has a plurality of omnidirectional light emitting filament LEDs 2 and 3 arranged inside a hard glass tube 1 having an elongated test tube shape, that is, two in series and two in parallel, arranged in a straight line at one end. An E17 base 24 is attached for power supply. As many filament LEDs as necessary can be combined and connected in a series, parallel, and series-parallel with crossovers so that a necessary luminous flux can be obtained. The introduction lines 15 and 16 at the power supply end are connected to the driving device 23 via introduction lines 20 and 21 passing through the sealing plug 17 shown in FIG. Further, the driving device 23 is electrically connected to the E17 base 24.

1 Hard glass tube 2 Filament LED
3 Filament LED
DESCRIPTION OF SYMBOLS 4 Electrode end part 5 Electrode end part 6 Electrode end part 7 Electrode end part 8 Crossover wire 9 Crossover line 10 Support body 11 Recessed part 12 Recessed part 13 Crossover line 14 Crossover line 15 Introduction line 16 Introduction line 17 Sealing plug 18 Hole 19 Hole 20 Lead wire 21 Lead wire 22 Exhaust hole 23 Drive unit 24 E17 base 25 Base adapter A
26 Base Adapter B
27 Base Adapter C
28 Stem Glass 29 Stem Brim 30 Heat-shielding Plate 31 Jumet Wire

Claims (5)

  An LED baud lamp comprising a support for holding a hard wire attached to an electrode of a filament LED for disposing the filament LED along a central line of a cylindrical glass tube having translucency.   The support is made of an insulating material having good heat conductivity and good translucency, and has a recess for holding a hard wire attached to the electrode of the filament LED in the vicinity of the center of the support, and a peripheral portion of the support 2. The LED bow lamp according to claim 1, wherein the LED is in contact with the inner surface of the glass tube.   The LED baud lamp according to claim 1 or 2, wherein a gas having high thermal conductivity is sealed in a cylindrical glass tube that houses the filament LED.   The LED baud lamp according to any one of claims 1 to 3, wherein helium gas is sealed as a gas having high thermal conductivity in the cylindrical glass tube.   The LED baud lamp according to any one of claims 1 to 4, wherein an E17 or E26 bulb cap for connecting to an external power source is attached to one end of the cylindrical glass tube.

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