阅读说明：本技术 轨道隧道照明装置 (Track tunnel lighting device ) 是由 鹿建 乔乾 潘虹 周琪 于 2021-09-24 设计创作，主要内容包括：本发明提供轨道隧道照明装置。该轨道隧道照明装置,包括灯体,所述灯体的表面设置有固态射频电源模块,所述灯体的内部设置有射频能量聚焦器,所述固态射频电源模块与射频能量聚焦器之间设有导接线,所述射频能量聚焦器的下表面设置有无频闪等离子灯珠,该轨道隧道照明装置,通过固态射频电源模块的设计,可将直流或交流电转化为具有特定频率高频电磁场,高频电磁场经过导接线耦合馈入到射频能量聚焦器腔体内部,利用无频闪等离子灯珠内的气体的电离反应,产生无频闪的灯光,同时利用防眩光反射器对灯光进行防眩晕处理,以此避免对驾驶员造成眩晕或视觉疲劳的现象,在保证照明效果的同时,保障驾驶员的安全驾驶。(The invention provides a track tunnel lighting device. The track tunnel lighting device comprises a lamp body, wherein a solid radio frequency power supply module is arranged on the surface of the lamp body, a radio frequency energy focalizer is arranged inside the lamp body, a lead wire is arranged between the solid radio frequency power supply module and the radio frequency energy focalizer, and a non-stroboscopic plasma lamp bead is arranged on the lower surface of the radio frequency energy focalizer, the safe driving of the driver is guaranteed.)

1. Track tunnel lighting device, including lamp body (1), its characterized in that: the surface of the lamp body (1) is provided with a solid radio frequency power supply module (2), a radio frequency energy focuser (3) is arranged inside the lamp body (1), a lead wire (21) is arranged between the solid radio frequency power supply module (2) and the radio frequency energy focuser (3), the lower surface of the radio frequency energy focuser (3) is provided with a non-stroboscopic plasma lamp bead (4), and an anti-dazzle reflector (5) is arranged inside the lamp body (1);

the solid radio frequency power supply module (2) is used for converting direct current or alternating current into a high-frequency electromagnetic field;

the radio frequency energy focalizer (3) is used for focusing the high-frequency electromagnetic field energy converted by the solid radio frequency power supply module (2);

the non-stroboscopic plasma lamp bead (4) is positioned in an energy concentration area inside the radio frequency energy focalizer (3), and gas capable of generating ionization reaction is filled inside the non-stroboscopic plasma lamp bead (4);

the anti-dazzle reflector (5) is matched with the shape and the light-emitting angle of the non-stroboscopic plasma lamp bead (4).

2. The track tunnel lighting device of claim 1, wherein: the solid radio frequency power supply module (2) selects 24V direct current or commercial power accessed through an AC-DC power supply.

3. The track tunnel lighting device of claim 1, wherein: the reflection angle range of the anti-dazzle reflector (5) is 32-63 degrees.

4. The track tunnel lighting device of claim 1, wherein: the device is characterized by further comprising an installation body (6), wherein a support (7) is rotatably connected to the surface of the installation body (6), a connection rotating shaft (71) is arranged between the support (7) and the installation body (6), a switching part (72) is arranged inside the support (7), and a driving regulation and control mechanism (8) is arranged inside the support (7).

5. The track tunnel lighting device of claim 4, wherein: the switching part (72) is positioned between the bracket (7) and the lamp body (1).

6. The track tunnel lighting device of claim 4, wherein: the driving regulation and control mechanism (8) comprises a driving gear (81), a first transmission gear (82), a second transmission gear (83), an adjusting telescopic rod (84) and an adjusting sleeve rod (85).

7. The track tunnel lighting device of claim 6, wherein: the driving gear (81), the first transmission gear (82) and the second transmission gear (83) are designed by bevel gears, and the driving gear (81) is located between the first transmission gear (82) and the second transmission gear (83).

8. The track tunnel lighting device of claim 6, wherein: the first transmission gear (82) is located on the surface of the connecting rotating shaft (71) and is in sliding connection with the connecting rotating shaft (71), a synchronous connecting rod is arranged between the first transmission gear (82) and the second transmission gear (83), and the first transmission gear (82) is in rotating connection with the second transmission gear (83).

9. The track tunnel lighting device of claim 6, wherein: the lower part of the second transmission gear (83) is provided with an eccentric disc (9), the surface of the eccentric disc (9) is rotatably connected with a lantern ring (91), the outer surface of the lantern ring (91) is fixedly connected with a push rod (92), the surface of the lamp body (1) is provided with a lamp shell (10), and the upper surface of the lamp shell (10) is provided with a sliding plate (101).

10. The track tunnel lighting device of claim 9, wherein: the eccentric disc (9) is in sliding connection with the second transmission gear (83), and the sliding plate (101) is in sliding connection with the push rod (92).

Technical Field

The invention relates to the technical field of lighting equipment, in particular to a track tunnel lighting device.

Background

Because the inside light in track tunnel is darker, consequently need be at track tunnel internally mounted lighting device, the lighting device in current track tunnel mainly adopts high-pressure sodium lamp, high-pressure mercury lamp etc. when the illumination operation, lighting device can exist and dazzle light, flash of frequencies etc. phenomenon, under this kind of condition, can cause certain influence to driver's vision, easily make driver produce dizzy or visual fatigue, can produce certain potential safety hazard to driver's driving.

In order to solve the problems, the track tunnel lighting device is provided, when the track tunnel is subjected to memorable lighting, the lighting device does not have a flash frequency phenomenon, and meanwhile, anti-dazzle reflection treatment can be carried out on generated light, so that the phenomenon of dizziness or visual fatigue of a driver can be effectively avoided, and the safe driving of the driver is guaranteed while the lighting effect is ensured.

Disclosure of Invention

In order to realize the purpose of the track tunnel lighting device, the invention is realized by the following technical scheme: the track tunnel lighting device comprises a lamp body, wherein a solid radio frequency power supply module is arranged on the surface of the lamp body, a radio frequency energy focuser is arranged inside the lamp body, a conducting wire is arranged between the solid radio frequency power supply module and the radio frequency energy focuser, a non-stroboscopic plasma lamp bead is arranged on the lower surface of the radio frequency energy focuser, and an anti-dazzle reflector is arranged inside the lamp body;

the solid radio frequency power supply module is used for converting direct current or alternating current into a high-frequency electromagnetic field;

the radio frequency energy focalizer is used for focusing the high-frequency electromagnetic field energy converted by the solid radio frequency power supply module;

the non-stroboscopic plasma lamp bead is positioned in an area with concentrated energy in the radio frequency energy focalizer, and gas capable of generating ionization reaction is filled in the non-stroboscopic plasma lamp bead;

the anti-dazzle reflector is matched with the shape and the light-emitting angle of the non-stroboscopic plasma lamp bead.

Further, the solid-state radio frequency power supply module selects 24V direct current or commercial power accessed through an AC-DC power supply.

Further, the reflection angle of the anti-glare reflector ranges from 32 degrees to 63 degrees.

The device is characterized by further comprising an installation body, wherein a support is rotatably connected to the surface of the installation body, a connection rotating shaft is arranged between the support and the installation body, a switching part is arranged inside the support, and a driving regulation and control mechanism is arranged inside the support.

Furthermore, the switching part is positioned between the bracket and the lamp body.

Furthermore, the driving regulation and control mechanism comprises a driving gear, a first transmission gear, a second transmission gear, an adjusting telescopic rod and an adjusting sleeve rod.

The driving gear, the first transmission gear and the second transmission gear are all designed by bevel gears, and the driving gear is located between the first transmission gear and the second transmission gear.

Furthermore, the transmission gear is located on the surface of the connecting rotating shaft and is in sliding connection with the connecting rotating shaft, a synchronous connecting rod is arranged between the transmission gear I and the transmission gear II, and the transmission gear I and the transmission gear II are in rotating connection.

Further, an eccentric disc is arranged on the lower portion of the second transmission gear, a lantern ring is rotatably connected to the surface of the eccentric disc, a push rod is fixedly connected to the outer surface of the lantern ring, a lamp housing is arranged on the surface of the lamp body, and a sliding plate is arranged on the upper surface of the lamp housing.

Furthermore, the eccentric disc is in sliding connection with the second transmission gear, and the sliding plate is in sliding connection with the push rod.

Compared with the prior art, the invention has the following beneficial effects:

1. this track tunnel lighting device, design through solid-state radio frequency power supply module, can turn into direct current or alternating current and have specific frequency high frequency electromagnetic field, high frequency electromagnetic field feeds into the radio frequency energy focuser cavity inside through leading the coupling of wiring, utilize the ionization reaction of the gas in the no stroboscopic plasma lamp pearl, produce no stroboscopic light, utilize anti-dazzle light reflector to carry out anti-dazzle halo to light simultaneously and handle, with this avoid causing dizzy or visual fatigue's phenomenon to the driver, when guaranteeing illuminating effect, guarantee driver's safe driving.

2. This track tunnel lighting device uses through the cooperation of drive gear and drive gear one, can rotate the lamp body and adjust, and drive gear two uses with the cooperation of eccentric disc, and rocking of usable lantern ring and push rod drives the lamp body and rotates to this can adjust the illumination angle of lamp body, can make the lamp body be applicable to different environment and different illumination position demand, is favorable to improving the illuminating effect of lamp body.

Drawings

FIG. 1 is a schematic front view of the present invention;

FIG. 2 is a schematic view of the structure of FIG. 1 at A according to the present invention;

FIG. 3 is a schematic top view of the present invention.

In the figure: 1. a lamp body; 2. a solid state radio frequency power supply module; 21. conducting wires; 3. a radio frequency energy focuser; 4. no stroboscopic plasma lamp bead; 5. an anti-glare reflector; 6. an installation body; 7. a support; 71. connecting the rotating shaft; 72. a switching part; 8. a driving regulation mechanism; 81. a drive gear; 82. a first transmission gear; 83. a second transmission gear; 84. adjusting the telescopic rod; 85. adjusting the loop bar; 9. an eccentric disc; 91. a collar; 92. a push rod; 10. a lamp housing; 101. a slide board.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The embodiment of the track tunnel lighting device is as follows:

referring to fig. 1-3, the track tunnel lighting device includes a lamp body 1, a solid-state rf power module 2 disposed on a surface of the lamp body 1, for converting direct current or alternating current into radio frequency power with specific frequency, a radio frequency energy focalizer 3 is arranged inside the lamp body 1, used for focusing the high-frequency electromagnetic field energy generated by the solid-state radio frequency power supply module 2, a conducting wire 21 is arranged between the solid-state radio frequency power supply module 2 and the radio frequency energy focalizer 3, used for coupling and feeding a high-frequency electromagnetic field into the cavity of the radio frequency energy focalizer 3, the lower surface of the radio frequency energy focalizer 3 is provided with a non-stroboscopic plasma lamp bead 4, non-flash-frequency light is generated through ionization reaction of gas in the lamp body 1, and an anti-glare reflector 5 is arranged in the lamp body 1 and used for performing anti-glare reflection treatment on the light generated by the non-flash-frequency plasma lamp beads 4;

the solid radio frequency power supply module 2 is used for converting direct current or alternating current into a high-frequency electromagnetic field;

the radio frequency energy focalizer 3 is used for focusing the high-frequency electromagnetic field energy converted by the solid-state radio frequency power supply module 2;

the non-stroboscopic plasma lamp bead 4 is positioned in an area with concentrated energy inside the radio frequency energy focalizer 3, gas capable of generating ionization reaction is filled inside the non-stroboscopic plasma lamp bead 4, and non-stroboscopic light is generated through the ionization reaction of the gas;

the anti-dazzle reflector 5 is matched with the non-stroboscopic plasma lamp bead 4 in shape and light-emitting angle, and is used for performing anti-dazzle reflection treatment on light rays generated by the non-stroboscopic plasma lamp bead 4.

The solid-state radio frequency power supply module 2 selects 24V direct current or commercial power accessed through an AC-DC power supply.

The reflection angle of the anti-glare reflector 5 ranges from 32 ° to 63 °.

The lamp body 1 is characterized by further comprising an installation body 6 used for installing the lighting device, wherein the surface of the installation body 6 is rotatably connected with a support 7 and used for installing and adjusting the lamp body 1, a connecting rotating shaft 71 is arranged between the support 7 and the installation body 6 and used for supporting the support 7, a switching part 72 is arranged inside the support 7 and used for rotating the lamp body 1, and a driving regulation and control mechanism 8 is arranged inside the support 7 and used for rotation adjustment of the support 7 and rotation control of the eccentric disc 9.

The adapter 72 is located between the bracket 7 and the lamp body 1, and is used for supporting and rotating the bracket 7.

The driving regulation and control mechanism 8 comprises a driving gear 81, a first transmission gear 82, a second transmission gear 83, an adjusting telescopic rod 84 and an adjusting sleeve rod 85.

The driving gear 81, the first transmission gear 82 and the second transmission gear 83 are designed by bevel gears, the driving gear 81 is located between the first transmission gear 82 and the second transmission gear 83, and the driving gear 81 can be meshed with the first transmission gear 82 or the second transmission gear 83 to drive the first transmission gear 82 or the second transmission gear 83 to rotate.

The first transmission gear 82 is located on the surface of the connecting rotating shaft 71 and is in sliding connection with the connecting rotating shaft 71, a synchronous connecting rod is arranged between the first transmission gear 82 and the second transmission gear 83, the first transmission gear 82 and the second transmission gear 83 are in rotating connection, the synchronous moving adjustment of the first transmission gear 82 and the second transmission gear 83 is achieved, and meanwhile the rotation of the first transmission gear 82 and the rotation of the second transmission gear 83 are independent.

The lower part of the second transmission gear 83 is provided with an eccentric disc 9 for driving a lantern ring 91 to move, the surface of the eccentric disc 9 is connected with the lantern ring 91 in a rotating mode and used for driving a push rod 92 to move, the outer surface of the lantern ring 91 is fixedly connected with the push rod 92, the lamp shell 10 is made to rotate by driving a sliding plate 101 to move, the surface of the lamp body 1 is provided with the lamp shell 10, and the upper surface of the lamp shell 10 is provided with the sliding plate 101 and used for rotating the lamp shell 10.

The eccentric disc 9 is in sliding connection with the second transmission gear 83, and the sliding plate 101 is in sliding connection with the push rod 92, so that the lamp housing 10 rotates by driving the sliding plate 101 to move.

When the plasma lamp is used, 24V direct current power supply is selected, or the solid-state radio frequency power supply module 2 is powered and driven by connecting an AC-DC power supply with commercial power, direct current or alternating current is converted into radio frequency power with specific frequency such as 433MHz, 915MHz or 2450MHz through the solid-state radio frequency power supply module 2, radio frequency energy, namely a high-frequency electromagnetic field is output through the conducting wire 21, the high-frequency electromagnetic field is coupled and fed into the cavity of the radio frequency energy focuser 3 through the conducting wire 21, the energy is focused and then concentrated in the area where the non-stroboscopic plasma lamp beads 4 are located, and gas in the non-stroboscopic plasma lamp beads 4 is ionized by the high-frequency electromagnetic field.

This ionization process is different with traditional high voltage electrode discharge, do not form pulse voltage and last discharge, but constitute by a series of ionization reactions, reaction process and high frequency electromagnetic field frequency do not have the relevance, the electromagnetic field is in promptly, the reaction just can last to go on, it produces along with ionization reactions is synchronous to give out light, consequently there is not stroboscopic effect, according to the luminous body shape size and the luminous angle characteristics of no stroboscopic plasma lamp pearl 4, carry out customization grading design anti-dazzle light reflector 5, can make the effectual irradiation track tunnel road surface and the surrounding environment of light that no stroboscopic plasma lamp pearl 4 launches.

The driving gear 81 is rotated by related driving equipment, the adjusting telescopic rod 84 is used for driving the adjusting sleeve rod 85 to move, the adjusting sleeve rod 85 is used for driving the first transmission gear 82 and the second transmission gear 83 to move together, when the first transmission gear 82 is meshed with the driving gear 81, the first transmission gear 82 does not rotate at the moment, the driving gear 81 is meshed with the first transmission gear 82, the first transmission gear 82 rotates on the surface of the first transmission gear 82, the support 7 is driven to rotate on the surface connected with the rotating shaft 71, and the support 7 drives the lamp body 1 to rotate together.

When the second transmission gear 83 is meshed with the second driving gear 81, the second driving gear 81 can drive the second transmission gear 83 to rotate, the second transmission gear 83 drives the eccentric disc 9 to rotate, the eccentric disc 9 can drive the lantern ring 91 to move, the lantern ring 91 drives the push rod 92 to move, the push rod 92 drives the lamp housing 10 to rotate through the sliding plate 101, and the lamp housing 10 drives the lamp body 1 to rotate on the surface of the switching part 72, so that the irradiation angle of the lamp body 1 can be adjusted.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.