CN206817190U - A kind of Underwater Optical Fiber lamp - Google Patents

Abstract

The utility model proposes a kind of Underwater Optical Fiber lamp, including：Rear module and front-end module, connected between rear module and front-end module using the first optical fiber；Wherein, front-end module includes：Optical fiber tapered end, the first optical fiber, Optical devices, cover, safety glass, built-in fitting, lamp body, wherein, first optical fiber is fixed on lamp body by optical fiber tapered end, Optical devices are fixed on lamp body, and cover and safety glass are fixed on lamp body using screw, and support is fixed on lamp body；Optical devices are reflector or lens, and rear module includes：Power supply, light source, the first coupling device, controller, radiator, power supply are direct current transducer, and its output end is connected with light source, and the first coupling device connects light source and the first optical fiber respectively, and the radiator is arranged on the outside of power supply and light source.The beneficial effects of the utility model are：1 the utility model is fiber optic conduction underwater lighting system photodetachment, to reach to human body non-contact electric hidden danger and have the equal illuminating effect of traditional underwater lamp.

Description

Optical fiber underwater lamp

Technical Field

The utility model relates to a lighting device, concretely relates to optic fibre is lamp under water.

Background

The existing traditional underwater lamp cannot be subjected to photoelectric separation, has high waterproof requirement, has the potential leakage hazard and has extremely high danger to a human body.

The size of the existing traditional underwater lamp cannot be very small, and the user experience is poor.

The existing traditional underwater lamp cannot be separated photoelectrically, when the underwater lamp is used for underwater environment illumination such as a swimming pool or a fountain, an additional water inlet system needs to be arranged, the two systems need to be isolated, the structure is complex, the cost is high, the underwater lamp is easy to damage, is not easy to maintain and is not beautiful.

The existing traditional underwater lamp cannot be separated photoelectrically, in order to be waterproof, the underwater lamp needs to be completely sealed, and the lighting effect is monotonous, and the user experience is very poor.

Disclosure of Invention

In order to solve the above problem, the utility model provides an optic fibre is lamp under water, include: the rear end module is connected with the front end module through a first optical fiber; wherein,

the front end module includes: the optical fiber lamp comprises an optical fiber lock head, a first optical fiber, an optical device, a face cover, toughened glass, an embedded part and a lamp body, wherein the first optical fiber is fixed on the lamp body by the optical fiber lock head;

the optical device is a reflective cup or a lens,

the back end module includes: a power supply, a light source, a first coupling device, a controller, a heat sink,

the power supply is a direct current converter, the output end of the direct current converter is connected with the light source, the first coupling device is respectively connected with the light source and the first optical fiber, and the radiator is arranged on the outer sides of the power supply and the light source.

Further, the first optical fiber and the optical device are plural.

Furthermore, the face lid and toughened glass reserve the water filling hole, still include the filler pipe, filler pipe one end is connected with face lid and toughened glass water filling hole, and the other end is connected with water feeding system.

Furthermore, a part of the water adding pipe is made of transparent materials and is fixed on the light emitting surface of the optical device.

Furthermore, the front-end module further comprises a second coupling device and a second optical fiber, the second optical fiber is connected with the first optical fiber through the second coupling device, the second optical fiber penetrates through the water filling hole, and the second optical fiber is a side light-emitting optical fiber.

Further, the rear module is provided with a plurality of filters and a filter selection means, interposed between the light source and the first coupling means, for varying the light emission colour.

Furthermore, the rear end module is also provided with a wireless communication module and a controller, the wireless communication module is connected with the controller and the filter selection device, the wireless communication module receives a control signal sent by the remote server and controls the filter selection device to select the filter according to the control signal so as to change the light emission color, or receives the control signal sent by the remote server and sends the control signal to the controller so as to control the light emission intensity.

Furthermore, the front-end module also comprises an objective lens which is used for collecting the light rays around the front-end module; the rear end module also comprises an image sensor, and the image sensor is connected with the objective lens through a first optical fiber; the image sensor receives light collected by the objective lens and generates images around the front-end module, the image sensor is connected with the controller, the controller calculates brightness values of the light around the front-end module according to the images around the front-end module, the optical fiber lamp is turned on through the controller if the brightness values around the front-end module are smaller than a preset value, and the optical fiber lamp is turned off through the controller if the brightness values around the front-end module are larger than the preset value.

The utility model has the advantages that:

the utility model discloses an optical fiber conduction is lighting system photoelectric separation under water to reach no electric shock hidden danger and have the equal illuminating effect of traditional lamp under water to the human body.

2 in the optical fiber underwater lamp lighting system, the front end module guides light for the optical fiber, and does not need to be used as a radiator to radiate heat for the LED, so that the volume and the weight of the lamp are reduced, and the working hours of installation and maintenance are reduced;

3 the utility model discloses optic fibre is lamp lighting system under water, front end module are optic fibre leaded light, are not afraid of optic fibre and intake water and influence light-emitting effect and lamps and lanterns life-span, need not to do waterproof design to cost is reduced and maintenance cost that lamps and lanterns have bad.

Drawings

Fig. 1 is a front end module composition of an underwater optical fiber lamp according to an embodiment of the present invention.

Fig. 2 is a structure diagram of an optical fiber underwater lamp according to an embodiment of the present invention.

Detailed Description

Fig. 1 is the utility model discloses an optical fiber is lamp front end module composition under water, wherein 1 is toughened glass, 2 is the face lid, 3 is optical device, 4 is the optic fibre tapered end, 5 is the lamp body, 6 is the support, 7 is first optic fibre.

The utility model provides an optic fibre is lamp under water, include: the rear end module is connected with the front end module through a first optical fiber; wherein,

the front end module includes: the optical fiber lamp comprises an optical fiber lock head, a first optical fiber, an optical device, a face cover, toughened glass, an embedded part and a lamp body, wherein the first optical fiber is fixed on the lamp body by the optical fiber lock head;

the optical device is a reflective cup or a lens,

the back end module includes: a power supply, a light source, a first coupling device, a controller, a heat sink,

the power supply is a direct current converter, the output end of the direct current converter is connected with the light source, the first coupling device is respectively connected with the light source and the first optical fiber, and the radiator is arranged on the outer sides of the power supply and the light source.

The power supply converts alternating current into direct current and drives the light source to emit light, the first coupling device couples light emitted by the light source into the first optical fiber 7, and the heat radiator conducts heat generated by photoelectric conversion away to reduce the temperature of the photoelectric module.

Through separating front end module and rear end module, electrified luminous component all installs in the rear end module, the front end module passes through fiber connection with the rear end module, photoelectric separation has been realized, the front end module is uncharged, do not generate heat, a lamp can not do waterproofly under water for simple structure is not fragile, a plurality of front end modules can be connected to a rear end module, the rear end module that the structure is complicated can not be put under water and place ground easy to maintain's place in, make things convenient for fortune dimension personnel to maintain.

The first optical fiber and the optical device are plural.

Furthermore, the face lid and toughened glass reserve the water filling hole, still include the filler pipe, filler pipe one end is connected with face lid and toughened glass water filling hole, and the other end is connected with water feeding system.

Utilize optic fibre under water light electricity separation's characteristic, reserve the water filling hole at face lid 2 and toughened glass 1, the water filling hole is connected with the filler pipe, when needing to add water, the filler pipe is direct to add water through optic fibre under water lamp, unites two into one water system and lighting system, simple structure, and is with low costs, and is not fragile, easy to maintain, handsome in appearance.

And one part of the water adding pipe is made of transparent material and is fixed on the light-emitting surface of the optical device.

A part of the water feeding pipe is fixed on the light emitting surface of the optical device 3, when the lighting system and the water feeding system work simultaneously, light emitted by the light emitting surface of the optical device 3 penetrates through the transparent water feeding pipe with liquid flowing to generate a dazzling lighting effect, and user experience is improved.

The front-end module further comprises a second coupling device and a second optical fiber, the second optical fiber is connected with the first optical fiber through the second coupling device, the second optical fiber penetrates through the water adding hole, and the second optical fiber is a side light-emitting optical fiber.

The second optic fibre is the luminous optic fibre of side, and the entire body is luminous and passes the water filling hole, and when water system and lighting system simultaneous workings, the second optic fibre is promoted by rivers and is sent out light and sway under water, produces and dazzles beautiful illuminating effect, has improved user experience.

The rear module is provided with a plurality of filters and a filter selection means, interposed between the light source and the first coupling means, for varying the light emission colour.

The rear end module is further provided with a wireless communication module and a controller, the wireless communication module is connected with the controller and the filter selection device, the wireless communication module receives a control signal sent by the remote server and controls the filter selection device to select the filter to change the light emitting color according to the control signal, or receives the control signal sent by the remote server and sends the control signal to the controller to control the light emitting intensity.

Through adding filter selection device and filter at the rear end module to accept remote control to change the filter that the rear end module used, and then change the light of front end module and emit colour and intensity, increased the use scene of optic fibre under water lamp, improved user experience. The filter selecting device can be a disc-shaped electromechanical structure provided with the filter, and the filter selection is realized by rotating the disc.

The front-end module also comprises an objective lens used for collecting the light rays around the front-end module; the rear end module also comprises an image sensor, and the image sensor is connected with the objective lens through a first optical fiber; the image sensor receives light collected by the objective lens and generates images around the front-end module, the image sensor is connected with the controller, the controller calculates brightness values of the light around the front-end module according to the images around the front-end module, the optical fiber lamp is turned on through the controller if the brightness values around the front-end module are smaller than a preset value, and the optical fiber lamp is turned off through the controller if the brightness values around the front-end module are larger than the preset value.

The utility model has the advantages that:

the utility model discloses an optical fiber conduction is lighting system photoelectric separation under water to reach no electric shock hidden danger and have the equal illuminating effect of traditional lamp under water to the human body.

2 in the optical fiber underwater lamp lighting system, the front end module guides light for the optical fiber, and does not need to be used as a radiator to radiate heat for the LED, so that the volume and the weight of the lamp are reduced, and the working hours of installation and maintenance are reduced;

3 the utility model discloses optic fibre is lamp lighting system under water, front end module are optic fibre leaded light, are not afraid of optic fibre and intake water and influence light-emitting effect and lamps and lanterns life-span, need not to do waterproof design to cost is reduced and maintenance cost that lamps and lanterns have bad.

Claims (6)

1. A fiber optic underwater light comprising: the rear end module is connected with the front end module through a first optical fiber; wherein,

the front end module includes: the optical fiber lamp comprises an optical fiber lock head, a first optical fiber, an optical device, a face cover, toughened glass, an embedded part and a lamp body, wherein the first optical fiber is fixed on the lamp body by the optical fiber lock head;

the optical device is a reflective cup or a lens,

the back end module includes: a power supply, a light source, a first coupling device, a controller, a heat sink,

the power supply is a direct current converter, the output end of the direct current converter is connected with the light source, the first coupling device is respectively connected with the light source and the first optical fiber, and the radiator is arranged on the outer sides of the power supply and the light source;

the first optical fiber and the optical device are multiple;

the water feeding device is characterized in that a water feeding hole is reserved in the face cover and the toughened glass, the water feeding device further comprises a water feeding pipe, one end of the water feeding pipe is connected with the face cover and the toughened glass water feeding hole, and the other end of the water feeding pipe is connected with a water feeding system.

2. The underwater light as claimed in claim 1, wherein a portion of the water feeding tube is made of a transparent material and fixed to the light emitting surface of the optical device.

3. A fiber optic underwater light as claimed in claim 1 wherein the front end module further comprises a second coupling means and a second optical fiber connected to the first optical fiber by the second coupling means, the second optical fiber passing through the fill hole, the second optical fiber being a side emitting optical fiber.

4. A fiber optic underwater light as claimed in claim 1 wherein the rear module is provided with a plurality of filters and filter selection means interposed between the light source and the first coupling means for varying the color of the light emitted.

5. The fiber optic underwater light of claim 1, wherein the rear module is further provided with a wireless communication module and a controller, the wireless communication module is connected with the controller and the filter selection device, and the wireless communication module receives a control signal sent by the remote server and controls the filter selection device to select the filter according to the control signal to change the light emitting color, or receives a control signal sent by the remote server and sends the control signal to the controller to control the light emitting intensity.

6. The fiber optic underwater light of claim 1, wherein the front end module further comprises an objective lens for collecting light around the front end module; the rear end module also comprises an image sensor, and the image sensor is connected with the objective lens through a first optical fiber; the image sensor receives light collected by the objective lens and generates images around the front-end module, the image sensor is connected with the controller, the controller calculates brightness values of the light around the front-end module according to the images around the front-end module, the optical fiber lamp is turned on through the controller if the brightness values around the front-end module are smaller than a preset value, and the optical fiber lamp is turned off through the controller if the brightness values around the front-end module are larger than the preset value.