CN109990236B - Mirror lamp - Google Patents

Abstract

The invention relates to a mirror lamp, which comprises a ox horn bracket with a built-in power line and a mirror frame made of metal, wherein two ends of the mirror frame are respectively hinged on two ends of the ox horn bracket through a conductive component so that the mirror frame can rotate 360 degrees around the conductive component; the LED mirror is characterized in that a mirror is arranged on at least one of two end faces of the mirror frame, a light-emitting part is arranged on the periphery of the mirror, and an LED lamp strip for providing a light source for the light-emitting part is arranged on the inner side wall of the mirror frame. The device can freely rotate by 360 degrees, has good luminous flux and good use experience.

Description

Mirror lamp

Technical Field

The invention relates to the field of lighting equipment, in particular to a mirror lamp.

Background

The mirror lamp is an emerging industry in the field of LED illumination, perfectly combines the functions of LED illumination and a mirror, has a wide market, and is deeply favored by people.

Mirror lamps on the market today have mainly two drawbacks, one: the light source is arranged in the mirror, and a radiator is additionally arranged in the mirror, so that the radiating effect is poor, the light loss is extremely large, reflection and scattering can be generated due to the fact that light waves are transmitted in media, and the attenuation of light waves with different degrees is caused due to the fact that two different media of glass and metal exist in the mirror frame at the same time, so that the light passing of the whole lamp cannot meet the requirement, and the light effect cannot meet the requirement; the second disadvantage is that the product capable of realizing the rotation of the mirror 360 is realized by the cooperation of the electrode and the spring, but because the electrode is limited by the structural design, the electrode is larger in size, the external power supply and the internal radiator are connected by the electrode, so that the light-emitting part of the mirror can see obvious power line shadows when the mirror does not emit light, obvious dark spots exist when the mirror emits light, and the mirror is not accepted by a user, as shown in fig. 1.

Disclosure of Invention

In view of the above, it is necessary to provide a mirror lamp capable of 360 ° rotation, good in heat dissipation performance, and excellent in light emitting effect.

In order to solve the technical problems, the technical scheme of the invention is as follows: the mirror lamp comprises a ox horn bracket with a built-in power line and a mirror frame made of metal, wherein two ends of the mirror frame are respectively hinged to two ends of the ox horn bracket through a conductive component so that the mirror frame can rotate 360 degrees around the conductive component; the LED lamp strip is characterized in that a mirror is arranged on at least one of two end faces of the mirror frame, a light-emitting part is arranged on the periphery of the mirror, an LED lamp strip for providing a light source for the light-emitting part is arranged on the inner side wall of the mirror frame, one end of the conductive component is electrically connected with a power line, and the other end of the conductive component is electrically connected with the anode or the cathode of the LED lamp strip.

Further, the conductive assembly comprises a plastic screw penetrating through the side wall of the lens frame from inside to outside, a conductive probe, a nut female end of the locking screw outside the lens frame, a nut male end fixedly arranged at the end part of the ox horn and one end of which is embedded into the nut female end, and a copper cap embedded into the nut male end, wherein a through hole for the probe to penetrate through is formed in the screw, the inner end of the probe is electrically connected with the anode or the cathode of the LED light bar, the outer end of the probe is propped against the inner end of the copper cap to realize electrical connection, and the outer end of the copper cap is electrically connected with a power line.

Further, the probe comprises a metal sleeve and a metal ejector rod arranged in the sleeve, and a spring is arranged between the sleeve and the ejector rod.

Further, a plastic sleeve is arranged in the male end of the nut, and the copper cap is embedded in the plastic sleeve.

Further, the inner end of the copper cap is provided with a groove for accommodating the outer end part of the probe.

Further, a light diffusion cover is arranged between the mirror frame and the mirror, the light diffusion cover comprises a barrel body encircling the outer side wall of the mirror and annular side walls arranged at two ends of the barrel body, the two side walls respectively correspond to the light-emitting parts on the mirror frame, and the barrel body is arranged opposite to the LED lamp strip.

Further, reflective paper is attached to the outer side wall of the cylinder.

Further, the ox horn support bottom is detachably provided with the cavity pillar, and the pillar bottom is provided with the base.

Further, a chargeable storage battery electrically connected with the power line and a MicroUSB interface for charging the storage battery are arranged in the base, and a switch for controlling the on-off of the LED lamp strip is arranged outside the base.

Further, the mirror frame is an aluminum frame.

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

firstly, a light source is placed on the inner wall of an aluminum outer frame of the mirror, so that the heat dissipation performance of the aluminum frame is fully utilized, and the heat dissipation problem is solved;

secondly, a connection mode of a probe is adopted, one elastic end is contacted with a copper cap in the ox horn bracket, and the other end is electrically connected with a light source on the inner wall of the aluminum frame, so that the problems of power line shadow and luminous dark spots are avoided as the mirror does not need to extend into the mirror;

thirdly, in order to reduce light loss, improve light transmission and achieve good light-emitting effect, optical treatment is carried out on the light-emitting part of the mirror, a light diffusion PC cover and reflective paper are added, the light-emitting effect is more uniform by utilizing the diffusion characteristic of the light diffusion plate, meanwhile, light rays striking the inside of the mirror are reflected by utilizing the reflection characteristic of the reflective paper, and the light transmission and brightness are improved;

fourth, this device can realize 360 degrees rotations accessible of mirror lamp, and luminous even to and the outward appearance is perfect, with low costs, simple to operate.

The foregoing and other objects, features and advantages of the invention will be apparent from the following more particular description of preferred embodiments, as illustrated in the accompanying drawings.

Drawings

Fig. 1 is a diagram showing the luminous effect of the prior art product.

Fig. 2 is a schematic structural diagram of an embodiment of the present invention.

Fig. 3 is an exploded view of an embodiment of the present invention.

Fig. 4 is a schematic structural diagram of a conductive component according to an embodiment of the invention.

FIG. 5 is a schematic view of a light diffusing mask according to an embodiment of the present invention.

FIG. 6 is a schematic diagram of a probe according to an embodiment of the present invention.

Fig. 7 is a diagram showing a lighting effect according to an embodiment of the present invention.

In the figure: 1-mirror frame, 11-mirror, 12-light emitting part, 2-ox horn support, 3-conductive component, 31-probe, 311-sleeve, 312-ejector rod, 32-screw, 33-nut female end, 34-copper cap, 35-plastic sleeve, 36-nut male end, 4-pillar, 5-base, 51-battery, 52-micro USB interface, 53-upper cover, 54-chassis, 55-switch, 56-chassis, 6-light diffusion cover, 61-cylinder, 62-1:10 mirror side wall, 63-1:1 mirror side wall.

Detailed Description

In order to further describe the technical means and effects adopted by the present invention for achieving the intended purpose, the following detailed description will refer to the specific implementation, structure, characteristics and effects according to the present invention with reference to the accompanying drawings and preferred embodiments.

As shown in fig. 2 to 7, a mirror lamp comprises a ox horn bracket 2 with a built-in power line and a mirror frame 1 made of metal, wherein two ends of the mirror frame are respectively hinged on two ends of the ox horn bracket through a conductive component 3 so that the mirror frame can rotate 360 degrees around the conductive component; the LED lamp strip is characterized in that the two end faces of the mirror frame are respectively provided with a mirror 11, one face is a 1:10 mirror, the other face is a 1:1 mirror, the periphery side of the mirror is provided with a light-emitting part 12, the inner side wall of the mirror frame is provided with an LED lamp strip for providing a light source for the light-emitting part, one end of the conductive component is electrically connected with a power line, and the other end of the conductive component is electrically connected with the anode or the cathode of the LED lamp strip.

In this embodiment, the conductive component includes a plastic screw 32 penetrating through the side wall of the lens frame from inside to outside, a conductive probe 31, a nut female end 33 locking the screw outside the lens frame, a nut male end 36 fixed at the end of the ox horn and having one end embedded in the nut female end, and a copper cap 34 embedded in the nut male end, the screw is provided with a through hole for the probe to penetrate through, the inner end of the probe is electrically connected with the positive electrode or the negative electrode of the LED light bar, the outer end abuts against the inner end of the copper cap to realize electrical connection, and the outer end of the copper cap is electrically connected with the power line.

In this embodiment, the probe includes a metal sleeve 311 and a metal push rod 312 disposed in the sleeve, and a spring is disposed between the sleeve and the push rod.

In this embodiment, a plastic sleeve is disposed in the male end of the nut, which has an insulating effect, and the copper cap is embedded in the plastic sleeve 35.

In this embodiment, the inner end of the copper cap is provided with a groove for accommodating the outer end of the probe. The absolute contact between the probe and the copper cap is ensured, and the separation of the probe and the copper cap is avoided.

In this embodiment, a light diffusion cover 6 is disposed between the mirror frame and the mirror, the light diffusion cover includes a cylinder 61 surrounding the outer side wall of the mirror and annular side walls (including side walls 62 corresponding to 1:10 mirrors and side walls 63 corresponding to 1:1 mirrors) disposed at two ends of the cylinder, the two side walls respectively correspond to the light emitting portions on the mirror frame, and the cylinder is disposed opposite to the LED light bars.

In this embodiment, a reflective paper is attached to the outer sidewall of the cylinder.

In this embodiment, ox horn support bottom detachable is provided with cavity pillar 4, and the pillar bottom is provided with base 5.

In this embodiment, the inside of the ox horn bracket and the inside of the pillar are both provided with channels through which the power cord passes.

In this embodiment, the base includes an upper cover 53, a bottom frame 54, and a bottom plate 56 sequentially disposed from top to bottom.

In this embodiment, a rechargeable battery 51 electrically connected to the power cord and a micro usb interface 52 for charging the battery are disposed in the base, and a switch 55 for controlling the on/off of the LED light bar is disposed outside the base.

In this embodiment, the frame is an aluminum frame. And the heat dissipation is convenient.

One end of the probe is welded on a light source on the inner wall of the aluminum frame, the other end of the probe penetrates out of the plastic screw, the female ends of the plastic screw and the nut are matched and locked on the aluminum frame, the inner end and the outer end of the aluminum frame are respectively connected with positive and negative 2 electrodes of the LED light bar by power wires. The male end of the nut and the top of the bracket are welded together. The power cord is worn out from the passageway of ox horn support, and 2 limit respectively. Forming positive and negative 2 electrodes at the input end of the light source. During assembly, the probe is compressed by utilizing the characteristics of the spring in the probe, the copper cap is installed in the male end of the inner nut, and after the support and the mirror are installed, the probe ejector rod stretches to be contacted with the groove of the copper cap, so that the conductive effect is achieved. Then respectively connecting the positive electrode and the negative electrode of the light source with 2 electrodes. 360 degrees of rotation of the mirror frame is completed by the cooperation of the nut female end and the nut male end. The assembly method ensures that the mirror contacts well when rotating 360 degrees, and solves the problem of difficult assembly.

The LED light source is attached to the inner wall of the aluminum frame, is at least 1mm away from the two mirror surfaces, and cannot be placed in the light-emitting area of the mirror. A light diffusion cover is added inside the light emitting area of the mirror, namely, between the two mirrors. The cambered surface side wall of the light diffusion cover corresponds to a 1:10 mirror, the plane side wall corresponds to a 1:1 mirror, and the outer side wall of the middle cylinder body is provided with reflective paper. The light is emitted from the light source, one part of the light is diffused from the two side walls to illuminate the light-emitting part, and the other part of the light reaches the inside of the mirror, so that the light is reflected back after reaching the light-reflecting paper due to the fact that the light-reflecting paper is added, and the light is continuously diffused from the two side walls, so that the light loss is greatly reduced.

The present invention is not limited to the above embodiments, but is capable of modification and variation in detail, and other modifications and variations can be made by those skilled in the art without departing from the scope of the present invention.

Claims (7)

1. A mirror lamp, characterized by: the electric power line comprises a ox horn bracket with an internal power line and a metal mirror frame, wherein two ends of the mirror frame are respectively hinged to two ends of the ox horn bracket through a conductive component so that the mirror frame can rotate 360 degrees around the conductive component; a mirror is arranged on at least one of the two end surfaces of the mirror frame, a light-emitting part is arranged on the periphery of the mirror, an LED lamp strip for providing a light source for the light-emitting part is arranged on the inner side wall of the mirror frame, one end of the conductive component is electrically connected with a power line, and the other end of the conductive component is electrically connected with the anode or the cathode of the LED lamp strip;

the conductive assembly comprises a plastic screw penetrating through the side wall of the lens frame from inside to outside, a conductive probe, a nut female end of a locking screw outside the lens frame, a nut male end fixedly arranged at the end part of the ox horn, one end of the nut male end embedded into the nut female end, and a copper cap embedded into the nut male end, wherein a through hole for the probe to penetrate through is formed in the screw, the inner end of the probe is electrically connected with the anode or the cathode of the LED lamp strip, the outer end of the probe is propped against the inner end of the copper cap to realize electrical connection, and the outer end of the copper cap is electrically connected with the power line;

the probe comprises a metal sleeve and a metal ejector rod arranged in the sleeve, and a spring is arranged between the sleeve and the ejector rod;

a plastic sleeve is arranged in the male end of the nut, and the copper cap is embedded in the plastic sleeve.

2. A mirror lamp as claimed in claim 1, wherein: the inner end of the copper cap is provided with a groove for accommodating the outer end part of the probe.

3. A mirror lamp as claimed in claim 1, wherein: the LED lamp strip comprises a mirror frame and a mirror, wherein a light diffusion cover is arranged between the mirror frame and the mirror, the light diffusion cover comprises a barrel body encircling the outer side wall of the mirror and annular side walls arranged at two ends of the barrel body, the two side walls respectively correspond to light-emitting parts on the mirror frame, and the barrel body is arranged opposite to the LED lamp strip.

4. A mirror lamp as claimed in claim 3, wherein: and reflective paper is attached to the outer side wall of the cylinder body.

5. A mirror lamp as claimed in claim 1, wherein: the ox horn support bottom is detachably provided with the cavity pillar, and the pillar bottom is provided with the base.

6. A mirror lamp as claimed in claim 5, wherein: the base is internally provided with a rechargeable storage battery electrically connected with a power line and a MicroUSB interface for charging the storage battery, and the base is externally provided with a switch for controlling the on-off of the LED lamp strip.

7. A mirror lamp as claimed in claim 1, wherein: the mirror frame is an aluminum frame.