CN218064736U - Energy-saving LED illuminating lamp - Google Patents

Abstract

The application discloses an energy-saving LED illuminating lamp which comprises a shell, a lamp bead assembly, a reflecting cover and an adjusting mechanism, wherein the lamp bead assembly, the reflecting cover and the adjusting mechanism are arranged in the shell; the reflecting cover is arranged on the side part of the lamp bead component, a reflecting angle is formed between the reflecting cover and the lamp bead component, and the reflecting cover is suitable for reflecting and concentrating light rays emitted by the lamp bead component through the reflecting angle; the adjusting mechanism is suitable for being matched with the lamp bead assembly or the reflecting shade; when entering the energy-saving mode, adjustment mechanism is suitable for adjusting the reflection angle between lamp pearl subassembly and the reflector. The beneficial effect of this application: when the illuminating lamp enters an energy-saving mode, part of the lamp beads of the lamp bead assembly are extinguished; at the moment, the reflection angle between the lamp bead assembly and the reflector can be adjusted through the adjusting mechanism; further, the brightness of the illumination is improved by reducing the projection range of the illumination lamp; therefore, energy is saved, and meanwhile, the brightness projected by the illuminating lamp is kept to meet the use requirements of users, so that the use experience of the users is improved.

Description

Energy-saving LED illuminating lamp

Technical Field

The application relates to the field of lighting lamps, in particular to a lighting lamp.

Background

A lighting lamp is a commonly used lighting tool. The existing illuminating lamp generally adopts LED lamp beads and combines a reflecting cover to realize the concentrated irradiation of light beams so as to realize the purpose of energy conservation. Moreover, the existing illuminating lamp generally divides different working modes according to the lighting quantity of the LED lamp beads.

In the existing illuminating lamp, the installation angles of a reflecting cover and an LED lamp bead are fixed. When the light entered into energy-saving mode, partial LED lamp pearl was extinguish for the light intensity of light in original irradiation range reduces, and then influences user's use and experiences.

SUMMERY OF THE UTILITY MODEL

One of the objects of the present application is to provide an energy-saving LED illumination lamp capable of maintaining illumination intensity of the illumination lamp in an energy-saving mode.

In order to achieve the purpose, the technical scheme adopted by the application is as follows: an energy-saving LED illuminating lamp comprises a shell, and a lamp bead assembly, a reflecting cover and an adjusting mechanism which are arranged in the shell; the reflecting cover is arranged on the side part of the lamp bead component, a reflecting angle is formed between the reflecting cover and the lamp bead component, and the reflecting cover is suitable for reflecting and concentrating light rays emitted by the lamp bead component through the reflecting angle; the adjusting mechanism is suitable for being matched with the lamp bead assembly or the reflecting shade; when the lamp enters the energy-saving mode, the adjusting mechanism is suitable for adjusting the reflection angle between the lamp bead assembly and the reflector, and then the illumination brightness can be improved by reducing the irradiation range of the lamp bead assembly under the condition that the lamp bead assembly is partially extinguished.

Preferably, the lamp bead assembly is fixedly installed in the shell, and the adjusting mechanism is matched with the reflecting shade; when the reflector enters the energy-saving mode, the adjusting mechanism is suitable for changing the taper of the reflector so as to adjust the reflection angle.

Preferably, the lamp bead assembly is slidably mounted on the housing; the reflector is fixedly arranged on the shell and is arranged at intervals with the lamp bead assembly; the adjusting mechanism is matched with the lamp bead assembly; when the reflector enters an energy-saving mode, the adjusting mechanism is suitable for driving the lamp bead assembly to move, and then the reflecting angle is adjusted by changing the distance between the lamp bead assembly and the reflector.

Preferably, the lamp bead assembly is slidably mounted on the housing, and the reflector is matched with the lamp bead assembly; the adjusting mechanism is connected with the lamp bead assembly in a matching manner; when the reflector enters an energy-saving mode, the adjusting mechanism is suitable for driving the lamp bead assembly to move, and simultaneously changes the taper of the reflector, so that the reflection angle can be adjusted.

Preferably, the reflector comprises a plurality of reflectors annularly arranged around the reflector, and the reflectors are obliquely hinged to the side of the irradiation end of the shell to form a tapered reflecting structure with adjustable taper; when the reflector enters an energy-saving mode, the reflector is suitable for synchronous deflection around the hinged position under the extrusion of the adjusting mechanism or the lamp bead assembly, and then the taper of the reflecting structure is changed.

Preferably, the light reflecting plates are connected with the shell through torsion springs, so that the light reflecting plates abut against the lamp bead assemblies or the adjusting mechanisms under the elasticity of the torsion springs; when the reflector enters the energy-saving mode, the reflector abuts against the lamp bead assembly or the adjusting mechanism around the hinged position under the elastic force of the torsion spring through the movement of the lamp bead assembly or the adjusting mechanism.

Preferably, the back of the reflector is provided with a first magnetic part; a second magnetic part is arranged on the side part of the lamp bead component or the adjusting mechanism; the reflector abuts against the lamp bead assembly or the adjusting mechanism under the magnetic attraction of the first magnetic part and the second magnetic part; when the reflector enters the energy-saving mode, the reflector is enabled to abut against the deflection of the lamp bead assembly or the adjusting mechanism around the hinged position under the magnetic attraction by the movement of the lamp bead assembly or the adjusting mechanism.

Preferably, the reflectors are rectangular; the reflector comprises a group of first reflectors and a group of second reflectors which are equal in number; the first reflector and the second reflector are distributed at equal intervals in the circumference, and the distance between every two adjacent first reflectors is smaller than the width of the second reflector; the second light reflecting plates are correspondingly arranged between the adjacent first light reflecting plates and are respectively attached to the back parts of the adjacent first light reflecting plates; and then in the process that the reflector deflects, the adjacent reflectors are always attached to each other.

Preferably, the adjusting mechanism comprises an actuator and an adjusting disc; the adjusting disc is in sliding fit with the shell, and the side part of the adjusting disc is matched with the reflector; the actuator is fixedly arranged on the shell and is connected with the adjusting disc; when the energy-saving mode is entered, the actuator is suitable for driving the adjusting disc to move, and then the reflector panel deflects around the hinge joint position under the extrusion of the adjusting disc.

Preferably, the adjustment mechanism comprises an actuator; the actuator is connected with the lamp bead assembly; when the energy-saving mode is entered, the actuator is suitable for driving the lamp bead assembly to move, and the reflector is extruded by the lamp bead assembly to deflect around the hinged position.

Compared with the prior art, the beneficial effect of this application lies in:

when the illuminating lamp enters an energy-saving mode, part of the lamp beads of the lamp bead assembly are extinguished; at the moment, the reflecting angle between the lamp bead assembly and the reflecting cover can be adjusted through the adjusting mechanism; further, the brightness of the illumination is improved by reducing the projection range of the illumination lamp; therefore, energy is saved, and meanwhile, the brightness projected by the illuminating lamp is kept to meet the use requirements of users, so that the use experience of the users is improved.

Drawings

Fig. 1 is a schematic view of the overall structure of one embodiment of the present invention.

Fig. 2 is an exploded view of one embodiment of the present invention.

Fig. 3 is a schematic structural diagram of a reflector according to one embodiment of the present invention.

Fig. 4 is a schematic structural diagram of a reflector in one embodiment of the present invention.

Fig. 5 is a schematic structural diagram of an adjusting disk according to one embodiment of the present invention.

Fig. 6 is a schematic structural view of a lamp bead assembly in one embodiment of the present invention.

Fig. 7 is a schematic structural view of a lamp bead assembly in another embodiment of the present invention.

Fig. 8 is a cross-sectional view of one embodiment of the present invention.

Fig. 9 is a cross-sectional view of another embodiment of the present invention.

Fig. 10 is a cross-sectional view of yet another embodiment of the present invention.

In the figure: the LED lamp comprises a shell 100, a sliding rod 110, a lamp bead assembly 2, a mounting disc 21, an LED lamp bead 200, a connecting rod 22, a sliding sleeve 23, a reflector 3, a first reflector 31, a second reflector 32, a first magnetic part 301, an adjusting mechanism 4, an actuator 41, a controller 42, an adjusting disc 43, a connecting part 400, a guide hole 430 and a second magnetic part 431.

Detailed Description

The present application is further described below with reference to specific embodiments, and it should be noted that, without conflict, any combination between the embodiments described below or between the technical features may form a new embodiment.

In the description of the present application, it should be noted that, for the terms of orientation, such as "central", "lateral", "longitudinal", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc., indicate orientations and positional relationships based on the orientations or positional relationships shown in the drawings, which are only for convenience of description and simplification of the description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and should not be construed as limiting the specific scope of the present application.

It is noted that the terms first, second and the like in the description and in the claims of the present application are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order.

In one preferred embodiment of the present application, as shown in fig. 1 to 10, an energy-saving LED lighting lamp includes a housing 100, and a lamp bead assembly 2, a reflector 3 and an adjusting mechanism 4 installed in the housing 100. The lamp bead assembly 2 is installed at the irradiation end of the illumination lamp to be used for emitting illumination light. The reflector 3 is arranged on the side part of the lamp bead component 2, and the reflector 3 can reflect the illuminating light emitted by the lamp bead component 2 through a reflection angle formed between the reflector 3 and the lamp bead component 2, so that the light emitted by the lamp bead component 2 is intensively irradiated to improve the irradiation brightness. The adjusting mechanism 4 can be matched with the lamp bead component 2 or the reflecting shade 3; thereby when getting into energy-conserving mode, adjustment mechanism 4 can adjust the reflection angle between lamp pearl subassembly 2 and reflector 3, and then can be under the condition that lamp pearl subassembly 2 part was gone out, improve illumination brightness through the irradiation range who reduces lamp pearl subassembly 2.

It can be understood that when the existing illuminating lamp is used, the illuminating range of light is large, and the night use can be fully met. However, depending on the usage habits of the user and the usage environment, a large illumination range and low illumination brightness may be required; sometimes, it is necessary to ensure that the illumination brightness is sufficient, and the illumination range is not high. The energy-saving mode of the existing illuminating lamp basically meets the conditions of large illumination range and low brightness. Therefore, on the basis of the existing illuminating lamp, the reflecting angles of the reflecting shade 3 and the lamp bead assembly 2 are adjusted through the adjusting mechanism 4; thereby under the circumstances of lamp pearl subassembly 2 self luminance reduction, guarantee the illumination luminance of light unchangeably through contracting irradiation range.

In this embodiment, the adjusting mechanism 4 can adjust the reflection angle in various ways, including but not limited to the following three ways.

The method I comprises the following steps: as shown in fig. 8, the lamp bead assembly 2 is fixedly installed in the housing 100, and the adjusting mechanism 4 is matched with the reflector 3. Therefore, when the reflector enters the energy-saving mode, the adjusting mechanism 4 can directly change the taper of the reflector 3, and further adjust the reflection angle.

The second method comprises the following steps: as shown in fig. 9, the lamp bead assembly 2 is slidably mounted in the housing 100; the reflecting shade 3 is fixedly arranged on the shell 100, and the reflecting shade 3 and the lamp bead assembly 2 are arranged at intervals; adjustment mechanism 4 and lamp pearl subassembly 2 cooperate. Thereby when getting into energy-conserving mode, adjustment mechanism 4 can drive lamp pearl subassembly 2 and remove, and then through changing the distance between lamp pearl subassembly 2 and the reflector 3 to carry out the regulation of reflection angle.

The third method comprises the following steps: as shown in fig. 10, the lamp bead assembly 2 is slidably mounted on the housing 100; the reflector 3 is matched with the lamp bead assembly 2; simultaneously, adjustment mechanism 4 and lamp pearl subassembly 2 cooperate and are connected. Thereby when getting into energy-conserving mode, adjustment mechanism 4 can drive lamp pearl subassembly 2 and remove to at the in-process that lamp pearl subassembly 2 removed, through lamp pearl subassembly 2 and reflector 3's cooperation, can change reflector 3's tapering, and then can adjust reflection angle.

It will be appreciated that the first is primarily to adjust the taper of the reflector 3 itself; the second mode is mainly that the distance between the lamp bead assembly 2 and the reflecting shade 3 is adjusted; mode three mainly is when adjusting the distance between lamp pearl subassembly 2 and the reflector 3, can also adjust the tapering of reflector 3 self. Specifically, the skilled person can select which way to use according to actual needs.

In one embodiment of the present application, as shown in fig. 2 and 3, the reflector 3 includes a plurality of reflectors annularly arranged around the reflector; the reflectors are obliquely hinged to the side of the irradiation end of the housing 100 to form a tapered reflector structure with adjustable taper. Thus, when the reflector enters the energy-saving mode, the reflector realizes the change of the taper of the reflecting structure through the synchronous deflection around the hinged position.

It is understood that the structure of the reflector 3 is applicable to the first and third modes described above. When the reflector is applied to the mode one, the reflector can be propped against the adjusting mechanism 4, and then when the reflector enters the energy-saving mode, the reflector can synchronously deflect around the hinged position under the extrusion of the adjusting mechanism 4. When being applied to mode three, the reflector panel can offset in the lateral part of lamp pearl subassembly 2, and then when getting into energy-conserving mode, the reflector panel can be around the synchronous deflection of articulated position under lamp pearl subassembly 2's extrusion.

Meanwhile, the specific number of the reflectors can be set according to actual needs. For example, as shown in fig. 3, the number of the light reflection plates is sixteen.

In this embodiment, in the process of deflecting the reflector, in order to ensure normal use of the reflector 3, the reflector must always abut against the adjusting mechanism 4 or the lamp bead assembly 2. There are various reflector mounting structures satisfying this condition, including but not limited to the following two.

The mounting structure I is as follows: as shown in fig. 8 and 10, the light reflecting plate is connected to the housing 100 through a torsion spring, so that the light reflecting plate abuts against the lamp bead assembly 2 or the adjusting mechanism 4 under the elastic force of the torsion spring. Therefore, when the reflector enters an energy-saving mode, the reflector can always abut against the lamp bead component 2 or the adjusting mechanism 4 to deflect around the hinged position under the elasticity of the torsion spring through the moving extrusion of the lamp bead component 2 or the adjusting mechanism 4.

And a second mounting structure: as shown in fig. 4, 5, 8 and 10, the back of the reflector is provided with a first magnetic part 301; a second magnetic part 431 is arranged on the side part of the lamp bead component 2 or the adjusting mechanism 4; the reflector is pressed against the lamp bead assembly 2 or the adjusting mechanism 4 under the magnetic attraction of the first magnetic part 301 and the second magnetic part 431. Therefore, when the reflector enters an energy-saving mode, the reflector can always abut against the lamp bead component 2 or the adjusting mechanism 4 to deflect around the hinged position under the magnetic attraction by moving and extruding the lamp bead component 2 or the adjusting mechanism 4.

In the present embodiment, as shown in fig. 2 to 4, the reflector is preferably rectangular. The reflector comprises a set of first reflectors 31 and a set of second reflectors 32 in equal numbers. The first reflector 31 and the second reflector 31 are circumferentially distributed at equal intervals, and a distance exists between adjacent first reflectors 31, and the value of the distance is smaller than the width of the second reflector 32. The second light reflecting plates 32 are correspondingly arranged between the adjacent first light reflecting plates 31 and are respectively attached to the back parts of the adjacent first light reflecting plates 31; and then in the process that the reflector panel deflects, adjacent reflector panels are always attached to each other.

It can be understood that, when entering the energy saving mode, the reflector 3 needs to increase the taper, that is, the opening of the reflector 3 far from the irradiation end needs to be increased, to ensure that the reflected light is more concentrated. The increase of the opening of the reflector 3 far away from the irradiation end can be embodied as that the end parts of the reflector far away from the hinged position are far away from each other; and then through the reflector panel of rectangle structure, can guarantee that the reflector panel keeps away from the in-process that the tip of articulated position was keeping away from each other, be in continuous laminating state between the adjacent reflector panel all the time. Therefore, the situation that gaps appear between adjacent reflectors in the adjusting process of the reflector 3 can be avoided. Of course, the structure of the reflector is not limited to the rectangular structure, and other structures may be used as long as the above functions are satisfied.

Specifically, as shown in fig. 3, fig. 8 and fig. 10, the adjusting mechanism 4 or the lamp bead assembly 2 may be in abutting fit with the first reflector 31, so that in the process of adjusting the reflection angle, the adjusting mechanism 4 or the lamp bead assembly 2 drives the first reflector 31 and the second reflector 32 to synchronously deflect around the hinge position by squeezing the first reflector 31.

In the present application, the specific structure of the adjustment mechanism 4 is different depending on the adjustment mode of the reflection angle.

For the first mode: as shown in fig. 2 and 8, the adjustment mechanism 4 includes an actuator 41 and an adjustment disk 43. The adjusting disk 43 is in sliding fit with the housing 100, and the side of the adjusting disk 43 is in abutting fit with the reflector. The actuator 41 is fixedly mounted to the housing 100 and is connected to the adjustment plate 43. When the energy-saving mode is entered, the actuator 41 can drive the adjusting disk 43 to move, and the reflector deflects around the hinge position under the extrusion of the adjusting disk 43.

Specifically, as shown in fig. 5, 6 and 8, the lamp bead assembly 2 is fixedly connected with the housing 100 through the connecting rod 22; the adjusting plate 43 is slidably engaged with the connecting rod 22 through the guiding hole 430, and the first reflective plate 31 is engaged with the side wall of the adjusting plate 43. Thus, when entering the energy saving mode, the actuator 41 can drive the adjusting disc 43 to move axially along the connecting rod 22, so as to drive the second reflector 32 to synchronously deflect around the hinge position by pressing the first reflector 31.

It can be understood that, when the reflector adopts the second mounting structure described above, the second magnetic part 431 is disposed at the side of the adjustment disc 43.

For the second mode: as shown in fig. 9, the adjustment mechanism 4 includes an actuator 41; the actuator 41 is connected with the lamp bead assembly 2. Therefore, when entering the energy saving mode, the actuator 41 can drive the lamp bead assembly 2 to move.

Specifically, as shown in fig. 7 and 9, the lamp bead assembly 2 is slidably engaged with a sliding rod 110 fixedly disposed in the housing 100 through a sliding sleeve 23. Therefore, when entering the energy saving mode, the actuator 41 can drive the lamp bead assembly 2 to move along the axial direction of the sliding rod 110, and further move towards the direction close to the reflector 3, so as to adjust the reflection angle.

For mode three: as shown in fig. 10, the adjustment mechanism 4 includes an actuator 41; the actuator 41 is connected with the lamp bead assembly 2. Thus, when entering the energy saving mode, the actuator 41 can drive the lamp bead assembly 2 to move, and the reflector is extruded by the lamp bead assembly 2 to deflect around the hinge position.

Specifically, as shown in fig. 7 and 10, the lamp bead assembly 2 is in sliding fit with a sliding rod 110 fixedly arranged in the housing 100 through a sliding sleeve 23; meanwhile, the side wall of the lamp bead component 2 is in abutting fit with the first reflector panel 31. When entering the energy saving mode, the actuator 41 can drive the lamp bead assembly 2 to move along the axial direction of the sliding rod 110. And at the in-process that lamp pearl subassembly 2 removed, lamp pearl subassembly 2 can drive second reflector panel 32 through the first reflector panel 31 of extrusion and carry out the deflection around articulated position in step.

It will be appreciated that the actuator 41 is specifically constructed in the prior art, and typically employs a motor. Meanwhile, the mode that the actuator 41 drives the lamp bead assembly 2 or the adjusting disc 43 to move is also the prior art, and generally adopts a threaded connection or a screw rod connection mode. Set up connecting portion 400 on lamp pearl subassembly 2 or adjustment disk 43 promptly, the output of executor 41 carries out threaded connection or lead screw through output shaft and connecting portion 400 and is connected, and then drives lamp pearl subassembly 2 or adjustment disk 43 through the rotation of executor 41 drive output shaft and move.

In one embodiment of the present application, as shown in fig. 6 and 7, the lamp bead assembly 2 includes a circular mounting plate 21 and a plurality of groups of LED lamp beads 200 fixedly mounted on the mounting plate 21 in an annular shape. The radial equidistance setting in proper order of mounting disc 21 is followed to multiunit LED lamp pearl 200. When the lamp enters the energy-saving mode, one or more groups of LED lamp beads 200 positioned outside the mounting disc 21 can be turned off; or part of the LED lamp beads 200 in each group are turned off.

In this embodiment, as shown in fig. 6 to 10, the connecting portion 400 and the connecting rod 22 or the sliding sleeve 23 may be fixedly disposed on the back of the mounting plate 21, i.e., on the side away from the irradiation end. Meanwhile, when the second mounting structure is adopted for the reflector, the second magnetic portion 431 is provided at a side portion of the mounting plate 21.

In this embodiment, as shown in fig. 2 and fig. 8 to fig. 10, the adjusting mechanism 4 further includes a controller 42, and the controller 42 is electrically connected to the LED lamp bead 200 and the actuator 41, so that when entering the energy saving mode, the controller 42 can control the LED lamp bead 200 to be partially turned off, and at the same time, can control the actuator 41 to drive the adjusting plate 43 or the mounting plate 21 to move.

It is understood that the specific structure of the controller 42 is conventional and will not be described in detail herein.

The foregoing has described the principles, principal features, and advantages of the application. It will be understood by those skilled in the art that the present application is not limited to the embodiments described above, which are merely illustrative of the principles of the application, but that various changes and modifications may be made without departing from the spirit and scope of the application, and such changes and modifications are intended to be within the scope of the application as claimed. The scope of protection claimed by this application is defined by the following claims and their equivalents.

Claims (10)

1. An energy-saving LED illuminating lamp is characterized by comprising:

a housing; and mounted to the housing:

the lamp bead component is used for emitting illumination light;

the reflecting cover is positioned on the side part of the lamp bead assembly; a reflection angle is formed between the reflection cover and the lamp bead assembly, and the reflection cover is suitable for reflecting and concentrating light rays emitted by the lamp bead assembly through the reflection angle;

the adjusting mechanism is suitable for being matched with the lamp bead assembly or the reflecting shade; the adjustment mechanism is adapted to adjust the reflection angle when entering the power saving mode.

2. The energy-saving LED illuminating lamp according to claim 1, characterized in that: the lamp bead assembly is fixedly arranged in the shell, and the adjusting mechanism is matched with the reflecting cover;

when the reflector enters the energy-saving mode, the adjusting mechanism is suitable for changing the taper of the reflector, so that the reflecting angle can be adjusted.

3. The energy-saving LED illuminating lamp according to claim 1, characterized in that: the lamp bead assembly is slidably mounted on the shell; the reflector is fixedly arranged on the shell and is arranged at intervals with the lamp bead assembly; the adjusting mechanism is matched with the lamp bead component;

when the reflector enters an energy-saving mode, the adjusting mechanism is suitable for driving the lamp bead assembly to move, and then the reflecting angle is adjusted by changing the distance between the lamp bead assembly and the reflector.

4. The energy-saving LED lighting lamp according to claim 1, wherein: the lamp bead assembly is slidably mounted on the shell, and the reflector is matched with the lamp bead assembly; the adjusting mechanism is connected with the lamp bead component in a matching manner;

when the lamp enters the energy-saving mode, the adjusting mechanism is suitable for driving the lamp bead assembly to move, and simultaneously changes the taper of the reflecting cover, so that the reflecting angle can be adjusted.

5. The energy-saving LED illuminating lamp according to claim 2 or 4, wherein: the reflector comprises a plurality of reflectors annularly arranged in a surrounding manner; the light reflecting plates are obliquely hinged on the side part of the irradiation end of the shell to form a conical light reflecting structure with adjustable taper;

when the reflector enters an energy-saving mode, the reflector is suitable for synchronous deflection around the hinged position under the extrusion of the adjusting mechanism or the lamp bead assembly, and then the taper of the reflecting structure is changed.

6. The energy-saving LED illuminating lamp according to claim 5, characterized in that: the light reflecting plates are connected with the shell through torsion springs, so that the light reflecting plates abut against the lamp bead assemblies or the adjusting mechanism under the elasticity of the torsion springs;

when the reflector enters the energy-saving mode, the reflector abuts against the lamp bead assembly or the adjusting mechanism around the hinged position under the elastic force of the torsion spring through the movement of the lamp bead assembly or the adjusting mechanism.

7. The energy-saving LED illuminating lamp according to claim 5, characterized in that: the back of the reflector is provided with a first magnetic part; a second magnetic part is arranged on the side part of the lamp bead component or the adjusting mechanism; the reflector abuts against the lamp bead assembly or the adjusting mechanism under the magnetic attraction of the first magnetic part and the second magnetic part;

when the reflector enters the energy-saving mode, the reflector is enabled to abut against the deflection of the lamp bead assembly or the adjusting mechanism around the hinged position under the magnetic attraction by the movement of the lamp bead assembly or the adjusting mechanism.

8. The energy-saving LED illuminating lamp according to claim 5, characterized in that: the light reflecting plates are all rectangular; the reflector comprises a group of first reflectors and a group of second reflectors which are equal in number; the first reflector and the second reflector are distributed at equal intervals in the circumference, and the distance between every two adjacent first reflectors is smaller than the width of the second reflector; the second light reflecting plates are correspondingly arranged between the adjacent first light reflecting plates and are respectively attached to the back parts of the adjacent first light reflecting plates; and then in the process that the reflector deflects, the adjacent reflectors are always attached to each other.

9. The energy-saving LED lighting lamp according to claim 5, wherein: the adjusting mechanism comprises an actuator and an adjusting disc; the adjusting disc is in sliding fit with the shell, and the side part of the adjusting disc is matched with the reflector; the actuator is fixedly arranged on the shell and is connected with the adjusting disc;

when the energy-saving mode is entered, the actuator is suitable for driving the adjusting disc to move, and then the reflector deflects around the hinge joint position under the extrusion of the adjusting disc.

10. The energy-saving LED lighting lamp according to claim 5, wherein: the adjustment mechanism comprises an actuator; the actuator is connected with the lamp bead assembly;

when the energy-saving mode is entered, the actuator is suitable for driving the lamp bead assembly to move, and the reflector is extruded by the lamp bead assembly to deflect around the hinged position.

Images