CN219102794U - Bidirectional sliding wall lamp - Google Patents

Abstract

The utility model discloses a bidirectional sliding wall lamp, which comprises a central rotating shaft, a first rotating shaft end and a second rotating shaft end, wherein the central rotating shaft comprises a central piece, and the first rotating shaft end and the second rotating shaft end are symmetrically arranged around the center of the central piece; the first rotating shaft end and the second rotating shaft end are respectively connected with a light shielding plate. Therefore, when one of the light baffles is pushed, the first rotating shaft end is driven to move, the central rotating shaft is driven to rotate by taking the central piece as the center of a circle, and the second rotating shaft end drives the other light baffle to rotate, so that the relative positions of the light baffles are adjusted simultaneously. In addition, the bidirectional sliding wall lamp can realize the simultaneous adjustment of the relative positions of a plurality of more complex light baffles and various decorative effects by arranging the bottom plate, the shell and the transmission mechanism. Finally, through setting up chassis and second slip subassembly, realize the damping size adjustment of two-way slip wall lamp when the slip for after the facula adjustment is accomplished, two-way slip wall lamp can keep the position not remove.

Description

Bidirectional sliding wall lamp

Technical Field

The utility model relates to the field of illumination, in particular to a bidirectional sliding wall lamp.

Background

The wall lamp is an auxiliary lighting decorative lamp arranged on a wall, the core component is a light source and a shading sheet, and the shape and the size of light spots emitted by the wall lamp can be changed by arranging the shading sheet at the relative position of the light source, so that the decorative effect is achieved.

However, the wall lamp has a single structure, and the relative position of the light shielding sheet is generally fixed, so that the user cannot adjust the size of the light spot according to the change of the actual use requirement. To solve this problem, some wall lamps use a single rotating blade to change the spot size. However, according to the method, a plurality of light shielding sheets are required to be arranged for each light source, the relative positions of the light shielding sheets cannot be adjusted at the same time and can be adjusted one by one in sequence, so that the light spots of the wall lamp are inconvenient to adjust, and the use experience of a user is affected.

Disclosure of Invention

According to the first aspect of the embodiment of the utility model, the bidirectional sliding wall lamp is provided, and the relative positions of a plurality of light shielding sheets can be adjusted simultaneously.

The embodiment of the utility model provides a bidirectional sliding wall lamp, which comprises:

the central rotating shaft comprises a central piece, a first rotating shaft end and a second rotating shaft end; the first and second rotating shaft ends are symmetrically disposed about the center piece;

at least two light shielding plates; the first rotating shaft end is connected with at least one light shielding plate, and the second rotating shaft end is connected with at least one light shielding plate.

In one implementation, the bi-directional sliding wall lamp further includes a light source disposed at the center piece.

In one implementation, the bidirectional sliding wall lamp further includes at least two bottom plates, and the bottom plates are symmetrically disposed around the central member:

a rotating shaft limiting groove is formed in the bottom plate;

the bottom plate is connected with the first rotating shaft end and the second rotating shaft end through the rotating shaft limiting groove and the first sliding component respectively.

In one implementation, the bottom plates are right-angle trapezoidal, and the upper bottom edges of the two bottom plates are oppositely penetrated.

In one implementation, the bidirectional sliding wall lamp further includes at least two shells, the shells being symmetrically disposed about the central piece;

the shell is connected with the bottom plate, and the shell and the bottom plate wrap the central rotating shaft and the light shielding plate; the shape of the shell corresponds to the shape of the bottom plate;

and a light transmission area is correspondingly arranged on the shell and the position of the light shielding plate, and the light transmission area is used for transmitting light spots.

In one implementation, the housing is a right-angle trapezoid, and the upper bottom edge of the housing is arranged in a penetrating manner.

In one implementation, a transmission slot is arranged on the shell opposite to the light transmission area, and a light shielding plate moving slot is arranged below the light transmission area.

In one implementation, the bidirectional sliding wall lamp further includes at least two transmission mechanisms:

the transmission mechanism is symmetrically arranged around the central piece;

the transmission mechanism comprises a first transmission end and a second transmission end; the first transmission end is connected with the shell through the transmission clamping groove; the second transmission end is connected with the light shielding plate, and the light shielding plate is placed in the light shielding plate moving clamping groove.

In one implementation, the first driving end is a linear bearing and the second driving end is a long shaft.

In one implementation, the bidirectional sliding wall lamp further comprises a shade cloth, wherein the shade cloth comprises a first fixed end and a second fixed end, the first fixed end is connected with the shade plate, and the second fixed end is connected with the shell.

In one implementation, the bottom plate is further provided with a chassis limiting groove.

In one implementation, the bidirectional sliding wall lamp further comprises a chassis, and the chassis is connected with the bottom plate through a second sliding component.

In one implementation, the second slide assembly includes:

the inner clamping piece and the outer clamping piece are oppositely arranged, the inner clamping piece is arranged on the inner side of the bottom plate, and the outer clamping piece is arranged on the outer side of the bottom plate;

the screw and the nut are used for connecting the inner clamping piece, the bottom plate, the outer clamping piece and the chassis; the second slide assembly is for adjusting a damping amount between the base plate and the chassis.

In one implementation, the bidirectional sliding wall lamp further includes a power source disposed inside the housing.

The bidirectional sliding wall lamp has the beneficial effects that the bidirectional sliding wall lamp comprises a central rotating shaft, wherein the central rotating shaft comprises a central piece, and a first rotating shaft end and a second rotating shaft end which are symmetrically arranged around the center of the central piece; the first rotating shaft end and the second rotating shaft end are respectively connected with a light shielding plate. Therefore, when one of the light baffles is pushed, the first rotating shaft end is driven to move, the central rotating shaft is driven to rotate by taking the central piece as the center of a circle, and the second rotating shaft end drives the other light baffle to rotate, so that the relative positions of the light baffles are adjusted simultaneously. In addition, the bidirectional sliding wall lamp can realize the simultaneous adjustment of the relative positions of a plurality of more complex light baffles and various decorative effects by arranging the bottom plate, the shell and the transmission mechanism. Finally, through setting up chassis and second slip subassembly, realize the damping size adjustment of two-way slip wall lamp when the slip for after the facula adjustment is accomplished, two-way slip wall lamp can keep the position not remove.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed in the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural diagram of a bidirectional sliding wall lamp according to an embodiment of the present utility model;

fig. 2 is a schematic structural diagram of a bidirectional sliding wall lamp according to an embodiment of the present utility model;

fig. 3 is a schematic structural diagram of a bidirectional sliding wall lamp according to an embodiment of the present utility model;

fig. 4 is an overall schematic diagram of a bidirectional sliding wall lamp according to an embodiment of the present utility model;

fig. 5 is a schematic placement diagram of a shade fabric in a bidirectional sliding wall lamp according to an embodiment of the present utility model;

fig. 6 is a schematic placement diagram of a chassis in a bidirectional sliding wall lamp according to an embodiment of the present utility model;

fig. 7 is a schematic structural diagram of a second sliding component in the bidirectional sliding wall lamp according to the embodiment of the present utility model;

the reference numerals include: 100-center spindle, 110-center piece, 120-first spindle end, 130-second spindle end, 200 light shield, 300-light source, 310-light source mount, 400-bottom plate, 410-spindle limit slot, 420-first sliding component, 430-chassis limit slot, 500-shell, 510-light transmission area, 520-transmission clamping slot, 530-light shield moving clamping slot, 540-light shield, 600-transmission mechanism, 610-first transmission end, 620-second transmission end, 700-light shield, 800-bottom plate, 810-second sliding component, 811-inside clamping piece, 812-outside clamping piece, 813-screw, 814-nut, 900-power source, 910-power source bracket.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model. Furthermore, it should be understood that the detailed description is presented herein for purposes of illustration and description only, and is not intended to limit the utility model. In the embodiments of the present utility model, unless otherwise specified, terms such as "upper" and "lower" are used to generally refer to the upper and lower positions of the device in actual use or in an operational state, and specifically to the orientation of the drawing figures; while "inner" and "outer" are for the outline of the device. Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more of the described features.

In an embodiment of the present utility model, a bidirectional sliding wall lamp is provided, and referring to fig. 1, a schematic structural diagram of the bidirectional sliding wall lamp provided in the embodiment of the present utility model is provided. The bi-directional sliding wall lamp includes a central rotation shaft 100 and a shade 200.

The central shaft 100 includes a central member 110, a first shaft end 120, and a second shaft end 130; the first and second shaft ends 120, 130 are symmetrically disposed about the center piece 110;

at least two light shielding plates 200; at least one light shielding plate 200 is connected to the first rotation shaft end 120, and at least one light shielding plate 200 is connected to the second rotation shaft end 130.

When one of the light-shielding plates 200 is pushed, the central rotating shaft 100 rotates around the center piece 110, the first rotating shaft end 120 and the second rotating shaft end 130 drive the other light-shielding plate 200 to rotate, and the rotating angle can be set according to the actual use requirement. Thus, the two light shielding plates 200 can move synchronously, so as to adjust the light spot of the bidirectional sliding wall lamp.

Further, the present utility model is not limited to the case where the number of the light shielding plates 200 is two, and if more complicated spot effects are required, the number, shape and color of the light shielding plates 200 may be changed according to actual use requirements, or other structures that can play a role in decoration. The above-described effects can be achieved as long as the light shielding plate 200 is secured to the first or second rotation shaft end 120 or 130.

In one implementation, the bi-directional sliding wall lamp further includes a light source 300, where the light source 300 is disposed on the center piece 110.

In one implementation, the light source 300 may be disposed at the center piece 110 by a light source mount 310.

In the embodiment of the utility model, the light source 300 determines the final light spot effect of the bi-directional sliding wall lamp to a certain extent, so that different types of light sources 300 can be selected according to actual use requirements. It should be noted that, the light emitted by the light source 300 needs to be irradiated to all the light-shielding plates 200 at the same time, so that the light-shielding plates 200 can be effectively shielded, and light spots meeting the requirements can be emitted.

In the embodiment of the present utility model, in order to move one of the light-shielding plates 200, the other light-shielding plate 200 may move synchronously, and the light-shielding plate 200 needs to be connected to the first shaft end 120 or the second shaft end 130, where the light-shielding plate 200 is directly connected to the first shaft end 120 or the second shaft end 130, in other implementations, the light-shielding plate 200 may also be indirectly connected to the first shaft end 120 or the second shaft end 130 through other transmission devices. The following description is made:

referring to fig. 2, another schematic structure of a bidirectional sliding wall lamp according to an embodiment of the present utility model is shown.

In another embodiment of the present application, the bi-directional sliding wall lamp further includes at least two bottom plates 400; the bottom plate 400 is symmetrically disposed around the center piece 110;

in one implementation, when the number of the bottom plates 400 is two, the two bottom plates 400 are right trapezoid, and the upper bottom edges of the two bottom plates 400 are oppositely inserted, so that when one bottom plate 400 is moved, the other bottom plate 400 can relatively move.

In the embodiment of the present utility model, the base plate 400 is used to transmit the movement states of the first and second rotation shaft ends 120 and 130. The shape and the style of the bottom plates 400 can be set according to the actual use requirement, and the shapes and the styles of the two bottom plates 400 can be the same or different, and only the two bottom plates 400 are required to be respectively connected with the first rotating shaft end 120 and the second rotating shaft end 130.

In one implementation, the base plate 400 has different patterns, which can bring about a richer decorative effect for the bidirectional sliding wall lamp.

In the embodiment of the present utility model, the two bottom plates 400 may be directly connected to the first shaft end 120 and the second shaft end 130, or may be indirectly connected to each other. The connection mode can be fixed connection or sliding connection, and can be set according to specific use requirements.

In one implementation, the base plate 400 is provided with a rotation shaft limiting groove 410; the two base plates 400 are respectively connected with the first rotating shaft end 120 and the second rotating shaft end 130 through the rotating shaft limiting groove 410 and the first sliding assembly 420. The first sliding component 420 is any component that can be adapted to the shaft limiting groove 410 and realize a sliding effect.

Referring to fig. 3, an overall schematic diagram of a bidirectional sliding wall lamp according to an embodiment of the present utility model is shown.

In the embodiment of the present utility model, the bidirectional sliding wall lamp further includes at least two housings 500, and the housings 500 are symmetrically disposed around the central member 110. The housing 500 and the bottom plate 400 are coupled such that the housing 500 and the bottom plate 400 enclose the central rotation shaft 100 and the light shielding plate 200; the shape of the housing 500 corresponds to the shape of the bottom plate 400.

In one implementation, when the two housings 500 are two, the two housings 500 are right trapezoid, and the upper bottom edges of the two housings 500 are oppositely inserted, so that when one housing 500 is moved, the other housing 500 can relatively move.

The shape of the case 500 corresponds to the shape of the bottom plate 400, and includes a case where the shape of the case 500 is the same as the shape of the bottom plate 400, and the shape of the case 500 is different from the shape of the bottom plate 400 but corresponds to the shape. The former makes the appearance of the bi-directional sliding wall lamp look as a whole of a complete package, and the latter can realize a more beautiful decoration effect of the bi-directional sliding wall lamp through the shell 500 and the bottom plate 400, for example, the shape of the shell 500 is smaller than that of the bottom plate 400, and the redundant part of the bottom plate 400 can be shaped more complicated.

In the embodiment of the present utility model, the light-transmitting area 510 is disposed on the housing 500 and at the position of the light-shielding plate 200, and the light-transmitting area 510 is used for transmitting light spots.

In one implementation, the size and shape of the light transmissive region 510 and the mask 200 may be the same or different, and may be specifically determined according to the final light spot effect.

In one implementation, a transmission slot 520 is provided on the housing 500 opposite the light-transmitting region 510, and a shutter movement slot 530 is provided below the light-transmitting region 510. Correspondingly, the bidirectional sliding wall lamp further comprises at least two transmission mechanisms 600, and the transmission mechanisms 600 are symmetrically arranged around the central piece 110.

The transmission mechanism 600 includes a first transmission end 610 and a second transmission end 620; the first driving end 610 is connected with the housing 500 through the driving clamping groove 520; the second driving end 620 is connected to the light shielding plate 200, and places the light shielding plate 200 in the light shielding plate moving slot 530.

In one implementation, the first driving end 610 is a linear bearing and the second driving end 620 is a long shaft, and the linear bearing and the long shaft are matched with each other.

In the embodiment of the present utility model, the base plate 400, the housing 500 and the transmission mechanism 600 are used as transmission devices, so that the light shielding plate 200 is indirectly connected with the first rotating shaft end 120 or the second rotating shaft end 130.

Referring to fig. 2, when the two base plates 400 and the two housings 500 are right trapezoid, the bi-directional sliding wall lamp moves as follows: when the upper shell 500 is pushed from left to right, the left transmission mechanism 600 is driven to move from left to right, and the left transmission mechanism 600 drives the lower light shielding plate 200 to move from left to right; meanwhile, due to the limitation of the central rotating shaft 100 and the rotating shaft limiting groove 410 and the trapezoid bevel edge of the housing 500, the lower housing 500 is pushed from right to left, driving the right driving mechanism 600 to move from right to left, and the right driving mechanism 600 drives the lower light shielding plate 200 to move from right to left. In this way, the two light-shielding plates 200 move synchronously in the two light-transmitting areas 510, so that the light spots above and below the bi-directional sliding wall lamp are adjusted at the same time. In the above process, the light spot is adjusted from one light spot to two light spots. Further, as the number of the mask plates 200 increases, the light spot may be adjusted from one light spot to a plurality of light spots.

Referring to fig. 4, a schematic placement diagram of a shade fabric in a bidirectional sliding wall lamp according to an embodiment of the present utility model is shown.

In one implementation, the bi-directional sliding wall lamp further includes a shade cloth 700, the shade cloth 700 includes a first fixed end 710 and a second fixed end 720, the first fixed end 710 is connected to the shade 200, and the second fixed end 720 is connected to the housing 500.

In the embodiment of the utility model, the shading cloth 700 provides a richer light spot adjusting mode for the bidirectional sliding wall lamp.

When the two bottom plates 400 and the two housings 500 are right trapezoid, and the shade cloth 700 is present, the bi-directional sliding wall lamp moves as follows:

when the upper shell 500 is pushed from left to right, the left transmission mechanism 600 is driven to move from left to right, the left transmission mechanism 600 drives the lower light shielding plate 200 to move from left to right, and at this time, the area in the light transmission area 510 corresponding to the left side of the lower light shielding plate 200 is shielded by the light shielding cloth 700; meanwhile, due to the limitation of the central rotation shaft 100 and the rotation shaft limiting groove 410 and the trapezoid bevel edge of the housing 500, the lower housing 500 is pushed from right to left, the right driving mechanism 600 is driven to move from right to left, the right driving mechanism 600 drives the lower light shielding plate 200 to move from right to left, and at this time, the area in the light transmitting area 510 corresponding to the right side of the upper light shielding plate 200 is shielded by the light shielding cloth 700. In this way, the two light-shielding plates 200 move synchronously in the two light-transmitting areas 510, so that the light spots above and below the bi-directional sliding wall lamp are adjusted at the same time. In the above process, the light spot is adjusted from large to small.

Further, the shade cloth 700 can be provided with different transparency or shapes to realize a richer decorative effect of the bi-directional sliding wall lamp.

Referring to fig. 5, another schematic structure of a bidirectional sliding wall lamp according to an embodiment of the present utility model is shown.

In one implementation, chassis restraint slots 430 are also provided on the base plate 400.

In one implementation manner, referring to fig. 6, a schematic placement diagram of a chassis in a bidirectional sliding wall lamp according to an embodiment of the present utility model is shown. The bi-directional sliding wall lamp further comprises a chassis 800, and the chassis 800 is connected to the base 400 through a second sliding assembly 810.

Referring to fig. 7, a schematic structural diagram of a second sliding component in a bidirectional sliding wall lamp according to an embodiment of the present utility model is shown.

In one implementation, the second slider assembly 810 includes: an inner clip 811, an outer clip 812, a screw 813, and a nut 814. Wherein the inner clip 811 and the outer clip 812 are disposed opposite to each other, the inner clip 811 is disposed on the inner side of the base plate 400, and the outer clip 812 is disposed on the outer side of the base plate 400; screws 813 and nuts 814 are used to connect the inside clip 811, the bottom plate 400, the outside clip 812, and the chassis 800; the second sliding component 810 is used for adjusting the damping between the base plate 400 and the chassis 800, so that the bi-directional sliding wall lamp can keep the position from moving after the adjustment of the light spot is completed.

When the two bottom plates 400 and the two housings 500 are right trapezoid, the shade cloths 700 are present, and the chassis 800 is provided, the movement mode of the bidirectional sliding wall lamp is as follows:

in the embodiment of the present utility model, the base plate 400, the housing 500, the transmission mechanism 600 and the chassis 800 are used as transmission devices, so that indirect connection between the light shielding plate 200 and the first rotating shaft end 120 or the second rotating shaft end 130 is realized. Referring to fig. 5, when the upper housing 500 is pushed from left to right, the left driving mechanism 600 is driven to move from left to right, the left driving mechanism 600 drives the lower shade 200 to move from left to right, the light rays covered by the shade cloth 700 are more, and the angle of the light spots is smaller; meanwhile, due to the limitation of the central rotation shaft 100 and the rotation shaft limiting groove 410, the chassis 800, the chassis limiting groove 430 and the second sliding assembly, and the trapezoid bevel edge of the housing 500, the lower housing 500, the right driving mechanism 600 and the upper light shielding plate 200 relatively move leftwards, the light shielded by the light shielding cloth 700 is reduced, and the angle of the light spot is increased. In this way, the light shielding plate 200 moves in the light-transmitting area 510, so that the light spots above and below the bi-directional sliding wall lamp are adjusted at the same time.

In one implementation, the bidirectional sliding wall lamp further includes a power supply 900, where the power supply 900 is disposed inside the housing 500.

In one implementation, the power supply 900 is disposed inside the housing 500 by a power supply bracket 910.

The bidirectional sliding wall lamp and the bidirectional sliding wall lamp provided by the embodiment of the utility model are described in detail, and specific examples are applied to the description of the principle and the implementation mode of the utility model, and the description of the above examples is only used for helping to understand the method and the core idea of the utility model; meanwhile, as those skilled in the art will have variations in the specific embodiments and application scope in light of the ideas of the present utility model, the present description should not be construed as limiting the present utility model.

Claims (14)

1. Two-way slip wall lamp, its characterized in that includes:

a central spindle (100), the central spindle (100) comprising a central member (110), a first spindle end (120) and a second spindle end (130); -the first (120) and second (130) rotational shaft ends are symmetrically arranged around the centre piece (110);

at least two light shielding plates (200); at least one light shielding plate (200) is connected to the first rotating shaft end (120), and at least one light shielding plate (200) is connected to the second rotating shaft end (130).

2. The bi-directional sliding wall lamp of claim 1, further comprising a light source (300), the light source (300) being disposed at the center piece (110).

3. The bi-directional sliding wall lamp of claim 2, further comprising at least two base plates (400):

-said bottom plate (400) being symmetrically arranged around said central member (110);

a rotating shaft limiting groove (410) is formed in the bottom plate (400);

the bottom plate (400) is connected with the first rotating shaft end (120) and the second rotating shaft end (130) through the rotating shaft limiting groove (410) and the first sliding component (420) respectively.

4. A bidirectional sliding wall lamp as recited in claim 3 wherein the bottom plates (400) are right-angled ladder-shaped, and upper bottom edges of the two bottom plates (400) are oppositely interposed.

5. A bi-directional sliding wall lamp according to claim 3, characterized in that it further comprises at least two housings (500):

-said housing (500) being symmetrically arranged around said central member (110);

the shell (500) is connected with the bottom plate (400), and the shell (500) and the bottom plate (400) wrap the central rotating shaft (100) and the light shielding plate (200) inside; -the shape of the housing (500) corresponds to the shape of the bottom plate (400);

and a light transmission area (510) is correspondingly arranged on the shell (500) and the position of the light shielding plate (200), and the light transmission area (510) is used for transmitting light spots.

6. The bidirectional sliding wall lamp of claim 5, wherein the housing (500) is a right-angled ladder, and the upper bottom edge of the housing (500) is oppositely inserted.

7. The bi-directional sliding wall lamp of claim 5, wherein the housing (500) is provided with a transmission slot (520) on the opposite side of the light-transmitting zone (510), and a shutter movement slot (530) is provided below the light-transmitting zone (510).

8. The bi-directional sliding wall lamp of claim 7, further comprising at least two drive mechanisms (600):

the transmission mechanism (600) is symmetrically arranged around the central piece (110);

the transmission mechanism (600) comprises a first transmission end (610) and a second transmission end (620); the first transmission end (610) is connected with the shell (500) through the transmission clamping groove (520); the second transmission end (620) is connected with the light shielding plate (200), and the light shielding plate (200) is placed in the light shielding plate moving clamping groove (530).

9. The bi-directional sliding wall lamp of claim 8, wherein the first driving end (610) is a linear bearing and the second driving end (620) is a long axis.

10. The bi-directional sliding wall lamp of claim 8, further comprising a shade cloth (700), wherein the shade cloth (700) comprises a first fixed end (710) and a second fixed end (720), wherein the first fixed end (710) is connected to the shade plate (200), and wherein the second fixed end (720) is connected to the housing (500).

11. A bi-directional sliding wall lamp according to claim 3, wherein the base plate (400) is further provided with a chassis limiting groove (430).

12. The bi-directional sliding wall lamp of claim 11, further comprising a chassis (800), wherein the chassis (800) is connected to the base plate (400) by a second sliding assembly (810).

13. The bi-directional sliding wall lamp of claim 12, wherein the second sliding assembly (810) comprises:

an inner clip (811) and an outer clip (812), the inner clip (811) and the outer clip (812) being disposed opposite each other, the inner clip (811) being disposed on an inner side of the base plate (400), the outer clip (812) being disposed on an outer side of the base plate (400);

-a screw (813) and a nut (814), the screw (813) and the nut (814) being for connecting the inner clip (811), the bottom plate (400), the outer clip (812) and the chassis (800); the second slide assembly (810) is used to adjust the amount of damping between the base plate (400) and the chassis (800).

14. The bi-directional sliding wall lamp of claim 5, further comprising a power source (900), the power source (900) being disposed inside the housing (500).

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