This application claims priority to Chinese Patent Application No. 202010103083.2, entitled “LIGHTING DEVICE” and filed on Feb. 19, 2020, which is incorporated herein by reference in its entirety.
The present disclosure relates to the technical field of electronic lightings, and in particular to a lighting device.
With the continuous development of electronic lighting technologies and the improvement of people's life, lighting devices are used not only for daily lighting but also for decorating houses. People nowadays have increasing demands in the designs, functions, and application scenarios of lighting devices, which are used in various applications to improve people's quality of life.
One of the embodiments of the present disclosure discloses a lighting device. The lighting device may include a support assembly, an illuminant assembly, and a switch assembly. The support assembly is connected to the illuminant assembly, and the illuminant assembly is capable of being rotated relative to the support assembly. The switch assembly is turned to an on-state by the first illuminant assembly being rotated to a position at which an angle between the illuminant assembly and the support assembly is less than or equal to a first angle threshold, and the switch assembly turns to on-state.
The accompanying drawings, which are incorporated herein and form a part of the specification, illustrate embodiments of the present disclosure and, together with the description, further serve to explain the principles of the present disclosure and to enable a person skilled in the pertinent art to make and use the present disclosure.
The detailed descriptions of the disclosure are provided below with reference to the accompanying drawings and the embodiments. The embodiments described below with reference to the accompanying drawings are only intended to explain the present disclosure and cannot be construed as a limitation to the present disclosure. Moreover, the embodiments described below are some but not all embodiments of the disclosure. The other embodiments that can be obtained without paying any creative efforts by those skilled in the art.
The term “embodiment” mentioned in the disclosure means that a specific technical feature or a structure or a specific function that is incorporated in an embodiment may be included in at least one embodiment of the disclosure. Within the scope that can be understood by those skilled in the art, no matter whether it is obvious or implicit, one embodiment described in the disclosure can be combined with some other one embodiment.
As shown in
In the present disclosure, the term “connected to” can generally refer to “operatively coupled to” in all embodiments. In some embodiments, the term “connected to” refers to “operatively coupled to” and “in contact with.”
In the embodiments as shown in
Support assembly 12 may be configured to support illuminant assembly 14. Support assembly 12 may have any suitable shape, such as a columnar shape or a plate shape.
One end of rotatable assembly 13 may be connected to (e.g., and in contact with) support assembly 12, and the other end of rotatable assembly 13 may be connected to (e.g., and in contact with) illuminant assembly 14, so that illuminant assembly 14 can be rotated to support assembly 12. In various embodiments, illuminant assembly 14 is rotatable to support assembly 12 because of rotatable assembly 13. The detailed structure of rotatable assembly 13 will be described below.
In some embodiments, each of support assembly 12 and rotatable assembly 13 may be hollow inside so that the cable can be routed in support assembly 12 and rotatable assembly 13. In some embodiments, the placement of the cable, e.g., being inside lighting device 10, improves the consistency of the visible structure of lighting device 10.
Illuminant assembly 14 may have any suitable shape/structure, such as a bar-shaped structure, a disk-shaped structure, or a columnar structure. The cable may be electrically connected to illuminant assembly 14 and configured to conduct electricity to illuminant assembly 14 such that illuminant assembly 14 can emit light.
In some embodiments, rotatable assembly 13 may include a sleeve 131, a rotatable ball 132, and a connecting arm 133. Each of sleeve 131, rotatable ball 132, and connecting arm 133 may be hollow so that cable 15, having by a first portion 151 and a second portion 152, may extend through rotatable assembly 13, e.g., sleeve 131, rotatable ball 132, and connecting arm 133.
As shown in
Rotatable ball 132 may be movably connected to sleeve 131, such that rotatable ball 132 can rotate with respect to sleeve 131. Rotatable assembly 13 (e.g., rotatable ball 132 and connecting arm 133) can thus rotate with respect to support assembly 12. Sleeve 131 may partially or fully cover/surround rotatable ball 132. In some embodiments, the fitting surface between rotatable ball 132 and sleeve 131 includes a spherical surface. The surface of rotatable ball 132 may be desirably smooth so that rotatable ball 132 can rotate with respect to sleeve 131 with less/minimum friction in between.
One end of connecting arm 133 may be connected to rotatable ball 132 by any suitable connection means such as clamping connection, glue connection, riveting connection, and/or screw connection. Illuminant assembly 14 may thus rotate to support assembly 12 through rotatable assembly 13. In some embodiments, connecting arm 133 and rotatable ball 132 are coupled by a riveting connection. In some embodiments, connecting arm 133 and illuminant assembly 14 are coupled by a screw connection. In some embodiments, connecting arm 133 and rotatable ball 132 are integrally-formed together as one piece.
A user may operate lighting device 10 with one hand or both hands. Illuminant assembly 14 may be rotated with respect to support assembly 12 in at least plane XY. In some embodiments, illuminant assembly 14 can be rotated to orient along various horizontal directions. For example, illuminant assembly 14 may be rotated around support assembly 12 (e.g., as a rotation axis) in plane XY clockwise or counter-clockwise. The angle of illuminant assembly 14 rotating in plane XY may be any value in the closed interval of [0°, 360°]. That is, the horizontal orientation of illuminant assembly 14 can be along various suitable direction in plane XY.
As shown in
One end of elastic piece 135 may be connected to (e.g., in contact with) damping block 134, and the other end of elastic piece 135 is connected to (e.g., in contact with) support assembly 12. Damping block 134 may abut against rotatable ball 132, and rotatable ball 132 may abut against sleeve 131. The fitting surface between damping block 134 and rotatable ball 132 may include a spherical surface. After illuminant assembly 14 is rotated to a desired position (and/or orientation) with respect to support assembly 12 in the plane XY, an angle between illuminant assembly 14 (e.g., angle θ shown in
Damping block 134 may include polyformaldehyde (POM) and/or polyamide (PA). In some embodiments, damping block 134 is self-lubricating, increasing the easiness of the rotatable ball 132 when being rotated with respect to sleeve 131 and damping block 134. Elastic piece 135 may include a spring and/or a hose made of an elastic material such as the PU (polyurethane).
It has found that if cable 15 extends in lighting device 10 and through support assembly 12, rotatable assembly 13, and illuminant assembly 14 respectively, with one end of cable 15 fixed to support assembly 12 and the other end fixed to illuminant assembly 14, cable 15 may rotate with illuminant assembly 14 when illuminant assembly 14 is rotated with respect to support assembly 12 in plane XY. Conventionally, the length of cable 15 is unchanged after lighting device 10 is assembled. As a result, when illuminant assembly 14 is rotated in plane XZ, cable 15 (especially the portion that extends through support assembly 12 and rotatable assembly 13) may be stretched, causing inner stress in cable 15. Cable 15 may be susceptible to tear and wear. To solve this issue, rotatable assembly 13 may include a sliding ring 136, as shown in
As shown in
Referring back to
Different from the embodiments described in
As shown in
Referring back to
In some other embodiments, sleeve 131 includes two guide grooves 1311. For example, the two guide grooves 1311 may be in the plane XZ and respectively located on the right side and the left side (e.g., the opposite side of the right side about support assembly 12) of the axis line of support assembly 12, so that illuminant assembly 14 can be rotated to a position at which angle θ may be range from 0° to 180°. When angle θ is equal to 0°, connecting arm 133 may be inserted in guide groove 1311 located on the right side of the axis line of support assembly 12. Illuminant assembly 14 can also be rotated to a position at which angle θ is equal to 180°. When the angle is 180°, connecting arm 133 may be inserted in the guide groove 1311 located on the left side of the axis line of support assembly 12. In plane XZ, angle θ may be any value in the closed interval [0°, 180°]. It should be pointed out that when illuminant assembly 14 is rotated to the position at which illuminant assembly 14 is located on the left side of the axis line of support assembly 12, angle θ may be any value in the closed interval [0°, 180°]. In some embodiments, illuminant assembly 14 cannot be further rotated upward, because sleeve 131 may prevent connecting arm 133 from further rotation, and the value of angle θ may not exceed 180°. In some embodiments, in plane XZ, angle θ may be any value in the closed interval [0°, 90°].
Based on the embodiments above, at least plane XZ, illuminant assembly 14 can be rotated to support assembly 12. That is, illuminant assembly 14 can be rotated in a vertical plane with respect to the horizontal plane (e.g., the XY plane). In some embodiments, after illuminant assembly 14 is rotated to a position, angle θ can be maintained because elastic piece 135 squeezes damping block 134 to cause rotatable ball 132 abut against sleeve 131. In some embodiments, the position and/or orientation of illuminant assembly 14 in plane XY can also be maintained thanks to the interactions amongst elastic piece 135, damping block 134, rotatable ball 132, and sleeve 131. It may be convenient for a user to adjust illuminant assembly 14 to a desired orientation and/or position.
Based on the detailed description mentioned above, when angle θ between illuminant assembly 14 and support assembly 12 is 90°, the length direction of connecting arm 133, the axis line direction of rotatable ball 132, and the axis line direction of support assembly 12 may coincide. For example, the directions are along the direction Z. When the angle is 90°, illuminant assembly 14 can be rotated with respect to support assembly 12 in plane XY, and cable 15 is in and extends through support assembly 12 and rotatable assembly 13. In some embodiments, when the value of angle θ between deviates from 90°, the axis line direction of rotatable ball 132 may be different from the direction Z. For example, when angle θ is equal to 0° or 180°, the axis line direction of rotatable ball 132 may be substantially perpendicular to the axis line direction of support assembly 12, and thus the arrangement of cable 15 may be affected. Thus, based on the embodiment mentioned above, this embodiment will improve the structure of rotatable ball 132 so as to reduce or eliminate the interference of rotatable ball 132 to cable 15 when rotatable ball 132 rotates with respect to sleeve 131.
In some embodiments, as shown in
Spherical surface 1321 may include a primary opening 1326. First surface 1322 may include a first secondary opening 1327. Second surface 1323 may include a second secondary opening 1328. The axis line of primary opening 1326 may be along the direction Z. The axis lines of the first and the second secondary openings may coincide, e.g., along the direction Y. Each of the axis lines of primary opening 1326, the first and second secondary openings 1327 and 1328 may extend through the center (e.g., geometric center) of rotatable ball 132. In some embodiments, primary opening 1326, first secondary opening 1327, and second secondary opening 1328 are in contact with each other.
Due to the visual angle of rotatable ball 132 shown in
Connecting arm 133 may be inserted in primary opening 1326. Cable 15 (specifically, may be second portion 152 of cable 15) may be divided into a first rope and a second rope extending through rotatable ball 132 from connecting arm 133. The first rope may extend from first secondary opening 1327 and in the space of first clearance 1324, and the second rope may extend from the second secondary opening 1328 and in the space of second clearance 1325. The first rope and the second rope may re-adjoin each other to form the second portion of cable 15. In some embodiments, taking into consideration that the rotatable assembly 13 may include a damping block 134 that abuts against rotatable ball 132, after cable 15 (e.g., second portion 152 of cable 15) extends out of the first secondary opening 1327 and the second secondary opening 1327, cable 15 may split and extend around the two sides of damping block 134, i.e., go around the damping bock 134, before the split portions of cable 15 merge again.
In some other embodiments, rotatable ball 132 may only include first surface 1322 or second surface 1323. Accordingly, only one of first clearance 1324 and second clearance 1325 can be formed, and only one of first secondary opening 1327 and second secondary opening 1328 can be formed. Cable 15 (e.g., second portion 152 of cable 15) may not be divided into two ropes extending through rotatable ball 132 from connecting arm 133, and cable 15 may extend from first secondary opening 1327 or second secondary opening 1328.
By the means mentioned above, when rotatable ball 132 rotates with respect to sleeve 131 in plane XZ, cable 15 (e.g., second portion 152 of cable 15) may rotate together with rotatable ball 132 in plane XZ, and the interference to cable 15 will be decreased.
Other structures of this embodiment are identical or similar to those of the embodiments mentioned above and the detailed descriptions of the structures may be referred to the embodiments mentioned above and are not provided herein.
Referring to
In the embodiment, as shown in
Switch assembly 16 may include a trigger 161 and a sensor 162. One of trigger 161 and sensor 162 is positioned at the end of illuminant assembly 14 that is away from support assembly 12, and the other of trigger 161 and sensor 162 is positioned at the end of support assembly 12 that is away from illuminant assembly 14. For illustrative purposes, in some embodiments, a trigger 161 may be located in illuminant assembly 14 and/or a sensor 162 may be located in base assembly 11, so that the consistency of the visible structure of lighting device 10 can be improved. In some embodiments, when illuminant assembly 14 is rotated to a position at which angle θ between illuminant assembly 14 and support assembly 12 is less than or equal to the first angle threshold, sensor 162 is triggered by trigger 161 to turn switch assembly 16 to the on-state.
In some embodiments, trigger 161 includes a magnet, such as a permanent magnet. Generally, a spherical magnetic field will be formed around a magnet. The magnetic field from the magnet decreases gradually with increasing distance. When illuminant assembly 14 is rotated with respect to support assembly 12 in the plane XZ, if the angle θ between illuminant assembly 14 and support assembly 12 changes from 90° to 0 or from 180° to 0°, the distance between trigger 161 and sensor 162 decreases gradually. The strength of the magnetic field of trigger 161 applied on sensor 162 may increase gradually.
Sensor 162 may include a hall sensor. When the strength of the magnetic field applied on the hall sensor is greater than a strength threshold, the electric current generated by the hall sensor may be transformed into a control signal that can turn switch assembly 16 to the on-state. In some embodiments, sensor 162 includes a magnetic reed switch. When the strength of the magnetic field applied on the magnetic reed switch is greater than a strength threshold, the magnetic reeds of the magnetic reed switch start to contact each other and then turns switch assembly 16 to the on-state.
By the above-mentioned means, when illuminant assembly 14 is rotated to a position at which angle θ is less than or equal to the first angle threshold, the strength of the magnetic field of trigger 161 applied on sensor 162 is greater than or equal to the strength threshold. Switch assembly 16 may be turned to the on-state.
It should be pointed out that the first angle threshold may be less than or equal to 45°. In some embodiments, the first angle threshold is less than or equal to 30°. In some embodiments, the first angle threshold is less than or equal to 10°. The strength threshold mentioned above is correlated not only with the first angle threshold but also with the magnetic strength of trigger 161 and the sensitivity of sensor 162. There is no limitation to the value of the magnetic field strength. That is, the value of the magnetic field strength can be reasonably designed based on the above-mentioned factors.
In some other embodiments, sensor 162 includes a capacitive sensor, and trigger 161 includes a media. When illuminant assembly 14 is rotated to a position at which angle θ is less than or equal to the first angle threshold, trigger 161 may be close to or may contact sensor 162. A change of the capacitance quantity of sensor 162 is caused by trigger 161, and the change may be transformed into a control signal that can turn switch assembly 16 to the on-state.
In some other embodiments, sensor 162 includes an inductive transducer, and trigger 161 includes a sheet metal. When illuminant assembly 14 is rotated to a position at which angle θ is less than or equal to the first angle threshold, trigger 161 may be close to or may contact sensor 162. The oscillation of sensor 162 may be weakened, caused by an eddy current generated by trigger 161. The change/reduction of oscillation may be transformed into a control signal that can turn switch assembly 16 to the on-state.
Based on the detailed description mentioned above, when angle θ is greater than the first angle threshold, e.g., equal to 90° as shown in
In some embodiments, switch assembly 16 may be electrically connected to illuminant assembly 14. When switch assembly 16 is at the on-state, switch assembly 16 can turn on illuminant assembly 14 to emit light. Because the volume of illuminant assembly 14 is much greater than that of the button(s) of base assembly 11, a user may not find the button(s) easily at night (e.g., in the dark). In some other scenarios, a user may rotate illuminant assembly 14 to a position at which illuminant assembly 14 is sufficiently close to support assembly 12 such that switch assembly 16 can be turned to the on-state, as shown in
In some other embodiments, lighting device 10 is configured to interact with an air conditioner, a TV, and/or other domestic appliances. Switch assembly 16 may function as a remote switch of these domestic appliances, and lighting device 10 may function as a controller for the domestic appliance. When a user cannot find the controller of the domestic appliance or in other scenarios, the user can turn the domestic appliances on or off by operating lighting device 10.
The main differences between light device 10 in
In some embodiments, switch assembly 16 is electrically connected to at least second illuminant assembly 17. When switch assembly 16 is at on-state, switch assembly 16 can turn at least second illuminant assembly 17 on to emit light. For example, switch assembly 16 is electrically connected to second illuminant assembly 17, and when switch assembly 16 is on-state, switch assembly 16 can turn second illuminant assembly 17 on to emit light. In another example, switch assembly 16 may be electrically connected to illuminant assembly 14 and second illuminant assembly 17. When switch assembly 16 is at the on-state, i.e., angle θ less than or equal to the first angle threshold, switch assembly 16 can turn illuminant assembly 14 and second illuminant assembly 17 to emit light. When angle θ is 0°, as shown in
In some embodiments, as shown in
It should be pointed out that when second illuminant assembly 17 at in the lighting state, the lighting directions of second illuminant assembly 17 may be towards the left side or the right side of support assembly 12 in plane XZ, or may be towards both the left and right sides of support assembly 12 in plane XZ. In the embodiment, the lighting directions of second illuminant assembly 17 are towards the left side of support assembly 12 in plane XZ.
Referring to
As shown in
In some embodiments, because the dimension of illuminant assembly 14 along direction Z may be small, to improve the connection between illuminant assembly 14 and rotatable assembly 13 (e.g., connecting arm 133) or strengthen the connection reliability between illuminant assembly 14 and rotatable assembly 13, illuminant assembly 14 may include a mounting board 144. Mounting board 144 may be located between first lampshade 141 and first board 142 and connected to (e.g., in contact with) at least one of first lampshade 141 and first board 142. In some embodiments, mounting board 144 includes a third mounting opening 1441 (located on the backside of mounting board 144 and not visible in
As shown in
Because second illuminant assembly 17 may be connected to (e.g., in contact with) illuminant assembly 14, to simplify the structure of lighting device 10, many structures mentioned above may be designed to be integrally formed or universal parts. For example, second lampshade 171 and first lampshade 141 may be designed to be integrally formed. Second board 172 and the first board 142 may be designed to be integrally formed. Second lampshade 171 and first lampshade 141 are integrally formed as a whole (e.g., one piece). As shown in
In some embodiments, ring light 173 has an annular shape. To position ring light 173, second illuminant assembly 17 may include a supplementary board 174. Supplementary board 174 may be located between second lampshade 171 and second board 172. In some embodiments, supplementary board 174 is connected to (e.g., in contact with) at least one of second lampshade 171 and second board 172. In some embodiments, supplementary board 174 includes a board body 1740 and a first annular protrusion 1741. First annular protrusion 1741 extends from board body 1740. Second lampshade 171 includes a lampshade body 1710 and a second annular protrusion 1711. Second annular protrusion 1711 extends from lampshade body 1710. Board body 1740 defines a through hole 17401. Through hole 17401 is surrounded by first annular protrusion 1741. After supplementary board 174 is assembled with second lampshade 171, second annular protrusion 1711 is located in through hole 17401, and an annular gap (not marked in
It should be pointed out that lighting device 10 described in the disclosure is equipped with only one illuminant assembly. That is, the detailed structures of illuminant assembly 14 may be similar or identical to the embodiments mentioned above.
The above-described embodiments are partial embodiments of the disclosure and cannot be considered as the limitation of the protection scope of the disclosure. All equivalent devices or processes obtained from the specification and the accompanying drawings and directly or indirectly applied to other relevant technical fields, fall in the protection scope of the disclosure.
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