CN110768074B - Adapter and magnetic conductive track system - Google Patents

Abstract

The embodiments of the present application disclose an adapter and a magnetic conductive track system. The adapter includes an insulating body, and a conductive terminal disposed in the insulating body and partially protruding from the insulating body. The conductive terminal is sheet-shaped and includes a base disposed in the insulating body and a docking portion protruding from the outside of the insulating body. The insulating body is provided with a guide portion protruding from the docking portion adjacent to the conductive terminal, which is spaced apart from the conductive terminal, and is configured so that the guide portion and the docking portion are jointly assembled into the at least two electrical devices to realize the electrical connection of the two electrical devices. The adapter and the magnetic conductive track system provided in the embodiments of the present application can quickly and conveniently cascade different magnetic conductive tracks into different configurations to meet different needs, and have a simple structure and are ultra-thin.

Description

Adapter and magnetic attraction conductive track system

Technical Field

The application relates to the technical field of illumination, in particular to an adapter for cascading electrical devices and a system thereof.

Background

The guide rail lamp mainly comprises a guide rail (conductive track) fixed on a ceiling or a wall, and various lamps which can slide along the guide rail, such as a spotlight, a line lamp and the like.

The guide rail is generally provided with a certain height or thickness, and has a certain improvement space on the basis of the prior art, so that the guide rail is lighter and thinner and has lower cost.

In addition, the cascade structure of the guide rail also has an improvement space, can be lighter and thinner and has smaller thickness, and smooth, efficient and rapid connection is realized.

The mechanical combination and the electrical combination reliability of the electrical device arranged on the guide rail when the guide rail is electrified are also technical problems which are always solved in the prior art. In the prior art, after the conductive terminal group of the electrical device is arranged on the conductive strip in the guide rail, if the reliability of the mechanical structure is insufficient, the electrical connection between the conductive terminal and the conductive strip is also affected, so that the use of the electrical device is affected.

Disclosure of Invention

The embodiment of the application provides an adapter, which at least solves one of the technical problems.

The embodiment of the application also provides a magnetic conductive track system formed by cascading the adapters, which is convenient and efficient to cascade and has a changeable structure according to requirements.

The embodiment of the application adopts the following technical scheme that the adapter is configured to at least cascade two electric devices and comprises an insulating body and a conductive terminal which is arranged in the insulating body and partially protrudes out of the insulating body, wherein the conductive terminal is sheet-shaped and comprises a base part arranged in the insulating body and a butt joint part protruding out of the insulating body. The insulation body is provided with a guide part protruding from a butt joint part adjacent to the conductive terminal at intervals, and the guide part and the butt joint part are combined into the at least two electric devices together to realize electric connection of the two electric devices.

Preferably, the insulating body and the conductive terminal are integrally formed or the insulating body comprises a first body and a second body, and the conductive terminal is clamped between the first body and the second body.

Preferably, the insulating body has at least two sides, and the butt-joint part of the conductive terminal extends from at least two sides of the insulating body.

Preferably, the abutting portion of the conductive terminal extends at least from two adjacent sides or two parallel sides or two perpendicular sides of the insulating body.

Preferably, the butt joint parts of the conductive terminals extending from each side edge of the insulating body are arranged in pairs, and are respectively positive electrodes or negative electrodes.

Preferably, the insulating body is square and has four sides, wherein at least two sides are provided with butt joint parts of the conductive terminals.

Preferably, the insulating body is L-shaped and has a first body and a second body, the conductive terminals include a first conductive terminal disposed in the first body and a second conductive terminal disposed in the second body, and the first conductive terminal is electrically connected with the second conductive terminal.

Preferably, the first conductive terminal and the second conductive terminal are both sheet-shaped.

The embodiment of the application also provides a magnetic conductive track system which is configured to be arranged on the surface of the installation foundation and comprises an adapter and at least two magnetic conductive tracks, wherein the adapter comprises an insulating body and conductive terminals arranged in the insulating body, the conductive terminals comprise a base part arranged in the insulating body and a butt joint part extending beyond the insulating body, the magnetic conductive tracks comprise a main body part and end parts arranged at two ends of the main body part, the main body part is internally provided with conductive parts, and the end parts are configured to be electrically connected with the conductive parts and the conductive terminals of the adapter at the same time and mechanically connected with the main body part of the magnetic conductive track and the adapter at the same time.

Preferably, the end part comprises an insulating body and a conductive terminal arranged in the insulating body, wherein two ends of the conductive part extend beyond two end surfaces of the main body part and extend into the end part to be electrically connected with the conductive terminal.

Preferably, the conductive terminal of the end portion includes a base portion located in a vertical plane, and a first abutting portion and a second abutting portion formed by extending from the base portion along a length direction in a reverse direction, wherein the first abutting portion is electrically connected with the conductive portion, and the second abutting portion is electrically connected with the conductive terminal of the adapter.

Preferably, the first and second abutting portions respectively include a pair of elastic members extending from upper and lower end edges of the base portion and bent toward each other, the elastic members are adjacent to each other near the free ends, the free ends form guide portions away from each other, and the conductive portions pass through the guide portions and are interposed between the elastic members to form electrical connection with the conductive terminals.

Preferably, the insulating body of the end part comprises a first surface and a second surface which are oppositely arranged, a first end surface and a second end surface which are oppositely arranged, a pair of conductive plug parts which are horizontally arranged and a positioning plug part which is positioned between the conductive plug parts are formed by extending from the first end surface along the length direction, wherein the conductive parts enter the end part from the conductive plug parts and are electrically connected with the conductive terminals, and the positioning plug parts enter the accommodating space and are abutted against the magnetic element.

Preferably, a positioning insertion portion and a positioning hole are concavely formed from the second end face to the first end face, and a guiding portion arranged at an interval with the conductive terminal is formed at the position, close to the butt joint portion of the conductive terminal, of the insulating body of the adapter in a protruding mode, wherein the positioning insertion portion is electrically connected with the conductive terminal of the adapter, and the positioning hole accommodates the guiding portion of the adapter.

Preferably, the positioning holes are in a pair, and the positioning plug-in parts are in a pair and are positioned at the inner sides of the pair of positioning holes.

Preferably, the magnetic conductive track system is located in the same plane and comprises at least two magnetic conductive tracks and at least one adapter, wherein the end parts, the main body parts and the at least one adapter of the different magnetic conductive tracks are mutually embedded and assembled, and the outer surfaces of the three are mutually flush.

Preferably, the magnetic conductive track system is located in different planes and comprises at least two magnetic conductive tracks and at least one adapter, wherein the adapter is L-shaped, after the end part, the main body part and one part of the at least one adapter of one magnetic conductive track are mutually embedded and assembled, the end part, the main body part and the other part of the at least one adapter of the magnetic conductive track are mutually flush with each other and are attached to the mounting base, and after the end part, the main body part and the other part of the at least one adapter of the other magnetic conductive track are mutually embedded and assembled, the end part, the main body part and the other part of the at least one adapter of the other magnetic conductive track are mutually flush with each other and are attached to the mounting base.

Preferably, the insulating body of the adapter is formed with a guide part protruding from a butt joint part adjacent to the conductive terminal and arranged at intervals with the conductive terminal, and the guide part and the butt joint part are combined into the end part (14) together to realize the electrical connection and mechanical connection of at least two magnetic conductive tracks.

The above at least one technical scheme adopted by the embodiment of the application can achieve the following beneficial effects:

The adapter and the magnetic conductive track system provided by the embodiment of the application can be used for cascading different magnetic conductive tracks into different configurations rapidly and conveniently, so that different requirements are met, and the adapter is simple in structure and ultrathin.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this specification, illustrate embodiments of the application and together with the description serve to explain the application and do not constitute a limitation on the application. In the drawings:

reference numerals illustrate:

fig. 1 is a perspective view of a magnetic conductive track according to an embodiment of the present application;

FIG. 2 is a perspective view of the magnetically attractable conductive track of FIG. 1 at another angle;

FIG. 3 is a partially exploded perspective view of the magnetically attractable conductive track of FIG. 1;

FIG. 4 is a partially exploded perspective view of the magnetically attractable conductive track of FIG. 2;

FIG. 5 is a perspective view of an end of a magnetically attractable conductive track provided by an embodiment of the present application;

FIG. 6 is an exploded perspective view of the end portion shown in FIG. 5;

FIG. 7 is another angular perspective view of the end portion shown in FIG. 5;

FIG. 8 is an exploded perspective view of the end portion shown in FIG. 7;

FIG. 9 is a cross-sectional view of the magnetically attractable conductive track of FIG. 1 taken along line A-A;

FIG. 10 is a cross-sectional view of the magnetically attractable conductive track of FIG. 1 taken along line B-B;

FIG. 11 is a cross-sectional view along line C-C of the magnetically attractable conductive track of FIG. 1;

FIG. 12 is a perspective view of an adapter according to a first embodiment of the present application;

FIG. 13 is an exploded perspective view of the adapter shown in FIG. 12;

FIG. 14 is a perspective view of a magnetically attractable conductive track system in accordance with a first embodiment of the present application;

FIG. 15 is a perspective view of an adapter according to a second embodiment of the present application;

FIG. 16 is an exploded perspective view of the adapter shown in FIG. 15;

FIG. 17 is a perspective view of a magnetically attractable conductive track system in accordance with a second embodiment of the present application;

FIG. 18 is a perspective view of an adapter according to a third embodiment of the present application;

FIG. 19 is an exploded perspective view of the adapter shown in FIG. 18;

FIG. 20 is a perspective view of a magnetically attractable conductive track system in accordance with a third embodiment of the present application;

FIG. 21 is a perspective view of an adapter according to a fourth embodiment of the present application;

FIG. 22 is an exploded perspective view of the adapter shown in FIG. 21;

FIG. 23 is a perspective view of a magnetically attractable conductive track system in accordance with a fourth embodiment of the present application;

FIG. 24 is a perspective view of an adapter according to a fifth embodiment of the present application;

FIG. 25 is an exploded perspective view of the adapter shown in FIG. 24;

Fig. 26 is a perspective view of a magnetically attractable conductive track system in accordance with a fifth embodiment of the present application;

FIG. 27 is a perspective view of an electrical device that may be assembled with magnetically attractable conductive tracks in accordance with a first embodiment of the present application;

FIG. 28 is a partially exploded perspective view of the electrical device shown in FIG. 27;

Fig. 29 is a perspective view of an electrical system consistent with a first embodiment of the present application;

Fig. 30 is a cross-sectional view of an electrical system consistent with a first embodiment of the present application;

FIG. 31 is an enlarged partial view of the cross-sectional view shown in FIG. 30;

FIG. 32 is a perspective view of an electrical device that can be assembled with magnetically attractable conductive tracks in accordance with a second embodiment of the present application;

FIG. 33 is another perspective view of the electrical device shown in FIG. 32;

FIG. 34 is a cross-sectional view taken along the line D-D of the electrical device shown in FIG. 32;

FIG. 35 is a partially exploded perspective view of the electrical device shown in FIG. 32;

FIG. 36 is an exploded perspective view of the electrical device shown in FIG. 32;

FIG. 37 is an exploded perspective view of the electrical device shown in FIG. 33;

FIG. 38 is a perspective view of an electrical connection module of the electrical device shown in FIG. 32;

FIG. 39 is an exploded perspective view of the electrical connection module shown in FIG. 38;

FIG. 40 is another angled perspective view of the electrical connection module shown in FIG. 38;

fig. 41 is a perspective view of an electrical system consistent with a second embodiment of the present application;

FIG. 42 is a cross-sectional view taken along line E-E of the electrical system shown in FIG. 41;

FIG. 43 is a perspective view of an electrical device that may be assembled with magnetically attractable conductive tracks in accordance with a third embodiment of the present application;

FIG. 44 is a partially exploded perspective view of the electrical device shown in FIG. 43;

FIG. 45 is a cross-sectional view taken along line F-F of the electrical device shown in FIG. 43;

FIG. 46 is a perspective view of an electrical connection module of the electrical device shown in FIG. 43;

fig. 47 is a perspective view of an electrical system consistent with a third embodiment of the present application;

FIG. 48 is a cross-sectional view taken along the G-G direction of the electrical system shown in FIG. 47;

FIG. 49 is a perspective view of an electrical device that can be assembled with magnetically attractable conductive tracks in accordance with a fourth embodiment of the present application;

FIG. 50 is another perspective view of the electrical device shown in FIG. 49;

FIG. 51 is an exploded perspective view of the electrical device shown in FIG. 49;

FIG. 52 is an exploded perspective view of the electrical device shown in FIG. 50;

FIG. 53 is an enlarged partial view of the body of the electrical device shown in FIG. 51;

FIG. 54 is an enlarged view of a partial perspective assembly of the electrical device shown in FIG. 49;

FIG. 55 is a perspective view of an electrical connection module of the electrical device shown in FIG. 49;

FIG. 56 is another angled perspective view of the electrical connection module shown in FIG. 55;

FIG. 57 is an exploded perspective view of the electrical connection module shown in FIG. 56;

FIG. 58 is a cross-sectional view taken along line H-H of the electrical device shown in FIG. 49;

fig. 59 is a perspective view of an electrical system consistent with a fourth embodiment of the application;

FIG. 60 is an enlarged view of a portion of the electrical system shown in FIG. 59;

fig. 61 is a cross-sectional view taken along line I-I of the electrical system shown in fig. 59.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the technical solutions of the present application will be clearly and completely described below with reference to specific embodiments of the present application and corresponding drawings. It will be apparent that the described embodiments are only some, but not all, embodiments of the application. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

The following describes in detail the technical solutions provided by the embodiments of the present application with reference to the accompanying drawings.

As shown in fig. 1-4, referring to fig. 9-11, an embodiment of the application discloses a magnetic conductive track 1, which is in a strip shape and flat, and comprises a main body 10, a magnetic element 11, an insulating part 12, a conductive part 13 and end parts 14 arranged at two ends of the main body 10.

The body 10 extends in the longitudinal direction and has a flat shape, and includes an adsorption wall 101, a mounting wall 102 provided in parallel with and opposite to the adsorption wall 101, a pair of side walls 103 connecting the adsorption wall 101 and the mounting wall 102, and a pair of partition walls 104 provided in parallel with the side walls 103 and between the side walls 103. The outer surface of the adsorption wall 101 is an adsorption surface 1010, and the outer surface of the installation wall 102 is an installation surface 1020. The side walls 103 and the partition walls 104 form conductive grooves 105 extending in the longitudinal direction and located on both sides, and a receiving space 106 located between the conductive grooves 105, respectively, with the suction wall 101 and the mounting wall 102. Two long and narrow grooves 107 are formed from the adsorption wall 101 to the mounting wall 102, and the grooves 107 are positioned above the conductive grooves 105 and are communicated with the conductive grooves 105. The adsorption wall 101 between the slots 107 is further provided with at least two elliptical mounting holes 108 adjacent to the two ends, and the number of the mounting holes 108 is set according to the length of the magnetic attraction conductive track 1. Corresponding to the mounting hole 108, the magnetic element 11 and the mounting wall 102 are respectively provided with a mounting hole 110 and a mounting hole 109, which are communicated in the height direction, and the size of the mounting hole 109 of the mounting wall 102 is smaller than that of the mounting hole 109 of the magnetic element 11 and the mounting hole 108 of the adsorption wall. The mounting holes 108, 109, 110 are used for screws to pass through, and the screw heads are finally pressed on both sides of the mounting hole 109 of the mounting wall 102 and locked with the mounting base (ceiling or wall) to fix the magnetically conductive track 1 to the mounting base. When the installation is completed, the installation hole 108 of the adsorption wall 101 is blocked and closed by a blocking piece (not shown), and in particular, the blocking piece can be arranged on the surface of the magnetic element 11 through adhesive.

The insulating portion 12 is accommodated in the conductive groove 105, and includes a horizontal bottom wall 120, a first side wall 121 formed by extending vertically from the bottom wall 120, a horizontal wall 123 formed by extending horizontally from the first side wall 121 in opposite directions, and a second side wall 122 formed by extending vertically from the horizontal wall 123. The distance between the second side walls 122 is smaller than the distance between the first side walls 121, so that a first space 124 is defined between the bottom wall 120 and the first side walls 121, and a second space 125 communicating with the first space 124 is defined between the horizontal wall 123 and the second side walls 122. The first space 124 and the second space 125 form a receiving portion 126 of the insulating portion 12. The first side wall 121 is located between the side walls of the conductive slot 105, i.e. between the side wall 103 and the partition wall 104 and forms a surface-to-surface contact, preferably an interference fit, while the second side wall 122 is located between the side walls of the slot 107, so that the insulating portion 12 is laid between the conductive slot 105 and the inner wall of the slot 107, providing reliable insulation. The free end of the second sidewall 122 is configured to be slightly below or flush with the suction surface 1010.

The two conductive parts 13 are flat bar-shaped, respectively, positive and negative, and are respectively inserted into the first spaces 124 of the insulating parts 12, so as to be located in the conductive grooves 105, and two ends thereof respectively extend beyond the two end surfaces 100 of the main body 10. The conductive terminal of the lamp assembled on the magnetic conductive track 1 enters the first space 124 through the second space 125 to be electrically connected with the conductive portion 13.

The magnetic element 11 is flat and sheet-shaped, is inserted into the accommodating space 106 of the main body 10, and is attached to at least the inner surface of the adsorption wall 101, so as to be adsorbed to the magnetic mounting portion of the lamp. Both ends of the magnetic element 11 are located in the accommodating space 106 and do not extend beyond both end surfaces 100 of the main body 10. The magnetic element 11 may be respectively attached to the inner surface of the adsorption wall 101 and the inner surface of the mounting wall 102, and in the preferred embodiment of the present application, the magnetic element 11 is attached to the inner surface of the adsorption wall 101, and the inner surface of the mounting wall 102 is provided with two protruding strips 1022 abutted against the surface of the magnetic element 11 to ensure the assembly reliability.

Referring to fig. 5-11, the end portions 14 are disposed at two ends of the main body 10 and electrically connected to the conductive portions 13. The end 14 includes an insulating body 140 and a conductive terminal 143 accommodated in the insulating body 140.

The conductive terminals 143 are a pair, and each conductive terminal 143 includes a base 1430 having a flat plate shape in a vertical plane, and a first abutting portion 1431 and a second abutting portion 1432 formed to extend in opposite directions from the base 1430, respectively. The first and second abutting portions 1431 and 1432 include a pair of elastic members extending from upper and lower end edges of the base portion 1430 and bent toward each other, respectively, adjacent to the free ends, the elastic members being adjacent to each other and the free ends forming spring piece guide portions 1433 spaced apart from each other.

The insulating body 140 may be integrally formed with the conductive terminal 143 and includes a pair of conductive plugs 144 extending from the first end face 1403 thereof and a locating plug 145 located between the conductive plugs 144.

The end surface of the conductive plugging portion 144 is provided with an opening, and the elastic piece guiding portion 1433 of the first abutting portion 1431 of the pair of conductive terminals 143 is adjacent to the conductive plugging portion 144, so that after the end 14 is assembled to the main body portion 10, the conductive portion 13 passes through the opening of the conductive plugging portion 144 and is assembled between the pair of elastic members of the first abutting portion 1431 to form an electrical connection with the conductive terminals 143. A guiding and positioning portion 1440 is also protruding from one surface of the conductive plug portion 144, and is a pair of protruding strips, the width of which is equal to that of the slot 107, and when the end portion 14 is assembled with the main body portion 10, the guiding and positioning portion 1440 enters the slot 107. The positioning plug 145 is inserted into the accommodating space 106 and abuts against the end of the magnetic element 11 to provide positioning of the magnetic element 11 in the length direction.

The insulating body 140 has a pair of positioning holes 146 formed in a concave manner from the second end face 1404 thereof toward the first end face 1403, and a pair of conductive insertion holes 147 provided between the positioning holes 146 and adjacent to the positioning holes 146. The second docking portion 1432 is configured such that the elastic piece guiding portion 1433 is received in the conductive socket 147, and is used for electrically connecting with the adaptor 2 and thus electrically connecting with other magnetic conductive tracks.

The insulating body 140 further includes a first surface 1401 and an opposite second surface 1402, which are flush with the suction surface 1010 and the mounting surface 1020 of the main body 10, respectively, so as to form a flat structure for reducing the height.

In the preferred embodiment of the present application, the insulating body 140 is formed by mutually assembling a first housing 141 and a second housing 142 arranged along the up-down direction, and the conductive terminals 143 are interposed and accommodated between the first housing 141 and the second housing 142. The first surface 1401 is disposed on the first housing 141, and the second surface 1402 is disposed on the second housing 142. Accordingly, the above-described structures are each formed by combining the first case 141 and the second case 142.

Specifically, the first housing 141 extends from a surface opposite to the first surface 1401 to form two conductive terminal receiving grooves 1410, and each conductive terminal receiving groove 1410 has two cavities 1412 that are staggered and respectively communicate with the conductive plug portions 144 and the conductive plug holes 147 that are staggered, so as to respectively receive the first butt joint portion 1431 and the second butt joint portion 1432 of the conductive terminal 143. A pair of positioning elements 1411 and a positioning plug portion 145 protruding from the first end face 1403 are disposed between the two conductive terminal receiving grooves 1410 adjacent to the first end face 1403, and the positioning elements 1411 may be a pair of positioning posts protruding in the height direction or a positioning element formed with a positioning groove. Positioning holes 146 are formed between the two conductive terminal receiving slots 1410 adjacent to the second end surface 1404 and the side walls.

Accordingly, the second housing 142 is provided with a partition wall 1422 for forming two cavities 1420 to accommodate the conductive terminals 143 in cooperation with the conductive terminal accommodating grooves 1410, and positioning elements 1421 formed in the cavities 1420 are matched with the positioning elements 1411 of the first housing 141. The cavity 1420 is in communication with the conductive socket 144, the conductive socket 147, and the positioning hole 146, respectively.

In summary, according to the magnetic conductive track 1 provided by the application, the adsorption surface 1010 and the mounting surface 1020 are respectively in direct surface-to-surface contact with the adsorption surface and the mounting base of the lamp, so that the height of the magnetic conductive track 1 is effectively reduced, the height of the end 14 is effectively reduced through the conductive terminals 143 with reverse extending flat structure design, the first surface 1401 and the second surface 1402 of the end 14 can be respectively flush with the adsorption surface 1010 level mounting surface 1020, the overall structure of the magnetic conductive track 1 is simple, the ultrathin structural design is realized, and the cost is effectively reduced.

In order to flexibly arrange the magnetic conductive track 1 provided by the application, various arrangements can be realized to meet different requirements, and the application also provides an adapter 2 which has various forms and can realize cascade connection modes such as linear connection, planar L-shaped connection, vertical L-shaped connection, cross connection, T-shaped connection and the like of the magnetic conductive track 1 as shown in figures 12-26. The system consisting of the adapter 2 and at least two magnetic conductive tracks 1 is a magnetic conductive track system 1000. The adapter 2 is mechanically and electrically connected with the magnetic conductive track 1, and after cascading the magnetic conductive track 1, is flush with the mounting surface 1020 of the magnetic conductive track 1 and the first surface 1401 of the end 14, and is respectively attached to the surface of the mounting base. Therefore, the thickness of the magnetic conductive track system 1000 is small, and an ultrathin structural design is realized.

In other embodiments, the adaptor 2 is not limited to the cascading magnetically attractable conductive tracks 1, but may be other electrical devices.

In correspondence with the above cascade manner, the adapter 2 has various structures, which are described below, respectively.

Please referring to fig. 12-26, the adapter 2 includes an insulating body 20 and a conductive terminal 23 disposed in the insulating body 20 and partially protruding out of the insulating body 20 to form an electrical connection with the end 14 of the magnetic conductive track 1. The insulating body 20 may be integrally formed with the conductive terminal 23, and may also include a first body 21 and a second body 22 assembled with the first body 21 along a height direction, where the conductive terminal 23 is sandwiched between the first body 21 and the second body 22. The insulating body 20 has a square shape and four sides, has a first surface 204 and an opposite second surface 206, and at least includes a main body 201 and a guiding portion 202 extending from the main body 201. The conductive terminal 23 includes at least a base 231 and a butt portion 232 extending from the base 231 and beyond the main body 201 of the insulating body 20. The guiding portion 202 of the insulating body 20 is disposed adjacent to the abutting portion 232 and is disposed in parallel to guide and protect the abutting portion 232. When the adaptor 2 is abutted with the end 14 of the different magnetic conductive track 1, the guiding portion 232 is assembled into the positioning hole 146, and the abutting portion 232 enters the end 14 from the positioning insertion portion 145 and is electrically connected with the second abutting portion 1432 of the conductive terminal 143. In order to accommodate the conductive terminals 23, the first body 21 and the second body 22 respectively form an accommodating space 24 located at a middle portion for accommodating the base 231 of the conductive terminal 23 and a plurality of accommodating channels 25 communicating with the accommodating space 24, and the abutting portion 232 is partially accommodated in the accommodating channel 25 and extends beyond the insulating body 20. Thus, the first surface 204 of the assembled adapter 2 is flush with the mounting surface 1020 of the magnetically attractable conductive track 1 and the first surface 1401 of the end 14, and is disposed in conforming relationship with the surface of the mounting base. The second surface 206 of the adapter 2 is flush with the suction surface 1010 of the magnetic conductive track 1 and the second surface 1402 of the end 14, so that the overall structure is smooth and simple, and the height is low.

Specifically, the adaptor 2 has a different structure according to a cascade type, and if the magnetically conductive track 1 is connected in a cross shape as shown in fig. 12 to 14, the adaptor 2 includes a quadrangular insulation body 20 and a pair of guide portions 202 formed to extend from each side of the insulation body 20 and to be close to both ends. The conductive terminal 23 includes a quadrangular base 231 and four sets of abutting portions 232 extending from each side of the base 231 in parallel, wherein the abutting portions 232 are adjacent to the respective guiding portions 202 and located between the pair of guiding portions 202 on the same side. The butting portions 232 are provided in pairs, positive and negative electrodes, respectively. Therefore, the adaptor 2 can be mechanically and electrically connected with the end portions 14 of the four magnetic conductive tracks 1, and arrange the four magnetic conductive tracks 1 into a cross shape to form a cross-shaped magnetic conductive track system 1000.

If the magnetic conductive track 1 is connected in a straight shape, referring to fig. 15 to 17, the adapter 2 includes a quadrangular insulation body 20 and parallel guide portions 202 extending from opposite sides of the insulation body 20. The conductive terminal 23 includes a quadrangular base 231 and mutually parallel abutting portions 232 extending from opposite sides of the base 231. Therefore, the adaptor 2 can be mechanically and electrically connected with the end portions 14 of the two magnetic conductive tracks 1, and the two magnetic conductive tracks 1 are arranged in a cross shape to form a cross-shaped magnetic conductive track system 1000.

If the magnetically conductive track 1 is connected in a planar L shape, referring to fig. 18 to 20, the adapter 2 includes a quadrangular insulation body 20 and parallel guide portions 202 extending from two adjacent sides of the insulation body 20. The conductive terminal 23 includes a quadrangular base 231 and a butt-joint portion 232 extending from two adjacent sides of the base 231 and parallel to each other. Therefore, the adaptor 2 can be mechanically and electrically connected with the end portions 14 of the two magnetic conductive tracks 1, and the two magnetic conductive tracks 1 are arranged in an L-shape in a plane to form an L-shaped magnetic conductive track system 1000.

If the magnetic conductive track 1 is connected in an L-shape in mutually perpendicular planes, referring to fig. 21 to 23, the adapter 2 includes an L-shaped insulating body 20, and the insulating body 20 includes a flat first body 21 in a horizontal plane and an L-shaped second body 22 assembled with the first body 21. The guide portion 202 is formed to extend from a side wall of the first body 21 and a side wall of a portion of the second body 22 in the vertical direction. The conductive terminals 23 include a first conductive terminal 233 located in a horizontal plane and a second conductive terminal 234 located in a vertical plane and disposed perpendicular to the first conductive terminal 233. The first conductive terminal 233 and the second conductive terminal 234 extend from the horizontal side and the vertical side thereof to form parallel butt-joint portions 232, respectively. The other horizontal side of the first conductive terminal 233 extends to form a protrusion 2330, and the second conductive terminal 234 is correspondingly provided with an opening 2340 for accommodating the protrusion 2330 to form an electrical connection therebetween. In other embodiments, the location of the aperture 2340 stage protrusions 2330 may be interchanged. The first conductive terminal 233 is interposed between the horizontal portions of the first body 21 and the second body 22, and the second conductive terminal 234 is received in the vertical portion of the second body 22. Therefore, the adaptor 2 can be mechanically and electrically connected with the end portions 14 of the two magnetic attraction conductive tracks 1 respectively located in a horizontal plane and a vertical plane, and the two magnetic attraction conductive tracks 1 are arranged in an L shape located in different planes, so that a three-dimensional L-shaped magnetic attraction conductive track system 1000 is formed. In this embodiment, the first surface 204 is an upper surface of the first body 21, and the second surface 206 is a rear surface of the second body 22. In the assembled L-shaped magnetic conductive track system 1000, the first surface 204 is flush with the mounting surface 1020 of the main body 10 and the first surface 1401 of the end 14 of one of the magnetic conductive tracks 1 and is flush with the horizontal surface of the mounting base, and the second surface 206 is flush with the mounting surface 1020 of the main body 10 and the first surface 1401 of the end 14 of the other conductive track 1 and is flush with the vertical surface of the mounting base.

If the magnetically attractable conductive track 1 is connected in a T-shape, referring to fig. 24 to 26, the adapter 2 includes a quadrangular insulation body 20 and parallel guide portions 202 extending from three continuous sides of the insulation body 20. The conductive terminal 23 includes a quadrangular base 231 and a butt-joint portion 232 extending from three continuous sides of the base 231 and parallel to each other. Therefore, the adaptor 2 can be mechanically and electrically connected with the end portions 14 of the three magnetic conductive tracks 1 respectively, and the two magnetic conductive tracks 1 are arranged in a T shape to form the T-shaped magnetic conductive track system 1000.

The magnetic attraction conductive track 1 cascaded through the adapter 2 can magnetically attract various electrical devices and realize electric connection, and is convenient and reliable. The following examples are several kinds of electrical devices 3, 4, 5, 6 that can be connected to the magnetically attractable conductive track 1, and the electrical devices 3, 4, 5, 6 and the magnetically attractable conductive track 1 constitute an electrical system 2000. The electrical devices 3, 4, 5, 6 can be driving power sources or lighting lamps, intelligent control devices or sensor modules and the like, wherein the driving power sources 3 can receive electric power of commercial power and convert the electric power into the electric power of the electrical devices such as the lighting lamps 4, 5, 6 or the intelligent control devices or the sensor modules, and the electrical devices such as the lighting lamps 4, 5, 6 or the intelligent control devices or the sensor modules can also be provided with driving devices by themselves to realize electric power conversion. Also, in other embodiments, the electrical device is not limited to the type described above, but may be any electrical device configured to mate with the magnetically attractable conductive track 1 described above.

Referring to fig. 27 to 31, an electrical device according to a first embodiment of the present application is a driving power source 3 that can be coupled to and provide power for the magnetically attractable conductive track 1. The driving power source 3 and the magnetically attracted conductive track 1 form an electrical system 2000 according to the first embodiment of the present application.

The driving power source 3 includes a body 30 formed to extend in a longitudinal direction, an electrical connection module 32, a wire 33, and a driving module 34. The longitudinal extending direction is the length extending direction of the magnetic conductive track 1.

The driving module 34 includes various circuit modules (not numbered) and a control module, a bluetooth module or a wifi module 35 (which may be that the control module is integrally provided with the bluetooth module or the wifi module), the driving module 34 has a circuit board (not numbered) provided with the above modules, the circuit board is electrically connected with the conductive wires 33 and the electric connection module 32, the conductive wires 33 are connected with external mains supply respectively, and are used for supplying power to the driving power supply 3, the circuit board of the driving module 34 is electrically connected with the electric connection module 32 through the conductive wires, and the electric connection module 32 is assembled in the driving module 34 and is adsorbed and assembled in the magnetic conductive track 1 to form an electrical connection, so that the driving power supply 3 supplies power to the magnetic conductive track 1 and supplies power to other lamps.

The electrical connection module 32 is assembled to the main body 30, and includes a housing 320 formed to extend in a longitudinal direction, a magnet 323 and a conductive module 324 accommodated in the housing 320. The housing 320 includes a first housing 321, a second housing 322 assembled with the first housing 321 in the height direction, and the magnet 323, the conductive module 324, and the housing between the first housing 321 and the second housing 322. The longitudinal extending direction is the length extending direction of the magnetic conductive track 1.

The first casing 321 and the second casing 322 are hollow, and form a receiving space for receiving the magnet 323 and the conductive module 324 after being assembled. One end of the first casing 321 and one end of the second casing 322 are provided with openings for the wires 33 to pass through. The magnets 323 are arranged in the accommodating space at intervals and are close to the second shell 322 so as to be adsorbed to the magnetic element 11 of the magnetic attraction conductive track 1, and the surface of the second shell 322 is attached to the adsorption surface 1010 of the magnetic attraction conductive track 1 after assembly. The second housing 322 is L-shaped, is provided with a portion perforated with a wire 33 to pass through, is raised to form a raised portion 3222, and is formed to have a height difference from the base portion 3223. In the preferred embodiment of the present application, the outer surface 32230 of the base portion 3223 facing the suction surface 1010 of the magnetic conductive track 1 is provided with a strip-shaped mating portion 3220 extending in the longitudinal direction, and the outer surface 32230 is used as a mating surface. Corresponding to the position of the conductive module 324, the mating portion 3220 is formed with a plurality of grooves 3221 at intervals as conductive terminal accommodating portions 3221, and the conductive terminals 3241 are partially accommodated in the grooves 3221 and extend beyond the mating portion 3220.

The conductive module 324 is located between the magnets 323. The conductive module 324 includes a circuit board 3240 and a conductive terminal 3241 disposed on one surface of the circuit board 3240, wherein the conductive terminal 3241 is electrically connected to a built-in circuit of the circuit board 3240, and is electrically connected to the circuit board of the driving module 34 through a wire or a conductive terminal (not shown) disposed on the other surface of the circuit board 3240, so as to obtain the electric current transmitted from the wire 33 and converted by the circuit board of the driving module 34. In other embodiments, the conductive module 324 may be adapted to connect with the circuit board of the driving module 34 by providing another set of conductive terminals.

After the driving power supply 3 is absorbed and assembled on the magnetic conductive track 1, the end 14 of the magnetic conductive track 1 abuts against one end of the protrusion 3222, and the magnetic conductive track 1 is located above the base 3223 and is flush with the surface of the protrusion 3222, so as to form a flat, simple and ultrathin configuration of the magnetic conductive track 1. Then, the first conductive terminal 3241 is electrically connected with the conductive portion 13 of the magnetic conductive track 1 to supply power to the magnetic conductive track 1. The first conductive terminal 3241 is elastically and elastically telescopic, the mating portion 3220 and the first conductive terminal 3241 extend into the second space 125 of the insulating portion 12, and the first conductive terminal 3241 abuts against the surface of the conductive portion 13 and is compressed to apply a reaction force to ensure reliable electrical connection between the two portions after entering the second space 125 from the first space 124 of the insulating portion 12 of the magnetic conductive track 1. The mating surface 32230 of the base 3223 is attached to the attraction surface 1010 of the magnetic attraction conductive track 1, and the magnet 323 is attracted to the magnetic element 11 behind the attraction surface 1010 to combine the driving power supply 3 with the magnetic attraction conductive track 1. The coupling portion 3220 of the magnetic conductive track 1 is combined with the conductive terminal 3241 to enhance the coupling force of the two, the coupling surface 32230 attached to the surface of the adsorption surface 1010 ensures the lowest height of the electrical system 2000, and the magnet 323 is effectively adsorbed and combined with the magnetic element 11. Therefore, the driving power supply 3 provided by the application can realize mechanical connection and power supply by being adsorbed on the magnetic conductive track 1 and being electrically connected with the conductive part 13, and is convenient to use.

Referring to fig. 32 to 42, an electrical device according to a second embodiment of the present application is a lighting fixture 4, which can be assembled on the magnetic conductive track 1 in an adsorption manner and electrically connected to the magnetic conductive track 1 to supply power to the lighting fixture 4. In a preferred embodiment of the application, the lighting fixture 4 is a linear fixture, known as a line lamp. The lighting fixture 4 and the magnetic conductive track 1 form an electrical system 2000 according to a second embodiment of the present application.

The lighting device 4 includes a main body 40 extending in a longitudinal direction, a reflective layer 41, a light guide element 42, a mask 43, and end caps 44 disposed at two ends of the main body 40. In a preferred embodiment of the present application, the mask 43 is a diffuser plate for homogenizing light. The end caps 44 are fastened to both ends of the body 40 by screws, but not limited thereto. The portable electronic device further comprises a magnet module 45, an electrical connection module 46 and a lighting module 47, and is accommodated in the main body 40.

In order to accommodate the magnet module 45, the electrical connection module 46 and the lighting module 47, the main body 40 includes a bottom wall 401, a pair of side walls 402 extending from the bottom wall 401, and a top wall 403 extending from the other end of the side walls 402 in opposite directions. Two partitions 404 are formed in the longitudinal direction from the bottom wall 401 to the side wall 402. The partition 404 is parallel to the side wall 402, and divides the main body 40 into three regions, and two illumination module housing portions 405 formed between the partition 404 and the side wall 402 and a magnet module housing portion 406 located between the partition 404 are respectively configured to house the illumination module 47 and the magnet module 45. In order to accommodate the electrical connection module 46, an opening 4010 is formed in the middle of the bottom wall 401 and is in snap fit with the electrical connection module 46. Because of the existence of the opening 4010, the partition 404 is divided into two parts in the longitudinal direction, and correspondingly, the magnet module 45 has two parts, which are respectively accommodated in the magnet module accommodating part 406 and are separated by the opening 4010 and the electrical connection module 46 accommodated in the opening 4010.

The magnet module 45 includes two strip-shaped fixing portions 450, a plurality of pairs of positioning elements 4501 are disposed on the surface of the fixing portions, and groups of magnets 451 are stacked in parallel between the positioning elements 4501 and are accommodated in the magnet module accommodating portion 406.

The lighting module 47 includes a strip-shaped light source substrate 470, a plurality of light sources 471 arranged on the light source substrate 470, and at least two electrodes 472, wherein the light sources 471 and the electrodes 472 are respectively arranged along the height direction, and in a preferred embodiment of the present application, the electrodes 472 are arranged in the middle of the lower row of the light source substrate 470, respectively, and in other preferred embodiments, the electrodes for transmitting various control signals, adjusting light and color, and the like can be further included. In other embodiments, the lighting module 47 may have two groups of lighting modules 47 respectively received in one group of the lighting module receiving portions 405 adjacent to the sidewall 402.

The top wall 403 and the partition 404 have a height difference on a surface facing the top wall 403, and an optical element accommodating space 407 is formed, and the reflective layer 41, the light guide element 42, and the mask 43 are respectively accommodated in the optical element accommodating space 407 and are sandwiched between the top wall 403 and the partition 404. After assembly, the light source 471 of the illumination module 47 faces the side wall of the light guiding element 42, so that the outgoing light of the light source 471 enters the light guiding element 42 from the side wall of the light guiding element 42, and is reflected by the upper surface and the lower surface for multiple times, and then exits from at least one surface, in the embodiment of the application, exits from the surface facing the face mask 43, the reflective layer 41 is located on the other surface of the light guiding element 42, and reflects the light incident on the surface to re-enter the light guiding element 42 to increase the light efficiency.

The electrical connection module 46 is disposed in the opening 4010 and includes a housing 460 and an electrical connector 463 extending longitudinally, wherein the housing 460 includes a first housing 461, a second housing 462 and the electrical connector 463 disposed between the first housing 461 and the second housing 462.

The electrical connector 463 includes a base 463 with a circuit built therein, two pairs of first conductive terminals 4631 disposed on the base 4630, and a pair of second conductive terminals 4632 disposed on the base 4630. In the embodiment of the application, the first conductive terminal 4631 and the second conductive terminal 4632 are spring-needle-shaped conductive terminals, and a spring is arranged inside the first conductive terminal 4631 and the second conductive terminal 4632, and the spring contracts and applies a restoring force to increase the reliability of the electrical connection after being stressed. The first conductive terminals 4631 may be at least one pair, and are used for electrically connecting the lighting fixture 4 with the conductive portion 13 after being assembled on the magnetic conductive track 1. The two groups of first conductive terminals 4631 are respectively perpendicular to the substrate 463 and disposed at four corners of the substrate 463, and are welded by through holes, or may be welded by surface welding or other connection methods, and electrically connected to the circuit in the substrate 463. The second conductive terminal 4632 is soldered on the surface of the base 463 and parallel to one surface of the base 463, but other connection methods can be adopted, and is electrically connected with the circuit in the base 463, so as to be electrically connected with the first conductive terminal 4631. The second conductive terminal 4632 is elastically abutted to the electrode 472 of the lighting module 47 to form an electrical connection, so that the first conductive terminal 4631 is electrically connected to the second conductive terminal 4632 via the circuit of the substrate 463 after being electrically taken from the magnetic attraction conductive track 1, so as to supply power to the lighting module 47, and meanwhile, the magnet 451 of the magnet module 45 is attracted to the attraction wall 101 of the magnetic attraction conductive track 1.

The first housing 461 and the second housing 462 are snap-coupled and snap-fit with the opening 4010 of the light fixture 4. The second housing 462 includes a bottom wall 4620 and a pair of side walls 4621 extending from both sides of the bottom wall 4620 toward the first housing 461. The side wall 4621 is torn at the middle and turned outwards to form a holding part 4622 which is buckled with the peripheral wall of the opening 4010. Four round holes are formed in four corners of the bottom wall 4620 for the first conductive terminal 4631 to pass through, and a plurality of mating parts 4623 are formed on the surface 46200 (as a mating surface) of the bottom wall 4620 facing the magnetic conductive track 1 in a protruding manner, the first conductive terminal 4631 is located between the mating parts 4623 and extends beyond the mating parts 4623, the mating parts 4632 can protect the first conductive terminal 4631 and extend into the second space 125 of the magnetic conductive track 1 together with the first conductive terminal 4631, and the first conductive terminal 4631 further enters the first space 124 to elastically abut against the conductive part 13 to form an electrical connection. The bottom wall 4620 is attached to the attraction surface 1010 of the magnetic conductive track 1, that is, the mating surface 46200 is attached to the attraction surface 1010, and the magnet 451 is attracted to the magnetic element 11 behind the attraction surface 1010. The second conductive terminals 4632 partially extend beyond the side walls of the first and second housings 461, 462 disposed perpendicularly to the side walls 4621 for elastic abutment with the electrodes 472 of the lighting module 47. The matching part 4623 of the magnetic conductive track 1 is assembled with the first conductive terminal 4631, so that the binding force between the magnetic conductive track 1 and the lighting lamp 4 is enhanced, the height of the electrical system 2000 is ensured to be low enough, the thickness is thin enough, and the structure is simple.

With continued reference to fig. 43 to 48, the present application further provides a lighting fixture 5 having an adsorption group disposed on the magnetic conductive track 1 according to a third embodiment of the present application, where in the embodiment of the present application, the lighting fixture 5 is a grille lamp. The lighting fixture 5 and the magnetically attractable conductive track 1 form an electrical system 2000 in accordance with a third embodiment of the present application.

The lighting fixture 5 includes a main body 50 extending in a longitudinal direction, a mask 53 assembled to the main body 50, a lighting module 57 accommodated between the main body 50 and the mask 53, an electrical connection module 51 pivotally connected to the main body 50, and a rotation shaft 52 respectively sleeved between the main bodies 50 of the electrical connection module 51.

The lighting module 57 includes a light source substrate 570, a light source 571 disposed on the light source substrate 570, a primary optical element 572 disposed outside the corresponding light source 571, and a secondary optical element 573 disposed at one end of the primary optical element 572. In the embodiment of the application, the light source may be an LED particle or COB light source, the primary optical element 572 is a reflector, and is fixed on the light source substrate 570, one end of the primary optical element is covered on the light source 571, the other end of the primary optical element is a light outlet, the secondary optical element 573 is in a flat plate shape and is positioned at the light outlet of the reflector 572, and a plurality of polarizer structures are arranged at intervals on the secondary optical element 573 for expanding the light outlet angle of the light from the light outlet of the reflector 572 along the transverse direction.

The mask 53 comprises a main body 530, and a number of gratings 531 located inside the main body 530 are provided for the number of reflectors 572. The main body 530 extends beyond the grille 531, a plurality of holding portions 532 are formed at intervals on the outer periphery of the side wall, and the mask 53 is assembled on the main body 50 and then is in snap fit with the holding portions 501 on the inner wall of the main body 50, in the embodiment of the present application, the holding portions 532 of the mask 53 are hooks, the holding portions 501 of the main body 50 are recesses formed therein, and the hooks and the recesses can be interchanged. Secondary optic 573 is sandwiched between primary optic 572 and grid 531. One end of the grille 531 is provided with an opening as a light inlet for correspondingly receiving incident light from the lens module, the other end is also provided with an opening as light outlet, and the side wall extends to be horn-shaped. The range of the outgoing light passing through the secondary optical element 573 is equivalent to the outgoing flare.

The electric connection module 51 includes a housing 510 extending in a longitudinal direction, a driving portion 58 accommodated in the housing 510, a conductive module 56, and a magnet module 55. The housing 510 includes a main body 54, and a cover 59 assembled to the main body 54, and the driving unit 58, the conductive module 56, and the magnet module 55 are accommodated between the main body 54 and the cover 59.

The main body 54 includes a rectangular frame 540 and a semicircular pivot portion 541 formed by protruding from an end portion of the frame 540. The pivot portion 541 has a circular pivot hole 5410 formed in a lateral end surface thereof. Correspondingly, the main body 50 is also provided with a semicircular pivoting portion 502 in a protruding manner, and a pivot hole (not numbered) is formed, so that two ends of the pivot 52 are respectively accommodated in the pivot hole 5410 and the pivot hole of the pivoting portion 502 of the lamp body 50, and the electric connection module 51 and the main body 50 can mutually rotate, so that the emergent light range of the lighting module 57 of the main body 50 can be adjusted.

The conductive module 56 includes a flat substrate 560 with a circuit therein, two pairs of pin-shaped conductive terminals 561 extending from one surface of the substrate 560, and a pair of mounting holes 562 formed in the middle of the substrate 560 and located between the two pairs of pin-shaped conductive terminals 561. The conductive terminals 561 have springs therein, which can be compressed to increase the reliability of electrical connection after being electrically connected with the magnetic conductive track 1, and are electrically connected with the built-in circuits of the base 560. In order to supply the power from the magnetically attracted conductive track 1 to the lighting module 57, the conductive module 56 needs to be electrically connected to the driving portion 58, in the embodiment of the present application, the base 560 of the conductive module 56 is electrically connected to the driving portion 58 through a wire (not shown), however, in other embodiments, the base 560 may be further provided with a pin-shaped conductive terminal 561 opposite to the other surface provided with the conductive terminal 561, and the driving portion 58 is provided with a conductive sheet on its circuit board for abutting against the pin-shaped conductive terminal to form an electrical connection. The driving part 58 is electrically connected with the lighting module 57 through a wire, and converts the electric power from the commercial power into the electric power required by the lighting module 57 to be supplied to the lighting module 57. Since the driving power supply 3 converts the commercial power into 58V power, the lighting fixture 5 needs to be provided with the driving section 58 to further convert the 58V power into the voltage required by the lighting fixture 5.

The magnet modules 55 are two groups, each group includes at least two magnets, and the rectangular frame 540 of the main body 54 is provided with a containing space for containing the magnet modules 55, the conductive modules 56 and the driving part 58.

The cover 59 is screwed to the main body 54, and the cover 59 is substantially flat, and has openings 591 at both ends, and the magnet module 55 is accommodated in the accommodation space of the main body 54 and protrudes from the openings 591 to the cover 59. In the preferred embodiment of the present application, the outer surface 593 (as the mating surface) of the cover 59 facing the adsorbing surface 1010 of the magnetic conductive track 1 is provided with a strip-shaped mating portion 590 and is located outside the opening 591, and the mating portion 590 is formed with a plurality of grooves 592 as conductive terminal accommodating portions 592 corresponding to the positions of the conductive terminals 561 of the conductive modules 56. The conductive terminals 561 of the conductive module 56 protrude beyond the surface of the mating portion 590 of the cover 59 for electrically connecting to the magnetically conductive track 1.

After the lighting fixture 5 is assembled on the magnetic conductive track 1 to form the electrical system 2000, the mating portion 590 and the conductive terminal 561 extend into the second space 125 of the magnetic conductive track 1, and the conductive terminal 561 further enters the first space 124 to be elastically abutted against the conductive portion 13 to form an electrical connection. The mating surface 593 of the cover 59 is attached to the attraction surface 1010 of the magnetic attraction conductive track 1, and the magnet module 55 is attracted to the magnetic element 11 behind the attraction surface 1010. The coupling portion 590 of the magnetic conductive track 1 is assembled with the conductive terminal 561, so that the coupling force between the magnetic conductive track 1 and the lighting fixture 5 is enhanced, the height of the electrical system 2000 is ensured to be low enough, the thickness is thin enough, and the structure is simple.

Therefore, after the grille lamp 5 is assembled to the magnetic conductive track 1 by the conductive terminal 561 and the magnet module 55, the lighting module 57 can emit light according to needs, can be controlled, can adjust light and color, and the like, and can realize angle adjustment relative to the electric connection module 51. The convenient assembly mode greatly facilitates the use.

Referring to fig. 49 to 61, the present application provides a lighting fixture 6 according to a fourth embodiment, which is a polarized light line lamp, especially a wall washer lamp. The lighting fixture 6 and the magnetically attractable conductive track 1 form an electrical system 2000 in accordance with a fourth embodiment of the present application.

The lighting fixture 6 comprises a body 60 formed by extending longitudinally, a cover 62 formed by extending longitudinally and assembled on the body 60, a light guide element 61 assembled on the body 60 and the cover 62, a magnet module 65, an electric connection module 66, a lighting module 67 and end covers 64 assembled on two ends of the body 60 and the cover 62.

The body 60 includes a conductive track housing 601, a magnet module housing 602, a lighting module housing 603, a light guide element housing 604, a cover housing 605, and an electrical connection module housing 606.

The body 60 includes an inverted U-shaped frame 607 enclosing the magnet module housing 602, and the U-shaped frame 607 includes a base 6070 and a pair of sidewalls 6071 extending perpendicularly from opposite edges of one surface of the base 6070. An L-shaped side wall 6072 is formed by extending vertically and then horizontally from the free end of the side wall 6071, and the L-shaped side wall 6072 is opened outwards and forms the conductive track accommodating portion 601 between the two sides, so that the conductive track accommodating portion 601 is U-shaped and is communicated with the magnet module accommodating portion 602 formed by surrounding the U-shaped frame 607. The other surface of the base 6070 has two protruding edges 6073, which form an outward opening lighting module accommodating portion 603 with the base 6070. The wedge-shaped extension portion 6074 protrudes from the vicinity of the base portion 6070 and the bottom wall thereof is connected to the L-shaped side wall 6072, and the wedge-shaped extension portion 6074 is formed with the above-described light guide element housing portion 604, which is of a hollow configuration, and reduces weight and increases strength. An L-shaped cover housing portion 605 is formed between the L-shaped side walls 6072 and 6071. The back of the body 60 is partially cut away to form an electrical connection module receiving portion 606.

The cover 62 has a substantially L-shape and includes a first cover 621 accommodated in the cover accommodating portion 605, and a second cover 622 formed by extending vertically from the first cover 621. The first cover 621 is hollow and has a protruding portion 6210 that is interference fit with an interference portion 6075 formed on the surface of the L-shaped side wall 6072 that faces the first cover 621. The second cover 622 partially covers the outside of the lighting module housing portion 603, that is, the outside of the lighting module 67, and has a U-shaped coupling portion 6220 formed at a free end thereof. The first cover 621 is also screwed with the L-shaped sidewall 6072 of the body 60.

The lighting module 67 includes a strip-shaped light source substrate 670, and a plurality of light sources 671 disposed on a surface of the light source substrate 670 and adjacent to one end. The lighting module 67 is inserted and accommodated in the lighting module accommodating portion 603.

The light guide element 61 is wedge-shaped, and is laid on the surface of the light guide element accommodating portion 604, and includes a wedge-shaped main body portion 610, a light incident surface 611 located at one side of the wedge-shaped main body portion, and a light emergent surface 612 forming a certain angle with the light incident surface 611, wherein the light emergent surface 612 is a main surface of the main body portion 610 and faces the outside. The light incident surface 611 faces the light source 671 of the lighting module 67, receives the incident light from the light source 671, and is totally reflected in the wedge-shaped main body 610 for multiple times, and exits from the light emergent surface 612. For uniform light extraction, the surface of the light extraction surface 612 may be etched or dotted or doped with particles with different concentrations inside the light guide element 61, so as to achieve scattering and light extraction.

The magnet module 65 includes a plurality of groups of magnets 650 and bar-shaped fixing portions 651 arranged at intervals, and the magnets 650 and the fixing portions 651 are arranged in a bar shape at intervals and assembled from the magnet module accommodating portion 602, so that at least one surface of the magnet module 65 faces the conductive track accommodating portion 601.

The end cover 64 has a triangular shape and includes a body portion 640, extension portions 641 extending from two ends of the body portion 640, and a plurality of coupling portions 642 disposed on a surface of the body portion 640 and facing the body 60. The end caps 64 are assembled at two ends of the body 60 by the combination of the combination portion 642 and the body 60, and the extension portions 641 are flush with one surface of the L-shaped side wall 6072, and the space between the extension portions 641 is used for accommodating the end 14 of the magnetic conductive track 1.

The electrical connection module 66 includes a housing 660 formed to extend in a longitudinal direction, and an electrical connector 663 accommodated in the housing 660. The housing 660 includes a first housing 661 and a second housing 662 assembled with each other, and the electrical connector 663 is sandwiched between the first housing 661 and the second housing 662.

The electrical connector 663 comprises a base 6630, a first conductive terminal 6631 disposed on one surface of the base 6630 and extending vertically from the base 6630, and a second conductive terminal 6632 disposed on the other surface of the base 6630 and extending vertically from the base 6630. The first conductive terminal 6631 is a spring-needle-shaped conductive terminal and is electrically connected to a circuit inside the base 6630, the second conductive terminal 6632 is an elastic element, preferably a spring, and the base 6630 is provided with an opening for accommodating the second conductive terminal 6632 and is electrically connected thereto.

The first housing 661 includes a bottom wall 6610 and a side wall 6611 extending from the bottom wall 6610. The middle part of the side wall 6611 is provided with a first combining part 6612 which is a buckling part. The bottom wall 6610 is respectively provided with a second connecting portion 6614 and a terminal accommodating portion 6613, in the embodiment of the application, the second connecting portion 6614 is an opening, and the terminal accommodating portion 6613 is a circular opening for the second conductive terminal 6632 to pass through and extend beyond the bottom wall 661 of the first housing 661.

The second housing 662 includes a bottom wall 6620, and a side wall 6621 extending from the bottom wall 6620. The middle part of the side wall 6621 is provided with a first combining part 6622 which is a buckle hook. The first combining portion 6622 is snapped with the first combining portion 661 of the first housing 661, and in other embodiments, the two structures can be interchanged. The bottom wall 6620 is provided with second coupling portions 6624, and terminal housing portions 6623, respectively. In the embodiment of the application, the second connecting portion 6624 is an opening, and the terminal receiving portion 6623 is a circular opening. In the embodiment of the present application, the second coupling portion 6624 is a cylinder, and is used for forming interference fit with the second coupling portion 6614 of the first housing 661 and has guiding function. In other embodiments, the second joints 6614, 6624 are interchangeable. The terminal receiving portion 6623 is a circular opening through the bottom wall 6620. On both sides of the other surface 66200 (as a mating surface) of the bottom wall 6620, strip-shaped mating portions 6625 are respectively formed in an extending manner, which are arranged in a row at intervals with the first conductive terminals 6631, and the first conductive terminals 6631 extend beyond the mating portions 6625.

The electrical connection module 66 is accommodated in the electrical connection module accommodating portion 606 of the main body 60, and is locked to the main body 60 by a screw. The second conductive terminal 6632 is abutted against the back surface of the light source substrate 670 of the lighting module 67 to realize electrical connection. The first conductive terminal 6631 protrudes into the conductive track housing 601. After the lighting fixture 6 is assembled on the magnetic conductive track 1, the magnetic conductive track 1 is accommodated in the conductive track accommodating portion 601, the adsorption surface 1010 is attached to the mating surface 66200 of the conductive track accommodating portion 601, and the l-shaped side wall 6072 and the extension 641 of the end cover 64 are attached to the side wall 103 of the magnetic conductive track 1. The first conductive terminal 6631 and the mating portion 6625 are combined together into the second space 125 of the insulating portion 12 of the magnetic conductive track 1, and the first conductive terminal 6631 continues to extend into the first space 124 and elastically abuts against the conductive portion 13 disposed in the first space 124 to form an electrical connection. The matching part 6625 of the magnetic conductive track 1 is assembled with the first conductive terminal 6631, so that the binding force between the magnetic conductive track 1 and the lighting lamp 6 is enhanced, the height of the electrical system 2000 is ensured to be low enough, the thickness is thin enough, and the structure is simple.

The magnetic conductive track system 1000 and the electric system 2000 which are composed of the magnetic conductive track 1, the adapter 2, the electric devices 3, 4, 5 and 6 are simple in structure, high in efficiency, low in cost and convenient to assemble.

In addition, the electric device can also be a down lamp, a spotlight, a dinner lamp, a ceiling lamp and other lighting lamps.

The foregoing embodiments of the present application mainly describe differences between the embodiments, and as long as there is no contradiction between different optimization features of the embodiments, the embodiments may be combined to form a better embodiment, and in view of brevity of line text, no further description is provided herein.

The foregoing is merely exemplary of the present application and is not intended to limit the present application. Various modifications and variations of the present application will be apparent to those skilled in the art. Any modification, equivalent replacement, improvement, etc. which come within the spirit and principles of the application are to be included in the scope of the claims of the present application.

Claims (7)

1. A magnetic conductive track system (1000) configured to be installed on a surface of a mounting base, comprising an adapter (2) and at least two magnetic conductive tracks (1); The adapter (2) comprises an insulating body (20) and a conductive terminal (23) arranged in the insulating body (20); The conductive terminal (23) comprises a base portion (231) disposed in the insulating body (20) and a docking portion (232) extending beyond the insulating body (20); The magnetic conductive track (1) comprises a main body (10) and end portions (14) arranged at both ends of the main body (10), the main body (10) comprises a receiving space (106), a conductive portion (13) is embedded in the main body (10), and the end portions (14) are configured to be electrically connected to the conductive portion (13) and the conductive terminal (23) of the adapter (2) at the same time and mechanically connected to the main body (10) of the magnetic conductive track (1) and the adapter (2) at the same time; The end portion (14) comprises an insulating body (140) and a conductive terminal (143) disposed in the insulating body (140), wherein two ends of the conductive portion (13) extend beyond the two end surfaces (100) of the main body (10) and extend into the end portion (14) to be electrically connected to the conductive terminal (143); The insulating body (140) of the end portion (14) comprises a first surface (1401) and a second surface (1402) which are arranged opposite to each other, and a first end face (1403) and a second end face (1404) which are arranged opposite to each other, and a pair of conductive plug-in parts (144) arranged in a horizontal direction and a positioning plug-in part (145) located between the conductive plug-in parts (144) are formed extending from the first end face (1403) along the length direction, wherein the conductive part (13) enters the end portion (14) from the conductive plug-in part (144) and is electrically connected to the conductive terminal (143), and the positioning plug-in part (145) enters the receiving space (106) and abuts against the magnetic element (11); A conductive plug hole (147) and a positioning hole (146) are recessed from the second end face (1404) toward the first end face (1403), and the insulating body (20) of the adapter (2) protrudes at the docking portion (232) adjacent to the conductive terminal (23) to form a guide portion (202) spaced apart from the conductive terminal (23), wherein the conductive terminal (143) in the conductive plug hole (147) forms an electrical connection with the conductive terminal (23) of the adapter (2), and the positioning hole (146) accommodates the guide portion (202) of the adapter (2). 2. The magnetic conductive rail system (1000) according to claim 1 is characterized in that the conductive terminal (143) of the end portion (14) includes a base (1430) located in a vertical plane and a first docking portion (1431) and a second docking portion (1432) extending from the base along the length direction and in the reverse direction, wherein the first docking portion (1431) forms an electrical connection with the conductive portion (13), and the second docking portion (1432) forms an electrical connection with the conductive terminal (23) of the adapter (2). 3. The magnetic conductive track system (1000) according to claim 2 is characterized in that the first and second docking portions (1431, 1432) respectively include a pair of elastic components extending from the upper and lower end edges of the base (1430) and bent toward each other, and near the free ends, the elastic components are adjacent to each other and the free ends form spring guide portions (1433) that are away from each other, and the conductive portion (13) passes through the spring guide portions (1433) and is sandwiched between the elastic components to form an electrical connection with the conductive terminal (143). 4. The magnetic conductive rail system (1000) according to claim 1 is characterized in that the positioning holes (146) are a pair, and the conductive plug holes (147) are a pair, and are located on the inner side of the pair of positioning holes (146). 5. The magnetic conductive track system (1000) as described in claim 1 is characterized in that: the magnetic conductive track system (1000) is located in the same plane, and comprises at least two magnetic conductive tracks (1) and at least one adapter (2), wherein the ends (14), the main body (10) and at least one adapter (2) of different magnetic conductive tracks (1) are mutually embedded and assembled, and the outer surfaces of the three are flush with each other. 6. The magnetic conductive track system (1000) as described in claim 1 is characterized in that: the magnetic conductive track system (1000) is located in different planes, and comprises at least two magnetic conductive tracks (1) and at least one adapter (2), wherein the adapter (2) is L-shaped, wherein after an end (14), a main body (10) and a part of at least one adapter (2) of one magnetic conductive track (1) are mutually embedded and assembled, at least the surfaces of the three facing the installation base are flush with each other and attached to the installation base; after an end (14), a main body (10) and another part of the at least one adapter (2) of another magnetic conductive track (1) are mutually embedded and assembled, at least the surfaces of the three facing the installation base are flush with each other and attached to the installation base. 7. The magnetic conductive track system (1000) according to claim 1 is characterized in that the guiding portion (202) and the docking portion (232) are jointly assembled into the end portion (14) to realize the electrical and mechanical connection of at least two magnetic conductive tracks (1).